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THE FISHING INDUSTRY 


PITMAN’S 
COMMON COMMODITIES 
AND INDUSTRIES SERIES 


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‘a9 1GSUUOA J IMVUL AHL ONIINVH 


PITMAN’S COMMON COMMODITIES 
AND INDUSTRIES 


THE 
FISHING INDUSTRY 


BY 
a 


; (Y 
W:E* GIBBS, D.Sc. 


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PARKER STREET, KINGSWAY, W.C.2 


BATH, MELBOURNE, TORONTO, NEW YORK 
1922 


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PREFACE 


IN this little book I have tried to describe concisely, 
yet clearly and comprehensively, the great work of 
our sea fisheries. It is notoriously difficult to write a 
small book on a large subject, and I expect there are 
many who will detect sins of omission. 

The book is chiefly concerned with fisheries for edible 
fish. I have included a chapter on whale fisheries, 
since whale oil is now used largely in the manufacture 
of such food substances as lard substitute and margarine. 
No account of seal “fishing” is included, as seals are 
not fished but are generally hunted on shore. I have 
not included fisheries for pearls, sponges or seaweed. 
To its cost the nation knows little of the methods and 
organization and achievements of the Fishing Industry. 
I sincerely hope that this little book may do something 
to stimulate a wider and deeper interest in this vitally 
important British industry. 


My cordial thanks are due to Mr. J. A. Robertson, 
O.B.E., of Fleetwood, and to Mr. W. T. Sinderson, of 
Grimsby, who have very kindly read through the 
manuscript and given me the benefit of their valuable 
experience and advice. 

I am indebted to Prof. James Johnstone, of Liverpool 
University, for much of the information contained in 
Chapters I and II, and also for permission to use the 
illustrations on pages 17 and 29. 

For other illustrations I make grateful acknowledge- 
ment as follows: for Nos. 7, 8, 9, 10, 15, 16, 17 and 19, 
from The Sea Fisheries, to the author, Dr. J. Travis 


Vv 


vi PREFACE 


Jenkins, and the publishers, Messrs. Constable; for 
the frontispiece and No 18, to the Grimsby Coal, Salt 
and Tanning Co ; for Nos. 11, 14 and 20 to Mr. Walter 
Wood, of the Mission to Deep Sea Fishermen. 

Mr. R. A. Fleming, of Liverpool University, very kindly 
copied Nos. 2, 3, 4 and 5 for me from Day’s British 
Fishes. 

Chapter V is based upon Bitting’s monograph on “‘the 
preparation of the cod and other salt fish for the market’ 
(U.S. Dept. Agric. Bur. of Chem. Bull. No. 133). 


W. E. G. 


Runcorn, 1922. 


- 


Win Woe B alee 8 eS 


CONTENTS 


PREFACE 

INTRODUCTION . ‘ ° ; ‘ 
CHARACTERISTICS AND HABITS OF FISHES 
METHODS OF FISHING . . p 
THE HERRING FISHING INDUSTRY : 
THE NEWFOUNDLAND COD FISHERY 
TRAWL FISHERIES . : : 
SHELLFISH - . : : ° 
FISHERIES FOR WHALES . i ° 
THE CURING AND PRESERVATION OF FISH 
THE FOOD VALUE OF FISH 

FISH PRODUCTS 


INDEX . 


PAGE 


ILLUSTRATIONS 


F1G. PAGE 
HAULING THE TRAWL ; . Frontispiece 

1. METAMORPHOSIS OF PLAICE : - y 7 

2.) cop ; Z - ; , : : ae: 5 

3. LEMON SOLE . Z 4 , ; s ee 

A SKATE «3 - ‘ , 8 A : tee: 

5. HERRING : : - ‘ ‘ : ~~ ae 

6. PLANKTON : : , ; : ; ee 

7. HERRING EGGS j : ; ; ; ee 

8. PLANKTON CONTAINING FISH EGGS . : Sah ao 

9. TRAWLING (civca 1750) : . ; . 45 

10. DRIFTING (civca 1750) . : ; : . 49 
11. SINGLE-BOATER AT FOLKESTONE ; : 2 ao 
12. HERRING DRIFTER : : : | 867 
13. CURING YARD (YARMOUTH) : i ; . 89 
14. SCOTTISH FISHER GIRLS . , : : Pepe | 
15. SECTION OF MODERN TRAWLER ; : > a 
16. PLANS OF MODERN TRAWLER . : , ee 
17. THE OTTER TRAWL : P ; : “pee 
18. THE CATCH ABOARD ; ; , . 87 
19. CHART OF TRAWLING GROUNDS 2iteelen pp. 88 and 89 
20. A WHALE’S MOUTH ‘ é i , Pees | i | 


THE 
FISHING INDUSTRY 


CHAPTER I 
INTRODUCTION 


IN its essential features the story of the gradual rise and 
development of the fishing industry closely resembles 
that of its sister industry, agriculture. In both cases 
man became skilled in harvesting long before he under- 
stood anything of the art of cultivation. Primitive man 
roamed from place to place in the wake of the annual 
wave of harvest, gathering wild crops of grain, berries 
and fruits. Ultimately he became alive to the signifi- 
cance of seed, and the nomad settled down to raise 
crops year after year in the same place. Gradually he 
acquired a knowledge of the conditions of temperature, 
moisture, and quality of soil that favoured the growth 
of his plants. Finally, he discovered the principle of the 
rotation of crops, and, by this, not only increased the 
productivity of his land but also laid the foundations of 
a systematic agriculture. Of recent years agriculture 
has been rapidly developing into a science. Chemistry, 
physics, botany, plant physiology, and bacteriology, all 
contribute increasingly to a full understanding of the 
inner processes of the growing plant, and indicate more 
and more clearly the exact relations that exist between 
the conditions of growth and the character and amount 
of the resulting product. 


1 


2 THE FISHING INDUSTRY 


The art of fishing is one of the oldest in the world, yet 
even to this day the fisherman is simply a hunter, 
gathering where he has not sown, and differing little, 
save in mechanical efficiency, from his primitive ancestor 
fishing with spear and trap. 

Only in recent years has any systematic attempt been 
made to understand something of the forces that produce 
the annual harvest of the sea. We know very little 
about the habits of the various fishes that constitute 
this harvest—their food, their migrations, their repro- 
ductive processes, and, in general, the conditions upon 
which their healthy life and development depend. We 
have developed highly efficient fishing implements, but 
we have yet to learn to use them wisely and not too 
well); ‘to increase the fertility of the various fishing — 
grounds rather than depopulate them by over-fishing 
and the destruction of immature fish. 

The fisherman’s harvest differs from that of the farmer 
in one important respect. Fishes grow for three or 
four, or more, years before they are mature. Now, 
only mature fish as a rule have any considerable com- 
mercial value, and only mature fish are able to reproduce 
their kind and so maintain the existence of the fishery. 
On the fishing grounds, both mature and immature 
fish are mingled together, and in capturing the one it 
is practically impossible to avoid netting the other. To 
some extent the capture of immature fish is avoided by 
making the mesh of the net of such a size that the 
smaller fish can escape. With drift nets only mature 
fish are caught, the small ones escaping; but with trawl 
nets it is otherwise. The trawl net is essentially a large 
string bag that is drawn open-mouthed along the sea 
bottom, scooping up wholesale all bottom-living fish, 
such as cod, haddock, sole and plaice. All go into the 
net, both large and small, and, although the young 


INTRODUCTION 3 


fish ultimately escape through the meshes, many of them 
are damaged in so doing, while many young, flat fish, 
lying on the sea bottom, are damaged by the foot rope 
of the net, as it passes over them. Certain fishing 
grounds, such as the Dogger Bank, were almost 
depopulated of flat fish in the years just previous to the 
war. 

Fortunately for the future of the fisheries, the trawl z~ 
can only be worked on smooth ground, andat depths not , - 
exceeding two hundred and fifty fathoms, so that only 
a small percentage of the actual fishing grounds is affected 
by it. Also, when a fishing ground shows signs of becom- 
ing exhausted by over-fishing, it is less frequented by 
fishermen, owing to the reduced catches that can be 
obtained, and thus it tends automatically to recover. 
Nevertheless, }it is desirable that fishing should be so 
organized and restrained, that the fertility of the 
fishing grounds is not imperilled. In the distant 
future it may become possible to re-stock partially 
exhausted grounds with young fish, artificially reared 
in a hatchery. 

Oceanography—the study of the ocean and its 
inhabitants—is one of the youngest of sciences. Yet, 
to an island people such as we are, it should be one of 
the most important, for it is only by the study of 
oceanography that we can hope to found a systematic, 
organized aquiculture. 

The beginning of a simple aquiculture is to be seen in 
the cultivation of shellfish, such as oysters and mussels, 
by the inshore fishermen. 

Of recent years, experiments have been carried out by 
the Fishery Boards of England, Scotland, Germany, and 
the United States of America, with the object of 
increasing the productivity of certain fishing grounds by 
adding large numbers of artificially hatched, young 


4 THE FISHING INDUSTRY 


fish. For some years the Fishery Board for Scotland 
added annually about twenty million plaice larvae to 
certain confined sea areas (Upper Loch Fyne), and 
found, as a result, that the number of young plaice on 
the shallow beaches was doubled. 

In some cases a new species of fish has been intro- 
duced into a particular fishing ground, with marked 
success. Thus the U.S.A. fisheries collected and 
hatched the eggs of the shad on the Atlantic coast and 
introduced the larvae into the Pacific, with the result 
that. a profitable shad fishery has now been established 
on the Californian coast. 

The application of science to the fishing industry is 
not restricted to biological investigations of the food, 
habits and development of living fishes. It is developing 
new processes for the better preservation of edible 
fish for food purposes, so that the large quantities of 
fish caught periodically—for example, in the summer 
herring fishery—may be stored up for gradual consump- 
tion during the winter. It has shown that fish waste 
can be manufactured into glue, cattle food, and fertil- 
izers. It has developed into a profitable industry the 
extraction of oils from both edible and inedible fish, and 
the conversion of these oils into hard fats, suitable for 
the manufacture of soap and margarine. It has demon- 
strated that the skins of certain fish, notably the shark, 
can be tanned to make excellent leather. 

With the exception of these pioneer experiments and 
investigations, however, the fishing industry of to-day 
is simply an organized art—the art of catching wild 
fish. The story of the industry is essentially a descrip- 
tion of the methods that are used for capturing the 
various species of fish that are of commercial importance, 
and for handling, curing, and disposing of the catch. 

Great Britain is situated in the midst of the greatest 


INTRODUCTION 5 


fishing grounds of the -world. The British fishing 
industry is the most efficient and the most highly 
developed of any. Consequently, since fishing methods 
are essentially the same everywhere, it will be sufficient 
for us to consider, with few exceptions, the methods 
and equipment that are used by our own fishermen 
around our own shores. 

ere is direct evidence that, as early as the third 
century, A.D., fish were caught in considerable quantities 
round the coast of Britain by the natives and used as 
food. Little is known about the early development of 
a fishing industry in this country. We know that in the 
fourteenth and fifteenth centuries, fish was in demand 
throughout the country, partly because of the religious 
observance .of fast days, and partly, no doubt, because 
it afforded a welcome change in the regular winter diet 
of salted meat. In those days there was no winter 
root crop, so that cattle were killed in autumn and salted 
down for consumption during the winter. 

In disposing of their catch, the fishermen were handi- 
capped by the almost complete lack of transport 
facilities from the coast inland. Their produce would be 
distributed by pack-horse, so that fresh fish would be 
practically unknown beyond a distance of a few miles 
from the coast. Consequently, all fish for imland 
markets were salted. The fish were pickled in brine, as 
the art of dry-salting was then unknown in this country. 

o develop a successful fishing industry, it was 
necessary, then, as it is to-day, either to dispose of the 
catch quickly on the spot, or to preserve the fish so that 
it could be transported to distant markets. In 1347, 
a Dutchman, William Beukels, of Biervelt, invented an 
improved means of curing and pickling herring, which 
was essentially the modern process of gutting the 
fish and packing them in dry salt. At this time the 


6 THE FISHING INDUSTRY 


Baltic herring fishery, carried on by the Hanseatic 
League, dominated the markets of Europe. But the 
new method of curing, exploited by the Dutch, improved 
the quality and keeping powers of the fish to such an 
extent that, by the end of the fifteenth century, the 
Dutch fishing industry was supreme, and had become 
a powerful and valuable national enterprise. In the 
sixteenth century, as many as two thousand Dutch 
herring “‘ busses”’ (as the boats were called) would 
gather on St. John’s day at Brassa Sound, in the Shet- 
lands, to begin the summer herring fishery. The fish 
were caught with drift nets, were salted and packed in 
barrels, and carried home by the fast-sailing, attendant 
“yaggers.” Ashore they were re-packed in fresh 
salt in new barrels. Over a million barrels were 
packed ina year. When caught, the fish would be worth 
about a million pounds, and when retailed about two 
million pounds. Contemporary illustrations of the 
methods of curing and salting then in use reveal the 
astonishing fact that even to the smallest detail the 
methods that were employed in Holland in Elizabeth's 
day are identical with those that are employed at 
Yarmouth to-day. 

As a direct result of the great development of their 

ade in salted herrings, the Dutch gradually gained a 
naval and maritime supremacy in Europe which they 
maintained until it was wrested from them by the 
English. | 

English sea-power in the early years of the sixteenth 
century was in a decadent condition. The ports and 
harbours had been neglected, and had become silted up, 
so that the condition of the shipping industry in general, 
and of the Navy in particular, had reached a very low 
ebb. In 1561, Mr: Secretary Cecil, alarmed by the 
growing menace of the Dutch naval ascendancy, proposed 


INTRODUCTION 7 


three remedies for restoring the strength and importance 
of the navy. He proposed : 

(1) That the fishing industry be promoted, as it 
provided a valuable recruiting ground for the navy ; 

(2) That merchandise be extended, and so provide 
increased employment for the shipping industry ; 

(3) That piracy be encouraged, privately-owned 
privateers forming valuable auxiliaries in time of war. 

He though that the fishing industry could be stimulated 
immediately by renewing the fast days, which had 
fallen into disuse since the abolition of the monasteries. 

He suggested that two days a week—Wednesday and 
Friday—should be meatless days. 

In 1563, he tried a measure of Protection, a Naviga- 
tion Act being passed, making it illegal to buy or sell 
foreign-caught fish, and attempts were made to 
prevent Dutch and other foreigners from fishing in 
English waters. These measures, although passed by 
Parliament, do not appear to have been enforced. 

James I issued two proclamations, imposing licences 
and dues upon foreign fishing vessels fishing in British 
waters. No attention was paid to these, and it was left 
to Charles I, some years later, to enforce them. Other 
steps taken by both Charles I and Charles II consisted 
mainly in the formation of Royal Fishery Companies. 
Various fishery companies and societies succeeded one 
another up to the end of the eighteenth century. They 
do not appear to have been successful in establishing a 
flourishing fishing industry, and in 1718 (George I) an 
act was passed by which fishermen were to be rewarded 
for their catch by a bounty. Bounties were to be paid 
for several kinds of fish : thus, for every barrel of white 
herrings of 32 gallons, exported beyond the seas, the 
bounty was 2s. 8d.; for full red herrings, 1s. 9d. per 
barrel ; for empty red herrings, 1s. per barrel. 


8 THE FISHING INDUSTRY 


The conditions upon which the bounty was to be paid 
were fully set forth in a later act in 1750 (George II). 
The construction of herring vessels was encouraged by 
a bounty of 30s. per ton, paid out of the Customs, for 
decked fishing vessels of from twenty to eighty tons. 

The time and place of fishing were stipulated, as well 
as rules for the proper management and prosecution of 
the fishery. Each vessel was to have on board twelve 
Winchester bushels of salt for every last of fish such 
vessel was capable of holding, the salt to be contained 
in new barrels. 

In 1757, the bounty was increased to 50s. per ton, but 
was reduced to 30s. again in 1771. It was further 
reduced to 20s. in 1787, and an additional bounty of 
4s. per barrel added. This was made proportional to 
the tonnage, so that no vessel could claim more than 
30s. per ton—aunless the vessel caught over three barrels 
per ton, in which case a bounty of ls. per barrel was 
granted upon the surplus quantity. 

While the bounty often undoubtedly encouraged the 
development of the fishery, the development was not so 
rapid or so extensive as it would otherwise have been, 
owing to the duty on imported salt. The weight of the 
duty was such that the fishermen threw fish overboard 
rather than cure it, only landing that which could be 
brought in fresh. 

In 1808 the bounty was raised to £3 per ton on every 
British built and British owned fishing boat of not less 
than sixty tons burden, properly manned, registered, 
and navigated and employed in herring fishing. The 
maximum tonnage on which the bounty was payable 
was one hundred tons. Two shillings per barrel was 
paid on properly cured and packed herrings. 

After the peace of 1815, the naval wars and the 
press gangs had reduced the sea fisheries to negligible 


INTRODUCTION 9 


proportions, but the existing bounties were continued 
until 1829, and encouraged the rapid revival of the 
industry. By 1829, the fishing industry was well estab- 
lished, and thereafter steadily developed in value and 
importance. 

The modern organization and development of the 
fishing industry began between 1870 and 1880, following 
the introduction of steam fishing vessels. The old 
sailing smacks and drifters were necessarily limited in 
their scope and capacity. They could only fish in 
certain weathers; they required skilled handling ; 
their effective area of operation was restricted by the 
necessity for bringing the catch ashore as fresh as 
possible ; their trawling power depended upon the wind. 


A sail boat was generally the property of a small 
family group of fishermen, who worked the boat and | 
fished, while one of their number—the ship’s husband— | 
stayed ashore to purchase stores and tackle, and dispose | 


of the catch. The proceeds of the boat were shared | 


among the owners. These privately owned sail boats 
were to be found in every little harbour on every coast 


of Britain. The fishermen themselves were a fine, | 


sturdy, independent class of men, skilful seamen, and 
all-round fishermen, able to turn their hands to any form 
of fishing, whether lining, trawling, or drifting. 

The introduction of steam trawlers and drifters has 
completely changed the character and organization of 
the fishing industry. Instead of being individualistic, 
it has become collective, and instead of being the com- 
mon industry of every seaside village, it has become 
controlled by large limited liability companies, and 
centralized in a few large ports. 

Steamers were first used in 1870, to collect the catch 
from the sail boats on the fishing grounds, bringing it 
home with all speed while the fishing boats remained at 


2—(1457H) 


10 THE FISHING INDUSTRY 


sea. This naturally enabled the fishing boats to catch 
more fish, and also made possible the use of larger boats 
fishing further afield. A logical development of this 
step was the construction of actual steam-driven fishing 
boats—trawlers and drifters. These steamers soon 
proved to be superior to the sail boats. They were able 
to fish in all weathers, even in a calm. Owing to their 
greater power, also, they were able to use much larger 
nets and fish in deeper waters. 

Steam trawlers and drifters are much more expensive 
than smacks or sailing drifters. They can only be 
berthed and handled satisfactorily in harbours that are 
equipped for the unloading and dispatching of large 
quantities of fish. From the very beginning these 
steamers were owned by large limited companies rather 
than by individuals, and the industry has tended to 
become more and more centralized at certain large ports, 
for example, Aberdeen, Hull, Grimsby, Yarmouth, 
Lowestoft, Milford Haven, and Fleetwood. The rise and 
development of many of these ports, for example, 
Aberdeen and Fleetwood, has been in direct response to 
the demands made upon them by the new steam fishing 
industry. 

The introduction of steam fishing made longer voyages 
possible, and led to the development of new fishing 
grounds. Steam trawlers from British ports now fish 
as far north as Iceland and the White Sea, as far west as 
Newfoundland, and as far south as Morocco, making 
voyages of many week’s duration. 

The re-organization of the fishing industry led to 
specialization amongst the fishermen themselves. The 
old sailing fisherman was essentially an all-round man. 
He was equally expert at lining, drifting and trawling. 
| The skipper of a steamer, however, is a specialist ; he 
is either a liner-, a drifter-, or a trawler-man. Generally, 


INTRODUCTION ll 


also, he keeps to a given region—Iceland, the White 
Sea, the North of Scotland, the North Sea, or the Bay of 
Biscay. ; 

In the three years preceding the war (1911 to 1914) 
the development of the steam fishing industry had 
become almost stationary. This was probably due in 
-part to over-capitalization, resulting in lower profits. 
It was feared also that the greatly increased efficiency of 
the steam trawlers tended to produce a condition of 
over-fishing in certain areas, with the result that catches 
obtained in those areas progressively diminished ; for 
example, the average catch per boat per day in the 
North Sea during three successive periods was as 
follows— 


Beene OO BUD a eee ee ae be oe 17-2 cwts. 
1A ie oy ee Al ie ee IG? S,, 
1 SRG 2) 0 aa barr eect isae gs 


The fishermen became alarmed and development was 
arrested. This tendency to over-fish certain grounds has 
been effectively checked during the war by the almost 
complete cessation of offshore fishing. There is thus 
every probability that such grounds have now recovered, 
and further that, in many cases, grounds such as the 
Dogger Bank, that had become almost depopulated, 
will have become restocked. 

The successful development of steam fishing has 
necessarily reacted upon the prosperity of the individual 
fishermen in the various fishing villages, with their 
smaller, privately-owned sail boats. They were faced 
with two alternatives: either to combine together to 
acquire steamers, and so maintain their position in 
the offshore fisheries, or to devote their attention to the 
development of inshore fishing. Many of the larger 
sailing drifters have now been fitted with petrol engines, 


12 THE FISHING INDUSTRY 


which make it possible for them to compete with the 
steam drifters for herring and mackerel. 

Generally speaking, however, the outlook for the small 
fishermen of the English and Scottish coast villages—the 
real fisher folk—is discouraging. The tendency of 
legislation, however, just before the war was to encourage 
this class of fishermen by restricting the operations of the 
steam trawlers in certain localities. In 1910-1914, 
with the object of protecting the inshore fishermen, the 
Fishery Board of Scotland prohibited trawling in the 
Moray Firth area, only drifting and lining being’ per- 
mitted. Since this prohibition only applied to British 
subjects, certain East Coast fishing companies evaded 
it by transferring their vessels to foreign flags, register- 
ing them in a foreign port and employing a foreigner as a 
dummy skipper. The Board secured convictions against 
these offenders in the Sheriff’s Court, but the convictions 
were upset subsequently by the Foreign Office. The 
original prohibition was then strengthened by a new 
law which made it illegal to land fish in Scotland, if 
caught by vessels registered in a foreign port. 

During the war, the inshore fisherman found himself 
in a comparatively advantageous position, as the high 
price of coal made steam fishing less profitable. Fur- 
ther, the offshore trawling grounds were mostly 
closed, and the majority of the steam trawlers and 
drifters were on war-service. For the time being, 
therefore, inshore fishing with smacks was placed at an 
advantage. 

A number of fishermen’s co-operative societies were 
formed to organize the sale and distribution of the 
produce of these inshore fisheries. This also tended to 
make the position of the inshore fisherman more secure. 

The old order changeth, and although there is that 
connected with this transformation in the fishing 


SS aE ee is 


INTRODUCTION 13 


industry which is to be regretted, yet, on the whole, 
the developments of the past forty years have 
undoubtedly transformed the fishing industry into a 
very efficient and valuable national asset. Individually, 
the present-day steam fisherman is very much inferior 
to his sailing predecessor. The centralization of the 
industry in a few big ports, although undoubtedly making 
for much greater efficiency, bears hardly on the type of 
the old class of expert fishermen ; but these are the 
almost inevitable consequences of such a transition. 
But what is the present condition of the industry, and 
what is its future likely to be ? The prosperity of the 
inshore fisherman, as well as that of his offshore rival, is 
vitally important to the welfare of this country ; there 
should be room and opportunity enough for both. 
The inshore fisherman, protected by legislation and 
secured by well-organized co-operation, can increase 
very considerably the amount of our available home- 
grown food supply. The superior power and equip- 
ment of the big steam trawlers and drifters, properly 
utilized and encouraged, should be one of the most 
valuable industrial assets of the State. We are not a 
great food-producing nation ; on the contrary, in the 
years before the war, we actually imported more than 
40 per cent of our total food requirements. We are 
surrounded by seas that teem with every form of 
edible fish. British enterprise has built up a fishing 
industry which is the greatest and most efficient in 
the world. In 1914, our fishing boats were practically 
equal in numbers and equipment to those of all the 
other countries in North-West Europe put together. 
Nearly 70 per cent of the fishing boats in the North Sea 
were British. The total produce of our sea fisheries has 
nearly doubled since the beginning of the century. 
The annual catch in the last few years before the war 


14 THE FISHING INDUSTRY 


averaged over a million tons. It was worth about 
fifteen million pounds when landed, and may be valued 
at nearly fifty million pounds by the time it reached 
the consumers. Of all this splendid food that is obtained 
at our very doors by our own people, less than half is 
retained for consumption in this country. Out of 
600,000 tons of herrings landed annually in this country 
before the war, over 500,000-were exported, chiefly to 
European countries. Herrings have a high food value, 
and contain a large amount of easily digested fat, and 
if all the herrings landed in this country were consumed 
at home, it would only allow two herrings a week to 
each adult individual in all the population. An 
increased home consumption of fish, would effect a 
corresponding saving in imported meat. 

Owing to this remarkably small home demand for 
fish, the fisherman has had to depend upon foreign mar- 
kets, chiefly Germany, Poland, Russia and the Levant. 
The present adverse rate of exchange with these 
countries, and the increased cost of fishing operations, 
make it impossible for the foreign importer to take our 
fish, except on terms which our fishermen cannot consider. 
These markets are therefore closed, and unless other 
outlets are found for its produce, the industry will be 
threatened with ruin. 

In 1920, the Government guaranteed the cure of 
herrings up to 880,000 barrels; unfortunately, they 
were only able to dispose of them in European markets 
at a great loss. The Government, therefore, have 
decided this year (1921) to withdraw their guarantee. 

It would seem that, in view of the present failure of 
the foreign markets, vigorous steps should be taken to 
encourage the consumption of fish in this country, and 
so preserve this valuable industry from ruin. A national 
scheme of development should be inaugurated, having 


INTRODUCTION 15 


for its objects, (1) the systematic exploitation of local 
and periodic coastal fisheries; (2) the discovery of 
methods of preserving for future consumption fish that 
cannot be disposed of just when it is caught; (3) the 
education of the public to use more freely the large 
supplies of excellent fish food that are available at our 
very doors. 


CHAPTER II 
CHARACTERISTICS AND HABITS OF FISHES 


FISHES are the most primitive vertebrate, i.e. back- 
boned, creatures known. All reptiles, birds, and animals 
have gradually evolved from fish-like ancestors by a 
series of age-long processes, the stages of which are 
recorded in fossilized remains that are found in various 
rock strata throughout the world. A fish lives exclusively 
in water. It has no lungs, but extracts oxygen from the 
water as it passes over the surface of its gills. Instead 
of limbs, it has fins, with which it balances itself and 
propels itself through the water. Its skin is either 
bare, e.g. the cat fish, or is covered with scales, e.g. the 
herring, or with bony plates, e.g. the sturgeon. The 
skin of certain sharks is studded with minute teeth and 
produces, when cured, the well-known shagreen leather. 
In nearly all cases the skin of fishes is liberally supplied _ 
with small glands which constantly produce a lubricating 
mucus. This mucus greatly reduces friction between the 
fish and the water through which it moves. 

The body of a fish is adapted to move swiftly and 
smoothly through the water ; it is shaped more or less 
like a torpedo, but this form is greatly modified in 
different species. Certain species of fish living at the 
bottom of the sea, for example skates and rays, have 
become flattened, as though by a pressure applied 
vertically downwards. Others, for example plaice, 
flounder, sole, appear to have been flattened sideways. 
In the various members of the eel family, the body is 
greatly elongated. 

The body of a fish is generally coloured and marked 


16 


Mh E 
of Plaice.. 


Metam orphosis 


— 


Fic. 1 


18 THE FISHING INDUSTRY 


in such a way that it becomes practically invisible 
when seen from above or below, the under-surface being 
silvery white, and the upper surface generally olive or 
blackish-green. Sometimes, as in the mackerel, the 
upper surface is mottled, resembling rippled water. 

Most small fish in ponds and streams reflect their 
surroundings so well, and are coloured and marked in 
such a way, that they are almost invisible to the large 
fish, for example pike, that prey upon them. Generally, 
they reveal their presence by the flash of light reflected 
from above by their scales, as they turn suddenly to 
snap at a morsel of food. In the same way, many 
predatory fish, e.g. the angler fish, resemble their 
surroundings so closely that the fish for which they are 
lying in wait swim within easy reach of them without 
perceiving their danger. Many fishes, particularly 
in tropical waters, are remarkable for their bright and 
gorgeous colouring. It is impossible to preserve 
these colours in their natural brightness after the fish 
have been taken from the water, but amongst the 
brightly coloured corals, and anemones and seaweeds, 
in the crystal clear water of their natural environment, 
they flit like gorgeous tropical birds in a tropical forest. 

Distribution. Fishes are found in practically every 
ocean, lake and river in the world, with a few notable 
exceptions, such as the Dead Sea, in which the con- 
centration of salt is too high. They appear to exist 
at all depths of water, and have been found in the sea 
as deep down as 2,720 fathoms. Fish living at this 
depth generally possess enormous mouths, long, attenu- 
ated, soft bodies, and are equipped with highly developed 
phosphorescent organs. 

The distribution of a particular species appears to 
depend upon the salinity of the water, the temperature 
of, the water, the kind and quantity of food available 


CHARACTERISTICS AND HABITS OF FISHES 19 


and the prevailing intensity of sunlight. It is possible 
to divide fish into four well-defined groups, according to 
the salinity of the water in which they are found: 
(1) Marine fish : those that live always in the sea, for 
example herring, haddock, shark. (2) Fresh-water 
fish : those that live always in fresh water, for example 
carp, trout, pike. (3) Many fish live in brackish water, 
and appear to be able to accommodate themselves easily 
to considerable changes in salinity, e.g. sticklebacks, 
gobies, grey mullets and blennies. Such species natur- 
ally are widely distributed ; thus, a particular kind of 
grey mullet (Mugil capito) is found without any 
appreciable difference in form on nearly every coast of 
the Atlantic Ocean. (4} The fourth group of fish are 
migratory. Some species, for example salmon and 
shad, live and develop in salt water, but ascend rivers 
to spawn, i.e. to lay their eggs, in fresh water. Others, 
such as eels and certain pleuronectids, for example the 
flounder, live and develop in fresh water, and descend 
rivers to the sea to spawn. Many fresh water fish, 
e.g. trout, forsake the large streams in the spring and 
ascend small brooks, where the young can be reared in 
greater safety. 

Of these different groups or species, the marine fishes 
are industrially by far the most important, for at least 
two-thirds of all the fish in the world live in the sea, 
and the capture of these sea-fish in enormous quantities 
constitutes the fishing industry, with which we are 
concerned. 

The different species of marine fishes can be divided 
into three well-marked groups, according to their 
habits and habitats. 

(1) There are the true deep-sea fishes that live at the 
bottom of the sea, for example cod, haddock, plaice, 
sole. These are called ‘‘ demersal” fish. Fish, like 


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CHARACTERISTICS AND HABITS OF FISHES 21 


birds, inhabit a medium that is continuous throughout 
the world. A glance at the map of the world will show 
that the three great oceans—Atlantic, Indian and 
Pacific—are united in the southern hemisphere. In 
Tertiary times, it is practically certain that the Pacific 
and the Atlantic oceans were also united at Darien, and 
that the Mediterranean was united with the Red Sea. 
Apart, therefore, from differences in local conditions, 
for example of temperature and food supply, there is 
practically no obstacle to the world-wide distribution of 
any particular species of fish. At the bottom of the sea, 
the temperature, the food supply, and the general con- 
ditions of life are singularly uniform all over the world, 
consequently there are no barriers at all to the dispersion 
of demersal fish, and we find various species widely 
distributed in all seas. Demersal fish, on the whole, 
are more primitive in type than those that live nearer 
the surface. They have well-developed senses of touch 
and smell by means of which they hunt for their food. 
They differ markedly in structure and shape from sur- 
face or shallow-water fish, their bodies being designed 
to resist the greater pressure of deep water. The body 
is generally lean and is enclosed by a wall of muscular 
fibre. Shallow-water fish, if introduced into deep water, 
would be crushed inward by the pressure. Similarly, 
the deep-living, demersal fish are unable to accomodate 
themselves to shallow water and, if placed in it, soon 
become unhealthy. A cod floats helplessly on its side 
when placed in shallow water, owing to the dilatation 
of its swimming bladder. If the bladder is pricked it 
collapses, and the fish is able to regain an upright 
position. This is done when cod and other similar 
demersal fish are kept alive in sea-water tanks on board 
ship, to be delivered to the markets alive. In Denmark, 
fish are delivered alive to the shops. When fishes from 


22 THE FISHING INDUSTRY 


great depths are brought to the surface, their bodies break 
into pieces owing to the reduced external pressure, the 
scales start from their skin and the eyes from their sockets. 
There are two distinct types of demersal fish: the 
“round ” and the “ flat.”” The body of a round fish is 
more or less circular in cross-section, for example cod, 
while that of a flat fish is flattened, for example sole, ray. 
‘The most important edible demersal fish can be 
classified as follows— 
(a) The Gadidae—telated to the cod. 

Cod—inhabits northern waters, notably the North 
of Britain, Iceland and Newfoundland. 

Ling—inhabits northern waters: West of Scotland 
and Ireland, and North towards Iceland and 
Newfoundland. 

Haddock—inhabits northern waters. Nearly half 
the total catch is obtained in the North Sea, from the 
White Sea to the Bay of Biscay. 

Whiting—found in great numbers in the North 
Sea. It is more coastal than the cod or haddock. 

Hake—found from Norway to the Mediterranean. 
The greater part of the catch is obtained off the south- 
west of Ireland. Hake is also caught off Morocco 
and in the Bay of Biscay. 

(b) The Pleuronectidae—telated to the plaice and 
sole. 

Sole—a shallow-water fish, common in the Irish 
Sea, and particularly abundant in southern waters 
down to Morocco. 

Plaice—inhabits northern waters—all round Britain 
and Iceland. 

Flounder—inhabits estuaries, for example, of the 
North Sea and the Baltic. 

Halibut—inhabits northern waters. It attains a 
large size, six feet or more. 


A, CA . 
OY AAA ee 


\S\ LAYS 


LEMON SOLE (Pleuronectes microcephalus) 


Length up to 16 ins. Food.—Small crustaceans and worms. 
Range.—From North of Europe to the Bay of Biscay. 


Fic. 4 
SKATE (Raia batis) 


Length up to 7 ft. Food.—Crustaceans and molluscs, and fish. 
Range Round the British Isles and along the coast of Western Europe. 


24 THE FISHING INDUSTRY 


Turbot—not very abundant. It inhabits the deeper 
parts of the North Sea. 

Brill—inhabits southern waters, and is fairly 
abundant. 

(c) The Raitidac. 

Skates and rays—found all round Britain, more 
particularly the Western area of the English 
channel. 

(2) The various species of fish that inhabit the surface 
waters of the sea are called “ pelagic.”” They include 
the herring, mackerel, tunny, flying fish, sword fish, and 
many sharks,.also various marine mammals, such as 
whales, grampuses, porpoises, dolphins. Amongst pelagic 
fish are included some of the smallest (plankton) as 
well as some of the largest (whales) of all living creatures. 
Pelagic fish pass their whole life swimming at or near the 
surface. They enter the shallow water offshore only for 
prey or, in some cases, periodically to spawn. The 
majority spawn in the open sea, far from land. Unlike 
demersal fishes, the distribution of the different species 
of pelagic fishes depends very much upon local con- 
ditions of light, water temperature, and the character 
and quantity of food available. They do not hunt 
their food individually to the same extent as demersal 
fishes, but generally filter it from the water as it passes 
through their gill-openings. Although not so widely 
dispersed as demersal fish, they are, in favourable 
circumstances, dispersed over large areas by swimming 
and by ocean currents. : 

All pelagic fish are ‘round.’ With the exception 
of the mackerel, the important edible pelagic fishes 
belong to the herring family, and are known as the 
Clupeidae. They include— 

Herring—found from the White Sea to the Bay of 
Biscay. It is the most abundant of all food fishes. 


CHARACTERISTICS AND HABITS OF FISHES 25 


Sprat—found from the North of Europe to the 

Mediterranean 

Pilchard—ranges from the English Channel to 

Madeira and the Mediterranean. Skipper “‘ sardines ”’ 

are young herring, pilchard, and brisling. 

There is also— 

Mackerel—found from the North Sea to Madeira 
and the Mediterranean. 

(3) The shallow-water of the seashore is inhabited 
by certain animals ( shellfish’) not found elsewhere, 
including various mollusca, e.g. mussel, cockle, oyster 
and periwinkle, and crustacea, e.g. lobster, crab, prawn, 
shrimp. In addition to these, there are various species 
of immature offshore fish, e.g. plaice and dabs. The 
inhabitants of this shallow, coastal water are called 
“littoral” fish. The distribution of such littoral fish 
depends not only upon the water temperature and the 
amount of light, but also upon the character of the 
shore—whether it is rocky, or soft and sandy—and more 
especially upon the animal and vegetable products of 
the adjacent land, e.g. plants, seaweed, worms. Littoral 
fish do not swim very far, but become scattered inadver- 
tently over considerable distances by currents and other 
mechanical means. 

Certain kinds of shellfish, for example oysters, mussels, 
cockles, live in the sand or attached to the stones or 
seaweed on the seashore, generally between high and 
low watermarks. They obtain their food from the water 
as it streams over their gills. They require adequate 
room for growth and development, and constant irriga- 
tion by water containing sufficient floating food. When 
mussel beds or oyster beds become overcrowded, the 
fish are ill-nourished, their health is impaired and their 
growth is arrested. It has been shown that, if they are 
transferred to new beds, their condition rapidly improves 

3—(1457n) 


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CHARACTERISTICS AND HABITS OF FISHES yep f 


and ultimately they increase considerably in size. All 
edible shellfish need systematic care and attention. 
Their cultivation by man affords the simplest instance 
of an attempt at a systematic aquiculture. 

Food. The surface water of the sea abounds in 
minute forms of vegetable and animal life. This vast 
floating population of microscopic organisms is called 
the ‘‘ plankton.” Just as man and all land animals 
depend ultimately for their food supply upon grass and 
other green-leaved plants which, under the influence of 
sunlight, are able to transform the inorganic constituents 
of the atmosphere and the soil into organic foodstuffs— 
albumen, fat, carbohydrates—so the minute unicellular 
marine plants of the plankton are able, under the 
influence of sunlight, to convert the imorganic con- 
stituents of their environment into fat, albumen and 
carbohydrate. Upon these minute organisms, therefore, 
directly or indirectly, all marine life depends. 

In addition to these minute plants, the plankton 
contains nearly all forms of marine life at some stage or 
other of their life history. Fish are only found in it as 
eggs, or larvae. Crustacea of all kinds are present, 
and form one of its most important constituents. Crabs 
and lobsters spend their larval, free-swimming career 
among the plankton, until they reach the adult stage 
and settle down to the bottom. Various minute 
crustacea, known as “Copepoda” (lit., oar-footed) 
spend the whole of their lives drifting about in the 
surface water. They occur in incredibly large numbers, 
and are the most abunaant of all forms of marine life. 
These copepoda form the main source of the food of 
pelagic fish, such as the herring, mackerel and sprat. 

The larvae of the edible molluscs, oyster, mussel, 
cockle, develop in ithe warm surface water until they 
settle to the bottom and begin their adult life. 


28 THE FISHING INDUSTRY 


There are also many larval forms of marine worms 
and jellyfish, and many kinds of microscopic, unicellular 
organisms, some of which are vegetable and others are 
clearly animal. The chief animal forms belong either 
to the Infusoria, the Foraminifera or the Radiolaria. 
The shells of the two latter forms accumulate at the 
bottom of the sea, producing the deposits known 
as the Globigerina and Radiolarian oozes. In this 
way, chalk deposits were formed in primitive times. 

The most important vegetable planktonic organisms 
are the Diatoms. Their accumulated shells form 
important deep-sea deposits. 

The numerous varieties of planktonic life can thus 
be divided into two groups: those minute animal and 
vegetable organisms that pass the whole of their exist- 
ence at the surface of the sea—the true constituents of 
plankton all the year round—and the eggs and larvae 
of many species of fish that are found among the plankton 
only at certain times of the year—notably in spring and 
summer. 

The quantity of organic food substances such as 
albumen, fat and carbohydrate, that is contained in the 
plankton produced annually by a given area of the sea, 
has been compared with the quantity of such substances 
produced by a similar ared of land in crops such as 
pasture, hay, lupine and peas. In this way, it has been 
estimated that the productivity of the sea is about 20 
per cent less than that of average land, 

Unlike that of the land, the productivity of the sea 
is greater in colder latitudes than in the tropics. This 
somewhat unexpected fact is attributable to the action 
of denitrifying bacteria which, flourishing more readily 
in warm, tropical waters, effectively reduce the amount 
of available nitrogen compounds in the water. In colder 
waters, denitrifying bacteria are less active, and nitrates 


PLANKTON: LARVAE 
1. Crab zoea; 2. Fish egg; 3. Sea Urchin pluteus; 4. Barnacle 
nauplius; 5. Fish larva; 6. Mussel larva; 7. Copepod nauplius ; 
8. Worm larva. 


mn uae es} 


PLANKTON : UNICELLULAR ORGANISMS 
1, 2, 3, 7, 10, 11, 12, 13, 16, 17, 18. Diatoms; 4, 5, 7, 9, Peridinians 
8. An Algal spore; 14. Noctiluca; 15. A Radiolarian. 
Fic, 6 


itil aie 


30 THE FISHING INDUSTRY 


and nitrites are available in larger quantities for the 
nourishment of the plankton. 

All the great fisheries of the world are prosecuted in cold 
or temperate seas ; as examples of this we have the Banks 
of Newfoundland, the cod fisheries of Norway,and the great 
trawling grounds of the North Sea and the North Atlantic. 

All fish, during the larval stage of their development, 
feed first upon the contents of the yolk sac which, 
when they are hatched, is attached to their ventral 
surface. When the yolk is absorbed, the larvae feed 
upon the microscopic plankton that abound in the 
water on every side. The surface water, with its 
warm temperature, high plankton content and sunlight, 
forms an ideal nursery for the very young fish of all 
species. Demersal fish, as they complete the larval 
stage of their development and descend into deeper 
water, have to rely for their food either upon the various 
species of young shellfish and crustacea that drop from 
the surface water as they develop, or hunt for their food 
amongst the small fish, mollusca, crustacea, worms and 
seaweeds of the sea-bottom. Plaice feed chiefly upon 
cockles and other mollusca, which in their turn feed upon 
diatoms, The cod is almost omnivorous, greedily 
devouring small fish, crustacea, worms or mollusca ; 
its favourite food, however, is shrimps and prawns. 
These, in their turn, feed upon smaller invertebrates, 
for example small jellyfish and larval molluscs, and 
these upon microscopic plankton. 

Pelagic fish, herrings and mackerel, feed almost 
entirely upon the larger plankton, mainly copepoda 
(small, shrimp-like crustacea). These may be present 
in the surface water in enormous quantities at certain 
times. In many cases, shoals of herring or mackerel 
probably follow special swarms of copepoda. Mackerel 
also feed upon young fish, hermit crabs, and prawns. 


CHARACTERISTICS AND HABITS OF FISHES 31 


With a few notable exceptions, the various species of 
demersal fish feed upon smaller fish. Thus— 

The hake, normally a deep-water fish, ventures inshore 
in pursuit of herrings, pilchards, mackerel. 

The ling, turbot, brill, dog fish live entirely upon small 
fish. The dog fish swarms on certain fishing grounds 
and is often a serious pest to the drift-net fishermen, 
destroying their nets as well as the fish that are 
attached to them. 

The whiting, like the cod, feeds upon small fish, and 
upon crustacea and mollusca. 

The food of the haddock consists of mollusca, crustacea 
and marine worms, etc. 

The sole lives on small crustacea, for example shrimps, 
and marine worms. 

Skates and rays feed upon mollusca and crustacea. 

Most shellfish live in shallow water and feed upon the 
plankton. 

The methods by which fish obtain their food differ 
greatly according to the species of the fish. Pelagic 
fish, e.g. herring and mackerel, sprat and pilchard, 
obtain their food almost automatically as they swim 
open-mouthed through the water in which it abounds. 
These direct plankton-feeders possess comb-like struc- 
tures—the gill-rakers—attached behind the gill openings, 
and as the food-bearing water streams through the mouth 
and gill openings of the fish, these structures strain the 
food from it. The fish licks the plankton from its 
gill-rakers with its tongue and swallows it. 

Many pelagic fish, e.g. carp, trout, salmon, look for 
their food while swimming through the well-lighted 
surface water. 

Demersal fish—flat fish, cod, haddock, etc.—seek their 
food by scent and touch. The cod possesses a barbel at- 
tached to its chin, by means of which it feels for its food. 


32 THE FISHING INDUSTRY 


The Angler or Devil fish is a curious creature, from 
three to four feet long, and appearing to consist almost 
entirely of head. It has a large mouth, and teeth that 
are hinged so as to admit food, but prevent it from 
escaping. The devil fish has a long feeler on the top of 
its head, terminating in a tassel which, moved by the 
water, attracts the attention of small fish and lures them 
to their fate. This tassel is a sensory organ and, when 
it is touched by the small fish, the angler fish snaps 
upwards with unerring aim at a point immediately in 
advance of the tassel. 

The dog fish seeks its food exclusively by scent. If 
its sense of smell be destroyed, it ceases to feed 
spontaneously. 

The sole also seeks its food by smell. It is quite unable 
to recognize a worm by sight or touch, even when hung 
just above its head, but feels aimlessly over the ground 
seeking it by smell. 

Reproduction. Fish are male and female and, with 
few exceptions, reproduce their kind by laying eggs. 
The number of eggs laid by an individual female fish 
during a single spawning varies greatly, according to 
the species. The average number of eggs spawned by 
a single female fish in the course of one season, is— 


Ling 5 ‘ ‘ ‘ . 18,500,000 
Turbot . ; . ‘ . 8,600,000 
Cod ; 5 ; ; . 4,500,000 
Flounder ; i : . 1,000,000 
Sole : ; , : a ~ 570,008 
Haddock ‘ ‘ . ; 450,000 
Plaice . : . ’ ; 300,000 
Herring : : ; ° 32,000 
Shark 


fore A few—not more 
Dog fish j : , (than a dozen. 
Skate 


_— 


. ee 
————s 


HERRING EGGS— xX 


o Sere 20% 
ik eS AS 


A 
4 
f 


Py 


PLANKTON CONTAINING FISH EGGS—x 3 


The large egg is that of a plaice: the smaller ones are cod and whiting. 
The copepod is a calanus. 


34 THE FISHING INDUSTRY 


The eggs of the cod, whiting, haddock, fluke, plaice, 
etc., are relatively small, varying from % of an inch in 
the case of a halibut, to #5 of an inch in a flounder. 
The eggs are discharged into the water by the female. 
This process takes place gradually, and generally 
occupies many weeks. A few of the eggs come to 
maturity at a time, and are extruded. They are 
fertilized in the water by the spermatazoa of the male, 
which are discharged into the water at the same time as 
the eggs. The fish, both male and female, are closely 
crowded together on the spawning grounds, so that the 
fertilization of the eggs is fairly complete. With few 
exceptions, the eggs of most species are buoyant and 
float to the surface, where they drift in the warm surface 
water until, happily, they hatch. Unhappily, however, 
a very large proportion of them never reach maturity, 
for, either as eggs, embryos or larvae, or post larval 
young fishes, they soon fall a prey to marauding fish. 
It is estimated that, of the thirty-two thousand eggs 
laid annually by each female herring, not more than two 
reach maturity. 

The spawning grounds of the herring are not definitely 
known. Research is being carried out at present with 
a view to solving this question. Haddock are to be 
caught in various likely parts of the sea, marked with 
the place of capture, and their interiors examined for 
herring spawn, 

Certain demersal fish, notably shark, dog fish and skate, 
deposit a few large, demersal eggs-—about a dozen in the 
year—in a carefully selected spot. The incubation period 
of these eggs is unusually long, being from six months to 
over a year, according to the species and the temperature 
of the water. 

Parental care is exhibited by very few fishes in this 
part of the world, although many foreign fish build 


CHARACTERISTICS AND HABITS OF FISHES 35 


nests and care for their young, often carrying them in 
their mouths. Certain kinds of dog fish and angel fish 
keep their young inside their oviducts until they are 
completely formed. The only notable example of a 
fish common to British waters that exercises parental 
care is the stickleback. Spawn is deposited by a number 
of different females in a nest constructed of stones 
and weed, and is guarded by a male until all the eggs 
are hatched. 

The eggs of the crustacea, for example the lobster, are 
found attached in large numbers to the swimmerets— 
feathery processes that are situated underneath the 
tail. When in this condition, the lobster is known as 
“ berried,” and, if captured, should be returned to the 
sea. The eggs are sticky and are laid while the lobster 
lies on her back, and so become attached to the hairs 
of these feathery processes. Berried crabs, prawns and 
shrimps may also be observed on the seashore in the 
spring and early summer. 

The mollusca, e.g. mussels, periwinkles, oysters, 
deposit their eggs in the sea-water. The eggs float to 
the surface, hatch out, and drift about with the other 
constituents of the plankton. The fully developed 
larvae fall to the sea bottom and become attached to 
seaweed and stones. 

The period of incubation of fish eggs varies according 
to the species of fish, and for the same species is pro- 
longed by a low temperature. Plaice eggs, fertilized in 
January, hatched in eighteen days ; others, fertilized in 
April, were hatched in nine days. 

All fish, on emerging from the egg, enter upon a larval 
stage in which they resemble each other very closely 
(see Fig. 1). (Thus, the larvae of plaice are quite 
symmetrical, like those of the cod or other round fish.) 
The newly hatched Jarvae drift helpless in the water for 


36 THE FISHING INDUSTRY 


two or three weeks, during which time they subsist upon 
the contents of the yolk sac, which they carry attached 
to their ventral surface. When this is exhausted, they 
feed upon the microscopic plankton which abound in 
the surrounding water. 

The characteristic forms of the different species of 
flat fish are gradually assumed by the young fish during 
the period of their larval development. The appearance 
of a newly-hatched young plaice exhibits little change 
during the first week or so, other than that due to the 
gradual disappearance of the yolk sac. The young fish 
grows very slowly, and, twenty-one days after hatching, 
is only 2 of an inch in length. For thirty days the 
development of the young fish is entirely symmetrical. 
During the succeeding fifteen days, the shape and appear- 
ance of the fish become profoundly modified. The left 
eye gradually moves upwards and forwards, until it 
attains its final position above and in front of the right 
eye. At the same time, the fish gradually acquires a 
new swimming position, finally swimming on what is 
really its left side. This left side becomes colourless. 
With these changes in form and habit, there proceeds a 
transformation in the diet of the fish. At twenty-one 
days it feeds upon the young stages of various crustacea. 
Gradually it acquires a taste for copepoda and the 
larvae of mollusca and crustacea. After its metamor- 
phosis is complete, it feeds upon various worms, small 
shrimps and small, bottom-living crustacea. The 
adult plaice feeds upon mollusca of the cockle and 
mussel families. 

The Migration of Fishes. Fishes, like birds, migrate 
over great distances at certain seasons of the year. In 
most cases, this migration occurs just before spawning, 
and is evidently connected directly with the spawning 
instinct, True marine fishes, such as the herring, 


CHARACTERISTICS AND HABITS OF FISHES 37 


haddock, plaice, cod, associate in vast numbers at 
spawning time, choosing a locality in which the tempera- 
ture and food supply will be favourable to the develop- 
ment of the young larvae. Generally, the spawning 
ground is in deep water. The eggs are buoyant, and 
drift up to the warm surface water and hatch out 
amongst the plankton. The herring differs from most 
other pelagic fish in laying its eggs in relatively shallow 
water, over a rocky bottom covered with seaweed. 
The eggs are denser than sea-water and are covered with 
an adhesive substance, so that they sink to the bottom 
and become attached to the stones and seaweed. 

It is at the time of this annual migration to the 
spawning grounds that the fish are most profitably 
caught, for not only are they gathered together in large 
numbers, but, just before spawning, the fat content and 
general condition of the fish, and therefore its food 
value, reacha maximum. After spawning, the food value 
of the fish is at a minimum, and remains comparatively 
low until a few months before the next spawning. 

The plaice migrates in the autumn from the feeding 
grounds in various parts of the North Sea to the spawn- 
ing grounds near the Straits of Dover. Spawning takes 
place between December and March. In the spring 
and summer it returns northwards to the feeding 
grounds in the centre of the North Sea. 

In the Irish Sea, there are two distinct annual migra- 
tions of plaice. The first occurs in summer (from June to 
September), the larger plaice moving from the warmer, 
shallow water inshore to the deeper, cooler waters 
offshore. In winter and spring, (from October to May), 
the mature plaice migrate from Morecambe and Liver- 
pool bays to the spawning ground in deep water to the 
North-East of Douglas (Isle of Man). 

In winter, also (from November to January), a large 


38 THE FISHING INDUSTRY 


number of plaice gather in Red Wharf Bay, off the north 
coast of Anglesey, probably because it is sheltered from 
the prevailing south-east winds. In February they 
commence their spawning migration round the coast 
of Anglesey to Cardigan Bay. 

Certain species of fish, instead of migrating from one 
part of the sea to another, migrate from the sea to rivers 
(anadromous), or from rivers to the sea (katadromous), 

Thus, in the spring or autumn, according to species, 
the anadromous salmon and shad ascend rivers to spawn. 
The eggs are deposited on clean gravel in clean water, 
where they are likely to remain undisturbed. The 
salmon does not feed when in the river, and after 
spawning, becomes very thin and in poor condition, 

The Alaskan salmon, from which the bulk of American 
canned salmon comes, exists in five species. It has a 
similar spawning habit to the British salmon, except that 
the same species always tends to use the same rivers. 
Once having spawned, the fish dies, so that the parents 
never see their offspring. The young larvae hatch out 
in the fresh water and make their way to the sea, where 
they pass the whole of their lives until they are mature, 
some years later, and then, in their turn, ascend the 
rivers to spawn. 

Eels are normally fresh-water fish. After living for 
six Or seven years in rivers and ponds and streams, they 
become mature and migrate to the sea to spawn. This 
spawning always takes place in deep water (over five 
hundred fathoms), the particular region chosen depend- 
ing upon the species. Eels from the British Isles and 
North-West Europe spawn in deep Atlantic, some 
hundreds of miles west of Ireland. In the autumn, the 
mature eels move down the rivers to the sea. When 
approaching maturity, the yellowish coat of the eel 
changes to silver. These “ silver” eels pass into the 


CHARACTERISTICS AND HABITS OF FISHES 39 


sea and are never seen again. It is probable that the eel 
only spawns once in its life and then dies. The spawn 
floats to the surface and hatches out into curious little 
transparent, leaf-shaped larvae. These larvae develop 
rapidly into elvers and commence the return journey 
to the shores and rivers. In the spring, the young eels 
ascend the rivers in enormous swarms. Many of them 
leave the rivers and travel over damp ground and grass 
to isolated pools and lakes. It is probable that the 
eels that are found in the Thames travelled overland 
from the Severn. 

The Baltic flounder migrates in winter from rivers and 
estuaries to the open sea, and spawns in spring in deep 
water. It returns in the summer when the spawning 
is over. By observing the movements of marked fish, 
it has been shown that the fish move at an average rate 
of from three to four miles per day. During its sea- 
ward migration, the flounder takes no food, but uses the 
material stored up in its tissues for the development of its 
reproductive organs. 

In addition to these spawning migrations, there are 
migrations that are prompted by a search for food, or 
for warmer or colaer water. 

In northern ana temperate seas, the surface water 
grows warmer with the spring. This warming influence 
spreads northwards from the equator, producing what is 
known as the annual wave of sea temperature. A 
direct result of the rise of temperature and the increased 
sunshine is a rapid increase in the amount and quality 
of the plankton. It is not surprising, therefore, that 
fish migrate in the wake of this annual wave of sea 
temperature, attracted by the increased food supply, 
and possibly, also, by the warmer water. 

The mackerel is a southern fish, and prefers the warm 
water of the Mediterranean and West African coast. In 


40 THE FISHING INDUSTRY 


spring, as the wave of rising sea temperature travels 
northwards, it migrates to the English Channel and the 
North Sea. This migration is often directly associated 
with the presence, in large quantities at that season, of 
a particular kind of copepod in the surface water of the 
English Channel. 
Phosphorescence. Many marine creatures, ranging 
from deep-sea fish living in the dark abysses of the ocean 
to various species of the minute plankton drifting in 
the surface water, possess phosphorescent organs, which 
emit light of low intensity similar to that of a glow- 
worm and firefly. In many cases the light appears to 
possess some important function, and highly specialized 
organs are developed. In such cases the light is only 
emitted in response to some stimulus—thus, the 
phosphorescence of the surface water of the sea, when 
disturbed by the blade of an oar, is due to the distur- 
bance of myriads of minute planktonic organisms, 
equipped with phosphorescent organs, either protozoa or 
protophyta ; many pelagic copepods are phosphorescent. 
In other cases, phosphorescence appears to be a more or 
less accidental by-product of some other process, and 
of little or no significance. The substance which pro- 
duces the glow is contained in the slimy secretion 
produced by the epidermal glands of the fish, and, as 
phosphorescence can only occur in the presence of 
oxygen, it is evident that the light is produced by the 
slow oxidation of this substance. The colour of the 
light emitted by marine organisms is generally blue or 
light green, but red and lilac also have been observed. 
The distribution and colour of the light or lights produced 
by individual fish vary with the different species. In 
many cases it would appear that these points of light 
provide the means by which fish recognize each other 
in the dark depths of the ocean. Some fishes possess 


CHARACTERISTICS AND HABITS OF FISHES 41 


highly developed phosphorescent organs known as 
photophores, consisting essentially of a group of gland 
cells that secrete the phosphorescent fluid. These 
organs are generally distributed in rows along the sides 
and ventral surface of the fish. Some fishes possess 
more complex and highly developed organs containing, 
in addition to the gland cells, a system of blood vessels 
and nerves, a transparent, protecting membrane and 
reflector, an iris-like diaphragm and a lens. These more 
complex organs are generally larger and less numerous 
than the simpler ones. Possibly they are used to 
search for, or to attract, prey. 

The phosphorescence of decaying fish and meat is 
due to the presence on the fish or meat of certain bac- 
teria of putrefaction, which are themselves phosphores- 
cent. When seen under the microscope, the individual 
bacteria appear as shining points of light. 


4—(1457H) 


CHAPTER III 
METHODS OF FISHING 


FIsH may be captured with spear, trap, line or net. 
Which of these methods is employed necessarily depends 
very much upon the size and habits of the fish, and upon 
the skill and available equipment of the fishermen. 

Spears and traps were used in prehistoric times and 
survive to this day in various forms, e.g. harpoons, 
lobster pots, hedge baulks, fishing weirs and the various 
ingenious traps and entanglements that are used by 
primitive races in all parts of the world. The logical 
development of the spear and the trap into the line and 
the net was made possible by the invention of string. 

To design and construct a trap, it is generally necessary 
to know something of the habits of the fish to be caught. 
Hedge-baulks and fishing weirs are fairly extensive 
enclosures made of brushwood, basket work, stakes or 
stones, constructed on the foreshore in such a way that 
at high tide the sea carries the fish into the enclosure and 
leaves them there when it recedes. These fishing weirs are 
probably the primitive origin of most forms of fishing 
nets. 

The crab or lobster pot or creel is constructed of 
basket-work, in shape somewhat like a safety inkpot, 
so that the lobster or crab can easily enter it, but, once 
in, is unable to escape. Lobster pots, suitably baited 
with fish and weighted, are distributed over the fishing 
ground—a rocky bottom full of crevices—from small, 
open boats, and are gathered the next day. 

Fishing with hook and line is also a very ancient method. 
Before the discovery of metals, the hooks were made of 

42 


METHODS OF FISHING 43 


bone. Some people—notably the Chinese—frequently 
use unbaited hooks, and rely upon the jerk of the hook 
at the right moment to secure the fish. Generally, 
however, the hook is suitably baited, the method being 
used chiefly for fish that seek their food by scent or 
sight, e.g. cod and shark. Lime fishing for cod is still 
employed on a large scale off the North of Scotland 
and the coast of Newfoundland. 

In lining, the fish are caught individually. A “line” 
may be as much as seven miles long. Short pieces of 
line from two to three feet long are attached to it at 
regular intervals. These lines are called the “ snoods,” 
and carry the hooks. The line is usually shot at night, 
and fished in the morning. In most cases line fishing 
is rapidly being superseded by trawling. 

The invention of netting marked a notable advance 
in the primitive development of the fishing industry. 
The net in all its various forms and applications is the 
characteristic and all-important implement of the 
fishing industry. A net may be used either to surround 
a fish and drag it out of the water, as in seining or 
trawling, or it may be used to enmesh the fish, as in 
drift netting. The rise and development of the sea 
fishing industry has been due very largely to the gradually 
improved efficiency of the net. 

Nets were originally used on the shore. A long 
strip of netting was attached to upright stakes, to form 
an enclosure with an opening towards the sea, con- 
structed like a fishing weir in such a way that the fish 
enter the enclosure at high tide and are unable to 
escape. Such devices constructed on shore are known 
as “fixed engines”; they include stake nets, poke 
nets, stream nets and purse nets. The net may simply 
form the wall of an enclosure (stake net). This enclo- 
sure may be furnished with a pocket at one corner 


44 THE FISHING INDUSTRY 


(poke net). It may consist essentially of one long, 
deep pocket kept open by rings or stakes at intervals 
(purse and hose nets). It may be simply a wall of netting 
into which the fish thrust their heads ; owing to their gill 
openings they are unable to withdraw and so become 
entangled (stream net). 

The first development of a movable net was the seine 
or drag net. The seine is a semi-circular drag net, 
which is shot in shallow water so as to enclose an area 
of water close to the shore. It is then hauled ashore, 
and gathers up the fish that are in the enclosed area of 
water. Such a net is limited to inshore use. Generally, 
a line is attached to each end of the net. The free end 
of one of these lines is made fast to the shore by a stake, 
and the net is paid out from a small boat. When the 
whole of the net has been paid out, the boat travels 
round until the net forms a semi-circle of which the 
diameter is parallel to the shore ; the net is then hauled in. 

The seine net was used in ancient times by Phoenicians, 
Greeks, and other Mediterranean peoples. Various 
types of seines are in common use to-day. In Denmark 
a seine net is employed to catch eels and plaice. On the 
Cornish coast pilchards are caught with a large seine 
up to two hundred fathoms long and eight fathoms 
deep. In the United States a seine is used in water 
of any depth to catch mackerel. Rings are attached 
to the footrope of the net, and by passing a line through 
these rings and drawing it tight, the net is transformed 
into a bowl of netting. This is called the purse seine. 

The seine was first improved by the addition of a 
pocket at its centre. Then the sides or wings were 
gradually lengthened, until finally it developed into a 
deep, conical, bag-shaped net, furnished with long 
arms or wings. This was dragged along the bottom, 
behind a boat in full sail, The net was weighted and its 


(OSLI 99419) DNTIMVUL 
6 ‘DLT 


46 THE FISHING INDUSTRY 


mouth kept open by attaching its upper edge to a beam 
of wood (beam trawl). When the net was full of fish, it 
was run ashore. Ultimately, instead of drawing the 
net ashore, the fishermen remained at sea and hauled 
the net on board with a winch. In this way the seine 
net gradually developed into the trawl net. The trawl 
net marked a big improvement, for it could be fished in 
deeper water further from shore, and thus greatly 
increased the scope of fishing operations, and led to the 
rapid growth and improvement of demersal fishing. 

Trawling is said to have been invented at the end of 
the seventeenth century by the Brixham fishermen. 
The first trawlers were quite small vessels, and were 
followed towards the end of the eighteenth century by 
the smack. The smack reached its maximum size and 
efficiency at about the middle of the nineteenth century. 
Some of the smacks that are still fishing from Brixham— 
durable, seaworthy, and with beautiful lines—are 
probably a hundred years old. 

In 1870, there were a thousand first-class smacks in 
the North Sea, three hundred in the English Channel, 
and over a hundred in the Irish Sea. 

The smacks were fitted with a tank in the well of the 
ship, in which the fish were kept in sea-water and 
brought in alive. In Denmark to-day, plaice are 
brought ashore and sold alive. 

The subsequent development of trawl fishing has been 
in the construction of larger nets, worked by mote 
powerful trawling vessels driven by steam. 

The size of beam trawl that can be worked by a large 
sailing smack is limited by the trawling power of the 
vessel, and also by the difficulty of constructing and 
handling very long beams. The maximum length of 
beam in general use by sailing smacks is fifty feet. The 
length of the net, from its mouth to the narrow of 


METHODS OF FISHING 47 


“cod” end, rarely exceeds a hundred feet. To each 
end of the beam is attached a triangular trawl-head of 
iron, which moves along the ground and serves to keep 
the beam about three and a half feet above the ground. 
These trawl crossheads are attached to the ship by 
bridles and warp. 

The upper edge of the net is attached to the beam, the 
lower edge being attached to a stout rope—the foot- 
rope—the ends of which are made fast to the crossheads. 
This foot-rope, being considerably longer than the beam, 
sweeps along the ground abaft of the beam, to form a 
deep curve known as the “‘ bosom” of the net. The 
result is that, when the foot-rope disturbs the fish so 
that they leap to avoid it, the beam has passed on 
overhead and they leap into the net. 

Pockets are formed in the sides of the net by lacing 
the top and bottom together for about two-thirds of the 
distance from the mouth of the net towards the cod end. 
The mouth of a pocket is at the cod end of the net, so 
that fish reaching the cod end and attempting to return 
to the mouth of the net, generally enter the pockets. 
A flap of netting suspended some distance inside the 
mouth of the net serves as a valve. It is easily lifted 
by the incoming fish, but tends to prevent their escape. 

The netting is of hemp, the mesh gradually increasing 
from one inch at the cod end to about two inches near 
the mouth, and is preserved with tar. 

When fishing, the vessel moves ahead at a steady, slow 
rate of from two to three miles per hour, dragging the trawl 
behind it. Smacks always trawl with the tide. If they 
trawl against the tide, the net is lifted from the ground. 

During fishing the cod end is closed by the cod line, 
but at the conclusion of the trawl the net is hoisted 
aboard, mouth upwards, and the contents are discharged 
upon the deck by drawing the cod line. 


48 THE FISHING INDUSTRY 


The otter trawl that is used by modern steam trawlers 
is from seventy to one hundred and twenty feet wide 
across the mouth, according to the character of the 
fishing, and a hundred and ten feet long from the mouth 
to the cod end. The otter trawl is shown in Fig. 17. 
It differs from the beam trawl in that its mouth is kept 
open, not by being attached to a beam, but by otter 
boards, which are attached one to each side of the mouth 
of the net. These are attached to the net and to the 
warps by which the net is towed in such a way that the 
pressure of the water upon them causes them to diverge, 
thus keeping the mouth of the net open. The size of a 
beam trawl is necessarily limited by the length of beam 
obtainable. The size of the otter trawl, however, is 
obviously only limited by the power of the steam 
trawler. The otter boards measure 11 ft. by 4 ft. 6 ins., 
are shod with iron, and weigh 15cwts. each. The 
warps, as the ropes are called which attach the otter 
boards to the ship, are from three hundred to a thousand 
fathoms long—generally a little over three times as 
long as the depth of the water in which the trawl is to 
be used. Each board is attached to the steamer by a 
separate warp. The upper edge of the mouth of the 
net is attached to a strong rope, called the “ head” 
rope. The lower edge of the mouth of the net is also 
attached to a strong rope, called the ‘‘ foot” rope. As 
in the beam trawl, the foot rope is considerably longer 
than the head line, and forms a bosom. Traps and 
pockets also are inserted in the sides of the net. When 
trawling on rough ground, the foot rope is furnished 
with large, heavy, wooden rollers, called the “‘ bobbins.” 

Trawl fishing, until quite recently, was almost entirely 
confined to demersal fish, such as god, plaice, haddock 
and halibut. In recent years, however, considerable 
quantities of herring have been caught by trawlers. 


(OSZI 9419) ONILAINGa 
OL ‘21 


50 THE FISHING INDUSTRY 


Drifting. The drift net is essentially a completely 
submerged, vertical curtain of netting, one end of which 
is attached to a boat called a drifter. The net extends 
in a straight line from the boat, and may be as much as 
three miles long. Unlike the trawl net, the drift net 
generally catches one kind of fish only—either herring 
or mackerel—drift net fishing being carried on at a 
time when these fish come together in shoals near the 
surface for the purpose of spawning. The trawl 
obviously only captures fish living at the bottom. At 
the same time, of course, it captures all the fish at the 
bottom, whether immature, or useless star fish, etc. 
The drift net, on the other hand, is generally used for a 
particular kind of fish—herring, mackerel, sprat—and 
only catches fish above a certain size. 

A drifter may be as much as 90 ft. long, with 20 ft. 
beam and 10 ft. draught. Its foremast is so constructed 
that it may be lowered when the vessel is steaming 
against a head wind, or when it is fishing. The ordinary 
sailing drifter is rapidly being superseded by the steam 
drifter, partly because the greater power of the steam 
driven boat increases its capacity and scope, and, further, 
owing to the centralization of the industry at a few big . 
ports at certain times of the year, these harbours are 
so crowded that it is almost impossible to handle a 
sailing drifter in them. Many of the larger sailing 
drifters have been equipped with petrol engines which 
largely discount this disadvantage. A steam drifter 
can travel at from 11 to 12 knots, and both steamers 
and sailers carry a fishing crew of seven men and a boy. 

Inshore Fisheries. The development of steam fish- 
ing—trawling and drifting—has resulted in the re-group- 
ing of the fishing industry into two well-marked divisions. 
Fisheries, whether trawling, drifting or lining, that are 
carried on in deep water far from shore in large steamers, 


ANOLSAN1IOA LV MALVOM-ATIONIS V 
Il “SM 


52 THE FISHING INDUSTRY 


for the most part owned by limited liability companies, 
are known as offshore fisheries. The fisheries of the 
seashore, carried on by small, privately-owned, sailing 
smacks and cutters within territorial waters, are distin- 
guished by the term “ inshore fisheries.”” The inshore 
fisheries are mainly for shellfish, crabs, lobsters, shrimps 
and immature deep sea fish such as plaice, soles, flounders, 
dabs, codling and sprats. 

Shrimps and whiting are caught with trawl nets of 
25 ft. beam or less, and of about }in. mesh. The net 
is generally drawn behind a small cutter, but frequently 
it is used in shallow water with a horse and cart. These 
nets are generally made of flax or cotton, and are either 
tanned or tarred, in order to preserve them. 

Smaller, fine-meshed, traw] nets are used for catching 
shrimps and also immature plaice, soles and dabs. 
These shrimp nets are either attached to a long handle 
and pushed through the water in front of the fisherman 
(push nets), or drawn behind a small boat or a horse 
and cart (trawl nets). 

Larger fish are sometimes caught in shallow water 
by casting a net over the fish so as to enclose it (cast 
nets). The fisherman of the Eastern Mediterranean uses 
a cast net with conspicuous skill. The net is essentially 
a circular disc of netting, to the circumference of which 
small weights are attached at regular intervals. A 
cord is attached to the centre of the net, and the fisher- 
man, standing knee-deep in the water, grasps the net by 
its centre, swinging it round his head, and casts it so 
that as it approaches the water it opens out, and with 
a soft splash sinks through the water until it lies out- 
stretched over the fish. It is then drawn up by the 
string attached to its centre, and the weighted edges fall 
together enclosing the fish. 

Fish are often caught on shores and in rivers by 


METHODS OF FISHING 53 


causing them to pass between converging walls of stakes . 
or basket work, until they enter an enclosure, the floor 
of which is covered by a net. When the fish have 
gathered in the enclosure, the net is pulled up. 

The simplest form of inshore fishery is that for peri- 
winkles, in which they are simply picked off the rock. 
Mussels live on the sea bottom, on the lower half of the 
foreshore. They generally attach themselves to a 
stone by a thread. They are usually collected at low 
tide by hand or, when submerged, are raked from the 
bottom. The rake is from 2 to 3 ft. wide, andis furnished ~ 
with teeth 10ins. long, the back of the rake being 
covered with netting. Sometimes the mussels are 
submerged even at low water and then a short rake is 
used. 

Cockles live about an inch or so below the surface of 
the sand, and maintain a connection with the water 
above by means of small tunnels inthe sand. They 
occur abundantly in many places between high and low 
watermark. When the cockles are abundant they are 
raked out of the sand, the rake being from 10 ins. to 
1 ft. wide, with teeth 1 in. long. The cockles are 
riddled, the small ones being rejected. When the cockles 
do not exist in such large numbers, they are obtained 
by means of a “jumbo.” This is essentially a block 
of wood, 3 or 4 ft. long, and 1 ft. wide, furnished with 
two upright handles. The jumbo is rocked to and fro 
on the surface of the sand, with the result that the 
cockles are gradually worked up to the surface. 


CHAPTER IV 
THE HERRING FISHING INDUSTRY 


HERRINGS abound in the waters round the coast of 
Great Britain. Ordinarily they are widely scattered 
in deep water, but at certain times of the year they come 
together in shoals in the warmer water near the surface 
for the purpose of spawning. It is at this time that 
they are of greatest value for food purposes and, being 
gathered together in shoals, are most economically 
caught. 

The herring may spawn at any time of the year. 
In this respect it differs from all other British marine 
food fishes. Most British caught herrings spawn during 
September and Autumn. Very little spawning takes 
place during late winter and spring, ie. just after 
minimum sea temperature. Each local race (or species) 
appears to spawn at a constant time of the year. The 
date of the annual spawning, and hence the herring 
fishing season, varies from point to point round the coast. 
Herrings caught at different places show well-marked 
differences in appearance and quality, which are evidently 
due to differences in species and feeding ground. The 
food value of the herring will depend also upon the 
time of the year at which spawning occurs. Thus, in 
the Irish Sea, there are two races of herrings—the Manx 
and the Welsh. The Manx herring spawns in summer 
(September), and is rich in fat; the Welsh herring 
spawns in winter (November and December), and is 
poor in fat. MHerrings are first caught off the West 
coast of Scotland in the waters round the Hebrides. 
This fishing begins in the middle of May, its chief centre 

54 


THE HERRING FISHING INDUSTRY 55 


being Stornoway. In early June herrings are caught 
in the waters round the Orkneys and Shetlands, and 
then in succession off Wick, Fraserburgh and Peterhead, 
and the Northumberland coast (Eyemouth, Berwick 
and Sea Houses). About the middle of July the herring 
fishery season begins at Blyth and Shields, and at 
Scarborough and Grimsby towards the end of July. 
At Yarmouth and Lowestoft it begins early in October. 
The last herrings to be caught in British waters are 
caught round Devon and Cornwall in December. 

Of the various kinds of herring obtained at different 
places, the largest and finest fish are those caught in 
Downings Bay off the North of Ireland, Castle Bay off 
the Island of Barra in the South Hebrides, and off the 
Shetlands. Herrings differ very much in their suitability 
for handling, keeping and curing. Most herrings have 
a small gut which is easily removed without seriously 
damaging the body of the fish. Blyth and Shields her- 
rings, however, are very rich and fat, and have a specially 
big, distended gut. Such herrings are difficult to clean 
because, when this large gut is removed, the belly of thefish 
is so tender that it is often broken. Herrings caught off 
these ports are fat and oily, so that many are landed in 
a broken condition. The Yarmouth herring is firm and 
hard, and is the best adapted for handling and curing. 

Unlike that of the cod, the flesh of the herring is very 
rich in oil and fat. The body flesh of the herring con- 
sists essentially of two well-developed layers of adipose 
tissue, alternating with two layers of muscular tissue. 
The fat in this adipose tissue is very liquid and oily, 
and tends to make the fish tender. The actual amount 
of body fat varies widely throughout the year. It 
gradually rises to a maximum before spawning takes 
place, and diminishes slightly before spawning and 
afterwards rapidly toa minimum. Thus, the fat content 


56 THE FISHING INDUSTRY 


of Manx summer herrings is about 2 per cent during 
the winter, and rises rapidly in June and July, until in 
August, just before spawning, it is over 30 per cent. The 
herring has a small liver which also contains some oil. 

Fishing is carried out with drifters. Practically 
all drifters to-day are steam-driven, although recently 
a number of motor-driven drifters have come into use. 
Motor-driven drifters are mostly sailing boats con- 
verted. Each drifter carries a crew of seven men, 
including the skipper and engineer. The boats are 
largely privately owned and the crew work on a share 
basis. A number of boats are owned by companies. 

The boats from the various fishing ports work round 
the coast, following the fishing from port to port. At 
Yarmouth during the fishery season there are about 
1,200 drifters from nearly all the fishing ports round 
the coast. Stornoway, Wick, Fraserburgh, Peterhead, 
Aberdeen, Berwick, Whitby, and Yarmouth are all 
well represented. 

Each boat carries from 70 to 80 nets. The nets are 
approximately 1 in. mesh. Each net is essentially a 
long rectangular curtain, hanging vertically in the water. 
Its upper edge, which is about 55 yds. long, is buoyed 
up by about 80 to 84 corks distributed equidistantly 
along it from end to end. The net is about 6 yds. 
wide. Each net hangs with its upper edge about 2 
fathoms below the surface of the water, being attached 
at each corner to two pellets or bladders, resembling 
large footballs, and serving as floats. 

Fishing nets and sails are often coated with warm 
gelatine, and then immersed in a strong solution of tan- 
nin. This renders the gelatine insoluble and preserves 
the nets against the attacks of destructive organisms. 

When fishing, the boat takes up a position stern on 
to the tide, The nets are paid out over the bow and 


UALAIUG ONINAAH 
GL “OM 


5—(14578) 


58 THE FISHING INDUSTRY 


connected up in line, and carried by the tide till they 
form one long line, one end of which is attached to the 
drifter. The position of the nets is indicated by the 
line of bladder floats. 

The fish swim against the nets, push their heads 
through, and then, owing to their gill openings, find 
that they cannot withdraw their heads, and in this way 
are caught in enormous numbers. Generally, fishing 
goes on all night, and in the morning the nets are hauled 
in, and, together with the attached fish, are thrown into 
the hold situated amidships. The drifters then return 
with all possible speed to the fish wharf. While the 
boats are returning to port, the men draw the nets 
from the hold and shake them free from any entangled 
fish. When the drifter reaches port, she moors along- 
side the fish wharf, bow on, and unloads her cargo 
of fish, using her derrick mast. The fish are unloaded 
in a round basket which is stamped by the Fishery 
Board’s officer as holding a quarter of a “‘cran.’’ The 
word “‘cran’”’ is derived from the ‘‘ crown” branded 
by the Fishery Board’s officer on each of the two wooden 
shafts in the basket. 

The cran is the measure which is universally used in 
the trade. At Yarmouth and Lowestoft originally 
herrings were counted out and sold by the “last.” A 
cran averages from 900 to 1,000 herrings and weighs 
approximately 3cwts. A “last” equals ten crans, 
and originally consisted of 13,200 herrings, counted out. 
_ This method, of course, was too slow and has now been 
. abandoned. 

The herrings, as they are removed from the ship, 
are put into special baskets called “ swills,” each swill 
holding half a cran. The swills containing the day’s 
catch are arranged in rows on the fish wharf, opposite 
each drifter. It is a great sight to see about four or five 


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60 THE FISHING INDUSTRY 


hundred drifters lying, bow on, alongside the fish wharf 
for about 24 miles, all unloading fish as fast as they can. 

A good day’s catch would consist of about 90 crans. 
A good catch, therefore, would average about 100,000 
herrings, and would weigh about 13 tons. Some boats 
come in with as many as 160 crans of fish, and the 
total ‘‘ cranage”’ for a day may exceed 30,000. The 
total catch for Yarmouth on a good day would be about 
30,000,000 herrings, weighing about 4,000 tons. 

Sometimes when the catch has been poor, the 
drifters remain out on the fishing grounds for another ~ 
day, rather than come home with a small catch. In 
this case, the two catches are kept separate, the first 
catch being called ‘‘ overdays.’’ Overdays are worth 
about half the price of fresh fish and are, of course, less 
suitable for high grade curing. 

After it has been purchased by the curer, the fresh 
herring may develop into a salted herring, a red herring, 
a bloater, or a kipper, depending upon the degree of 
salting and smoking to which it is subjected. Herrings 
are-sometimes put into cold storage, to be withdrawn sub- 
sequently as occasion demands, either to be salted or, 
more frequently, to be consumed fresh. Cold storage 
affords a convenient method of preserving herrings 
when there is a glut, for at such times it is often impossible 
to deal with the herrings adequately in the ordinary 
curing yards. 

Salted Herrings. The fresh herrings are delivered 
to the curer’s yards. Here, the fish are emptied into 
broad, shallow troughs, which generally run from end 
to end of the yard. The troughs are about 4 ft. wide, 
and are generally made of wood and arranged at a 
convenient working height. Usually, the trough is 
situated just inside the boundary wall, and the fish are 
delivered into it through large openings in the wall. 


Fic. 14 
SCOTTISH FISHER GIRLS 


62 THE FISHING INDUSTRY 


The fish are gutted and salted by Scottish girls—many 
of them from the Hebrides—who come to Yarmouth 
and other places in the season for this purpose. These 
girls are all brought up in Scottish villages, and are 
extraordinarily expert in all the operations connected 
with the cleaning and salting of the fish. They work in 
crews of three, and take very good care that each 
member of the crew is a good worker, as they are paid 
according to the amount of work they do. 

Each girl receives 25s. a week as a kind of subsistence 
allowance, and is paid 1s. a barrel for the work she does. 

As the fish are delivered into the gutting trough, they 
are liberally sprinkled with salt, thus enabling the women 
to grasp the fish easily, as otherwise the fish are too 
slippery for quick handling. 

The women work standing in a row beside the trough. 
They pick up a fish, gut it by inserting a sharp knife 
just below and behind the gills, and with a quick, upward 
cut, bring away the gut. The guts drop into small 
tubs placed in front of each worker, and are collected 
periodically and sold to manufacturers of manure. 
Behind each woman are three shallow tubs or baskets, 
and after she has gutted a fish, she throws it behind her 
into one of the three tubs, according to its quality and 
size. In this way, the two operations of gutting and 
selecting the fish are combined. As the tubs of gutted 
fish become filled, they are taken away by other girls 
to the barrel packers, and are packed in separate barrels, 
according to quality or size. The barrels are arranged 
in long rows, generally parallel to, and at some distance 
behind, the gutting trough. A girl will pack about 
three barrels in an hour. 

The gutted fish are first of all emptied into large, 
shallow tubs called ‘‘ rousing tubs,” placed just behind 
the row of barrels, and are again sprinkled with salt. 


THE HERRING FISHING INDUSTRY 63 


The packer takes an armful of fish from the rousing 
tub and drops them into the barrel. Each time the 
fish are taken from the rousing tub the contents of the 
tub are well stirred up. The fish are then packed in 
the barrel in layers, bellies upward, and each layer 
is liberally sprinkled with salt. In this way each 
individual fish is first of all thickly coated with salt in 
the rousing tub, and adjacent layers of fish in the barrel 
are also separated by a layer of salt. In this packing 
process, it is important that the fishery salt used should 
be coarse, reasonably hard, slow in dissolving and 
present in considerable excess. It should be coarse 
enough to prevent thefish from touching each other, 
thus enabling the brine to penetrate to every part. It 
should be hard enough to withstand the pressure of the 
fish in the barrel. It should dissolve slowly, so that the 
salting process takes place gradually, enough salt 
remaining undissolved throughout the process to keep 
the fish from touching. Altogether, about I cwt. of 
salt is used for each barrel of herrings cured. 

The barrel, when fully packed, is covered over and left 
for about eight days. During this time, the salt extracts 
water from the fish and dissolves in it to form a saturated 
brine. The efficiency of this salting process necessarily 
depends upon the salt being present in considerable 
excess, so that the brine formed is kept saturated, and 
consequently continues to withdraw water from the fish. 

At the end of eight days, the barrels are opened, 
an inch hole is drilled in the side at the bilge, and 
the pickle allowed to run out. It is found that, 
owing to the withdrawal of water from them, the her- 
rings have shrunk considerably, and some more salted 
herrings are added to the barrel, until it is full again. 
It is then fastened down permanently, turned over on 
its side and filled with brine pickle, and corked up. 


64 THE FISHING INDUSTRY 


The brine pickle which is formed during the eight 
days is not allowed to run to waste, but is used for 
filling up the barrels afterthey have been repacked. 
This brine pickle contains amino bases, together with 
small quantities of coagulable proteids, and is of distinct 
nutritive value. The Poles and Russians, who are 
great consumers of these salted herrings, actually use 
the pickle as a kind of sauce or gravy, dipping their bread 
init. This, together with the general demand for salted 
herrings in these two countries, may very largely be due 
to the comparative scarcity and high price of salt there. 

A cran of herrings (about 1,000 fish, weighing 
approximately 3 cwts.) uses up 1 cwt. of salt and, 
when completely salted, just fills a barrel. The curer 
estimates that 5 to 6 tons of salt will be sufficient for 
100 crans of herrings. Herrings salted in this propor- 
tion should be exported and consumed before the warm 
weather comes, as they are liable to decay if the tempera- 
ture rises above 70° F. The herrings that were packed 
for the British Government (1920-1921) were salted more 
heavily than usual (7 to 8 tons of salt per 100 crans), 
as, owing to the uncertain condition of the Russian and 
German markets, it was necessary to keep some of the 
fish in stock for a considerable time. Such a heavily- 
salted fish would be unpalatable to the home consumer. 

In Yarmouth and Lowestoft, and also in Scotland, 100 
crans of herrings should fill, when cured, from 125 to 
130 barrels. 

Herrings are sometimes salted at sea, 1 ton of salt 
being used toeach last (10 crans) of herrings. Such 
herrings are mostly used to make “ red herrings.” 

Red Herrings. A considerable trade in red herrings 
is done with the Mediterranean and the Levant. For 
this trade, the fish must be thoroughly smoke-cured, other- 
wise they will not keep in the comparatively warm climate. 


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THE HERRING FISHING INDUSTRY 65 


The fish are first of all dry-salted in concrete tanks about 
10 ft. square and 6 ft. deep, arranged under the floor of 
the curing house. Fresh fish and salt are simply thrown 
in and mixed up, and left to develop their own pickle. 

Generally speaking, 1 ton of salt is used to 10 crans 
of herrings, and each tank will hold from 20 to 30 crans 
of the fish. The fish should be left in these salting 
tanks for five days at least ; sometimes, of course, they are 
left for months, according to the trade, in which case the 
tanks practically serve as storage tanks for the salted 
fish. The fish are removed from the tank as required, 
washed, and put on “speets” and smoked. A 
“speet ” is a wooden rod about 3ft. 6ins. long and 
pointed at one end. The fish are threaded on the speet 
through the gill openings and mouth, each speet holding 
from 20 to 30 fish. The speets are then stacked horizon- 
tally on racks in the smoke house “ loves ” (lofts), about 
6ins. apart and about 12ins. above each other, until 
the smoke house is filled from the roof to within a few 
feet of the floor. When the smoke-house is filled, fires 
are lighted on the floor. Generally, the fuel used is 
oak turnings, shavings, and sawdust. This material 
burns quickly, and gives a very resinous smoke which 
not only dries the fish, but also permeates it thoroughly. 

The rate of curing and the character of the finished 
product depend upon the temperature of the smoke, 
and the proportion of antiseptic resinous materials in 
it. When the oak or other suitable hard wood 
fuel is in the form of turnings or dust it burns quickly, 
and thus produces a fairly hot smoke, containing anti- 
septic substances—for example, guaiacol and creosol. 
Such a smoke will cure the fish quickly. 

If oak billets or logs are used they burn compara- 
tively slowly. The smoke, therefore, is not so hot and, 
since slow combustion in this case probably means 


66 THE FISHING INDUSTRY 


more complete combustion, the proportion of resinous 
constituents in the smoke is liable to be considerably 
diminished. When oak billets are used, therefore, 
curing takes place much more slowly. 

The temperature in the smoke house will also depend 
very much upon the prevailing weather temperature 
outside. In cold weather it is difficult to keep the 
temperature up sufficiently. The curing takes longer, and 
results in a hard cured product. In very warm weather, 
on the other hand, it is difficult to keep the temperature 
down, and a “ fired” fish is sometimes produced, i.e. 
one which is half-cooked and soft. Such a fish is 
clearly unsuitable for packing for export. 

Generally speaking, the temperature of the smoke 
should be such that the curing takes about 10 days. 

After smoking, the fish are taken off the speets and 
selected according to quality. Those which are large 
and perfect fetch a better price, and command an entirely 
different market from those which are damaged or broken. 

During the smoking of red herrings, the fires are lit 
each night, and simply allowed to burn themselves out. 

Bloaters. There are two kinds of bloaters: those 
intended for the home trade and those intended for the 
Mediterranean trade. For the home trade the herring 
is lightly salted by immersing it in brine for two hours 
or less. It is then dried in the smoke-house for one 
night, using billets. Unlike “reds” or kippers, it is 
not cured by the smoke, but simply dried. The bloaters 
for the Mediterranean trade are salted in concrete tanks 
in exactly the same way as red herrings, but, instead 
of being smoke-cured for 10 days or so, they are simply 
smoke-dried for two days. 

Kippers. Kippering is the only process in the herring 
industry in which the fish are split before curing. Fresh 
herrings (sometimes over-day herrings) are bought 


THE HERRING FISHING INDUSTRY 67 


early in the morning from the drifters and taken to the 
curing yard. They are split down the back, close to 
the backbone, and gutted and thrown into large, open 
baskets. The basket and its contents (about 50 herrings) 
are then plunged into a tank of running water, and 
violently agitated to wash blood and slime from the 
fish. The fish are then thrown into brine in large tanks 
about 6 ft. by 5 ft. by 4 ft., until the tank is full. Salt 
is then sprinkled on the surface, and the fish are left 
from half to one hour, according to their size. 

They are then hung on kipper speets. A kipper 
speet differs from a bloater speet. It is a square bar 
of wood about 33 ft. long, and of 1 in. square cross-sec- 
tion. It is supported horizontally. The split herrings 
are opened out and impaled upon hooks at intervals 
along each side of the speet. Each speet in this way will 
carry about eight or nine herrings aside. The speets are 
then stacked on racks in the “ loves” of the smoke-house, 
are smoked over-night, using fires of oak turnings and 
sawdust, and are packed the next morning in boxes. 

The herring is probably the most abundant food fish 
known. During the autumn herring fishery of 1920, over 
1,000,000 crans of herrings were landed at Yarmouth and 
Lowestoft. If we assume that one cran measure 
contains 1,000 herrings, we see that over 1,000,000,000 
herrings were caught in less than 4 months, and this 
probably represents only a small fraction of the number 
present on the fishing grounds. In 1913, 11,762,748 cwts. 
of herrings, of value £4,412,838, were landed in Great 
Britain. In the same year, the exports of herrings 
from the British Isles were as follows— 


Fresh herrings . 1,464,296 cwts. worth 1,212,493 
Cured herrings . 8,797,106 ,, ie 5,333,113 


Total - 10,261,402 ,, * £6,545,606 


68 THE FISHING INDUSTRY 


The quantity of herrings caught by other European 
countries is as follows— 


cwts. £ 

France (1911) \ - 7,846,503 529,739 
Germany (1913) Fresh . 148,354 75,738 

a » Salted . 1,030,039 563,033 
Holland (1911) : - 1,685,751 919,973 
Norway (1912) , . 4,404,400 580,570 
Denmark (1912) . ‘ 845,295 —s_- 140,051 
Sweden (1912) : - 861,420 205,555 
Belgium (1911). : 13,000 5,000 


16,834,762 3,019,659 


Na i Mal em 


Seal 


CHAPTER V 
THE NEWFOUNDLAND COD FISHERY 


THE cod is widely distributed in the northern and 
temperate seas of Europe and America. It lives close 
to the bottom, in from 25 to 50 fathoms of water, and 
feeds upon fish, small crustacea, worms and mollusca. 
The cod spawns in the Spring. Of the 4,000,000 or so 
eggs that are spawned by a single female cod, compara- 
tively few are hatched, and fewer still reach maturity. 
The young are about 1 in. long by the beginning of the 
summer, and become fit for the market at the end of the 
second year. Usually, the fish are mature at the end 
of the third year, and then measure about 3 ft. in length, 
and weigh from 12 to 20lbs. They are in the finest 
condition in October, November and December. 

In addition to its great value as a food fish, the cod, 
like the sturgeon, yields isinglass (a pure fish gelatine) 
from its swimming bladder, and oil from its liver. Cod- 
liver oil is largely used as a remedy for scrofulous com- 
plaints—probably owing to its content of vitamins. 
It is also used effectively in cases of pulmonary 
consumption. 

Cod is fished along the coasts of Newfoundland and 
Labrador, and on the Banks. The Banks stretch for 
about 300 miles in a south-east direction from the coast 
of Newfoundland towards the middle of the North 
Atlantic. They are swept by the cold Labrador current. 
A branch of the Gulf Stream passes over the southern 
portion of the Banks. These currents bring enormous 
quantities of plankton and small fish, which provide 
excellent food for the many varieties of fish and small, 


69 


70 THE FISHING INDUSTRY 


invertebrate, marine animals that inhabit the Banks. 
These, in their turn, provide abundant food for the 
cod. 

The cod, together with other demersal fish, including 
haddock, hake and pollack, is caught with baited hooks 
and lines. This fishery has continued with unbroken 
prosperity for nearly four centuries. In addition to the 
Newfoundland boats, a large number of American 
boats set out for the Banks from Gloucester (Mass.). 
Most of the boats are sailing boats of about 35 tons 
capacity, and of sturdy construction. Each boat 
carries eight dories—small row-boats about 15 ft. long— 
amidships. The crew consists of a captain and cook, 
and sixteen men—two for each dory. 

The ‘“ Banks” stretch for about 300 miles, by 200 
miles wide, in a south-easterly direction, towards the 
centre of the North Altantic. The depths in which the 
fishing is carried on range from 20 to 120 fathoms off 
the coast of Newfoundland, from 15 to 90 fathoms on 
the Banks, ana from 100 to 135 fathoms at the edge of 
the Banks. The vessel starts out for the fishing grounds 
with about 400 hogsheads of salt, and from 15,000 to 
25,000 Ibs. of bait. The bait is generally frozen squid 
and herring. Capelan is also used as bait, but has to 
be obtained at Miquelon, the last port of call before 
putting out to the Banks. The bait must be well iced, 
as the cod will not bite well if the bait be tainted. 

During the second trip, squid is used as bait and is 
caught on the fishing grounds. 

As the boat approaches the fishing grounds, the 
dories are made ready. Each dory carries four tubs of 
baited lines. A tub contains nine lines, each 50 fathoms 
long. When fishing, these lines are all strung together, 
so that each dory will run a string 1,800 fathoms long— 
about two miles. Each line carries about 90 hooks—that 


we el ee ene 


THE NEWFOUNDLAND COD FISHERY 71 


is, 3,200 hooks to each dory. A vessel with eight dories 
will thus set about 16 miles of line, carrying about 
25,000 hooks. The hooks are attached to the lines by 
means of shorter lines called “ gangings ’—in Scotland 
they are known as “ snoods ”—about 2ft. long. The 
complete line, as set by a dory, is called a “ trawl.” 

On arriving at the fishing grounds, soundings are 
made to determine the depth and character of the 
bottom. The best fishing is obtained over a gravel 
bottom. The trawls are then set while the vessel is 
in motion (a flying set), and if the fish are found to be 
abundant the vessel drops anchor. 

The flying set is carried out as follows: The dories 
are towed astern and, when the right spot has been 
selected, are droppped at regular intervals until all are 


away. Each dory as it is dropped rows off at right 


angles to the course of the vessel, and in the same 
general direction, throwing out its trawl as it proceeds 
until it is all set. The vessel then returns diagonally 
across the fishing grounds to the starting point, picking 
up the dories as their trawls are set. After a time, 
the dories are dropped again in the same order as before, 
and the men haul up the trawls and take the fish off. 
Each dory is then picked up in succession together with 
her catch. If this flying set is successful, and other 
conditions are favourable, the vessel drops her anchor 
and fishing proceeds. 

The manner in which the trawls are set depends 
upon the tide. They are always set as far as possible 
with the tide. Thus, the dories on the side of the 
vessel against which the tide is flowing row out against 
the tide, until they are about a trawl-length from the 
ship. They then set the end of the trawl at the point, 
and work towards the vessel. On the other side of the 
vessel the trawl is set from the vessel with the tide 


vy THE FISHING INDUSTRY 


towards: the dory. Each end of the trawl is attached 
to an anchor by a line 1 fathom in length, and to a 
buoy by a line 25 fathoms longer than the depth of the 
water at that point. Thus, the trawl is situated just 
above the ground. The trawls are set once a day and 
drawn three hours afterwards, or set in the afternoon and 
drawn the following morning. The shorter the time 
between setting and drawing, 'the better the condition 
of the fish. In hauling the trawl, one man stands in the 
bow of the boat and hauls in the trawl, detaching the 
fish, the other man receiving the trawl and coiling it. 
A dory carries on an average 1,000 Ibs. of fish, and may 
sometimes make two or three trips before the line is 
cleared. 

The fish are ‘‘ gaffed’”’ from the dories to the fishing 
vessel and are kept on deck, packed between division 
boards to prevent sliding or turning of the fish by the 
movements of the vessel. 

When the fish are all aboard, they are split and 
cleaned and salted down. The crew is divided into 
splitting gangs, each consisting of three men—the 
throater, the gutter, and the splitter. The throater 
grasps the fish by the head with the left hand, and, 
holding it with its back on the edge of a tub, cuts its 
throat just behind the gills, and makes a slit down the 
belly. The head is then broken off by downward pressure 
against the edge of the tub, and the fish is passed on to 
the gutter. He opens the belly with his left hand, 
removes the liver for oil, and teats out the viscera. The 
fish then goes to the splitter, who completes the ventral 
splitting of the fish and removes the backbone. 

After being well washed, care being taken to remove 
all blood, the fish are passed down a canvas chute into 
the hold, where they are carefully salted and piled in 
“ Kenches.”’ The fish are laid on their backs alternately 


THE NEWFOUNDLAND COD FISHERY 73 


nape and tail, salt being liberally sprinkled between the 
adjacent layers. Nearly 14 bushels of salt are used per 
100 Ibs. of fish. The pickle formed by the salt ana the 
juices of the fish drains away to the bottom of the 
hold, from which it is pumped overboard. As the 
kench or pile settles, more fish are added, so as to keep 
the compartment full. Kenching begins in the forward 
compartment of the hold, and is carried on from side 
to side of the vessel. Each kench is about 4ft. by 
7 ft., and the full height of the hold. The refuse is 
thrown overboard. 

In addition to the “trawl” fishing, many boats use 
hand-lines. For this purpose, the lines are somewhat 
smaller, and only 13ft. long. About 100 barrels of 
bait are taken (slack-salted clams obtained on the coast 
of Maine), any additional bait that may be required 
being caught on the fishing grounds—squids, hagdens, 
and clams taken from the stomachs of fish. 

When the vessel reaches the fishing grounds, the 
dories row away in all directions, each man for himself. 
The dory is anchored in water from 18 to 40 fathoms 
deep. Each fisherman uses two lines carrying two 
hooks a piece. The boats generally go out at sunrise and 
return to the fishing boat about six hours later. Two 
boatloads—that is, 2,000 Ibs. of fish—make a good 
day’s work. 

On returning to the vessel the fish are pitched on 
deck and counted, only cod of over 22 ins. length being 
considered. Smaller fish, and the “ shack ’—pollack, 
haddock, cusk and hake—being counted separately. 
The fish are then dressed and salted, as already 
described. 

In some cases, hand-line fishing is carried on from the 
deck of the fishing boat itself, while the boat drifts. Each 
man uses one line carrying two hooks. The bait 


6—!1457n) 


74 THE FISHING INDUSTRY 


consists of iced cockles, broken with a hammer. The 
positions on the deck are followed by the crew in rota- 
tion, to give all an equal chance. As the fish are 
“landed ”’ they are thrown on to the deck, each man 
keeping his count by cutting out the tongues and keeping 
them in a separate bucket. 

On the Georges Bank, south-east of Gloucester, 
which is one of the favourite fishing grounds, the fish 
are caught by hand-line from the deck of the ship while 
at anchor. Frozen herring are used as bait, when 
possible. All the fish caught on the Georges Bank are 
salted, except the halibut, which is iced. Some idea of 
the value of these grounds is gained from the fact that a 
single fisherman may take 500 fish in a day. The 
Georges Bank area yields about 70 per cent of the total 
catch, the Grand and Western Banks accounting for 
the remaining 30 per cent. Approximately 60 per cent 
of the fish are brought in iced, and 40 per cent 
salted. 

On returning to port the fish are pitchforked on to 
the wharf, and sorted into snappers (less than 16 ins. 
from nape to tail), medium, and large (over 22 ins.) 
Generally, they are divided as follows: 4 per cent 
snappers, 41 per cent medium, and 55 per cent large. 
Each class is weighed separately and carefully examined 
for any indication of spoilage. Any suspected fish are 
thrown out. The fish are then washed and put with 
salt into butts in the store. Fish that are brought in 
iced whole are sorted and weighed, and then beheaded, 
gutted, and split and salted. About eight bushels of salt 
are used to each hogshead of fish. The fish are kept, 
salted down in hogsheads until required, care being 
taken that the fish are kept covered with strong 
brine. 

After salting, the fish are dried. The salting process 


THE NEWFOUNDLAND COD HMSHERY 75 


effects partial drying by extracting a large proportion 
of the flesh fluids of the fish. The extraction of water 
by the salt is assisted by kenching, the fish at the bottom 
of the kench being pressed down by the weight of those 
above. 

The fish are taken from the butts as required, and are 
piled in a kench about 4 ft. high, to express and drain 
off the pickle. At the end of two days the fish are re-piled, 
the top fish becoming the bottom, and so subjected to 
full pressure. If the weather is unfavourable for drying, 
they are re-kenched every two or three days. 

The fish are then dried by exposing them to wind and 
sun on a bed of latticework about 8 ft. wide and 30 ins. 
above the ground, and as long as necessary, called a 
“flake.” The drying yard is known as the flake yard. 
The latticework is constructed of triangular-section, 
wooden laths, placed about 3 ins. apart, the fish resting 
on the upper edges of the laths. 

In the hot weather, the fish are protected from sunburn 
by canvas awnings, and from rain at night by coops. 

With a warm sun and a good breeze, drying will be 
complete in about 10 hours. Thorough drying through- 
out the body of the fish is accomplished by drying on the 
flakes und the surface is dry and crystallized. The fish 
is then kenched, and the dry surface salt extracts more 
moisture from the interior. The fish is then dried again, 
thus ensuring a much more complete result. 

Fish are also dried in some factories in large, steam- 
heated shelf driers. This method is inclined to be too 
rapid, with the result that the fish are only surface 
dried instead of being uniformly dried right through. 

After drying, the fish are kenched in the store until 
required. They are then skinned, the bones are removed, 
and they are moulded into blocks which are cut up into 
cakes for packing and export. 


76 THE FISHING INDUSTRY 


It is estimated that the loss in weight during the 
different operations is as follows— 


Dressing. : ; : . 40 per cent 

Salting (full pickle) . : 

Drying . : ; : Act 

Skinning and boning : Selah 
Potaldoss. 253454 = 


The fresh waste, skins, bones, etc., of the fish are 
worked up for glue, the residue being manufactured 
into fertilizer. The best glue is obtained from the 
skins. The cod and cusk skins are superior in this to 
the skins of hake and haddock. 

The oil is extracted from the livers. That from 
fresh livers is refined and used for medicinal purposes, 
while that from old livers is used for tanning chamois 
leather. The value of this oil is considerable, as much 
as £150 being received by a boat in one trip for the oil 
alone. 

In 1914, Newfoundland exported 60,000 tons of cod 
meat, worth 1,600,000. The chief market is the 
Mediterranean. 


CHAPTER VI 
TRAWL FISHERIES 


UNLIKE the drift net, which only catches fish of one 
species and of fairly uniform size when they are swimming 
near the surface, the trawl net scoops up practically 
all the inhabitants of the sea bottom, including round 
fish, e.g. cod and haddock; flat fish, e.g. sole and 
plaice, as well as various invertebrates (jelly fish), and 
marine plants and stones. The trawl is essentially 
a flattened, conical net that is dragged open-mouthed 
along the sea bottom. The two kinds of trawl in 
common use—the beam trawl and the otter trawl— 
differ in the method that is adopted for keeping open 
the mouth of the net. The beam trawl is used by 
sailing vessels, the otter trawl by steamers. 

Sailing trawlers are divided into two classes: first 
class smacks and second class cutters. The smack is a 
two-masted vessel with fore and aft rig, generally 
making a five or six day voyage, and trawling in depths of 
up to 40 fathoms. The cutter makes shorter voyages— 
20 hours—and generally keeps within territorial 
waters. 

To work a beam trawl successfully, it is necessary to 
know the character of the sea bottom, whether rough 
or smooth, and also the time and direction of the tide. 
The net is trawled with the tide a little faster than it is 
running, so that sufficient resistance is encountered to 
keep the net extended. In shooting the trawl, great 
care must be taken to make it alight on its runners in 
the correct position for trawling. If the net be twisted, 
or if it alight upside down, it has been shot “ foul,” 

77 


78 THE FISHING INDUSTRY 


and has to be hauled up and shot again. In preparing 
for a shot the net is lowered over the side by adjusting 
the bridle ropes, and the beam is coaxed into its proper 
position while the net is still near the surface. The 
net is then gradually lowered, the boat moving slowly 
forward. The trawl is generally hauled for the duration 
of a tide—tbat is, six hours—during which time it will 
travel about 15 miles. The net is generally hauled in 
by a steam capstan, driven by a small donkey engine. 
When the trawl comes alongside, the beam is secured 
and the net is gradually hauled over the side by hand 
until the cod end appears ; this is then made fast to a 
rope and tackle, and hauled above the deck. The 
cod line is untied and the fish are discharged upon the 
deck. 

Since trawling is generally carried out on smooth 
ground, the greater proportion of the catch consists of 
certain kinds of demersal fishes that frequent sand and 
gravel. Of these, the most important are cod, haddock, 
whiting, ling, hake, cat fish, sole, plaice, turbot, and brill. 
Certain of these species also frequent rocky ground, 
and are taken in such areas by the line fishermen. 

Generally speaking, line fishermen work in deeper 
water than trawlers and capture larger fish, though of 
fewer species, e.g. cod, halibut, ling, skates and rays. 

The original sailing trawlers are rapidly being super- 
seded by steam trawlers. The first steam trawling 
company was formed in 1882. It had a capital of 
£20,000 and a fleet of four vessels. It trawled on the 
Dogger Bank for three years with marked success, 
After this the future of steam trawling was assured. 
The steam trawler is many times more efficient than a 
smack, for it can fish in nearly all weathers, including 
calm, and it can trawl over rough bottoms, owing to 
its greater power, and can go much further afield. 


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80 THE FISHING INDUSTRY 


Modern British steam trawlers travel as far afield as 
Iceland, Newfoundland and Morocco. 

Steam trawling developed rapidly, and resulted in a 
correspondingly rapid decrease in the number of sailing 
trawlers. Between 1893 and 1903, the number of first 
class smacks in Great Britain decreased from over 
2,000 with an average tonnage (net) of 57-4 to less than 
900 with an average tonnage (net) of 40. From 1903 
until the present day, the number had remained between 
900 and 800 ; it would seem, therefore, that the relative 
numbers and importance of smacks and steam trawlers 
gradually attained to a condition of equilibrium. 
Between 1900 and 1906 the increasing importance of 
steam trawling received a temporary check. A steam 
trawler in those days would cost about £10,000 to con- 
struct and about {£5,000 a year to operate ; their com- 
mercial success, therefore, depended upon correspond- 
ingly large and valuable catches of fish being obtained. 
When first introduced on the fishing grounds round the 
coast their superior efficiency and speed amply com- 
pensated for their high cost. About 1900, however, 
the catch obtained by these vessels on the home fishing 
grounds began to diminish, and the fishermen became 
alarmed lest the greatly increased efficiency of steam 
trawling should prove to be its own undoing, and result 
in the depopulation of the fishing grounds by over- 
fishing. Between 1900 and 1906, the number of steam 
trawlers fishing from British ports only increased by 
200, whereas, during the preceding 10 years, the numbers 
had increased from a few hundred to over 2,000. 

The anticipated exhaustion of the home grounds led 
to the steam trawler prospecting further afield. These 
longer voyages, as far as Iceland and the White Sea and 
Morocco, were very successful. The result of this was that 
larger steam trawlers were built, capable of undertaking 


TRAWL FISHERIES gt 


long voyages of many weeks’ duration. Between 
1900 and 1906 the average net tonnage of the steam 
trawlers increased from 54 to 62. The steam trawlers, 
in Opening up new and more distant fishing grounds, 
left the home grounds to the smacks. Consequently 
we find that the smacks confined their operation to the 
smooth ground in home waters, leaving the rough and 
more distant grounds to the steam trawlers. A direct 
result of this gradual redistribution of the fisheries 
between sailing smacks and steamers was the develop- 
ment of specialized fishing ports. Such ports as Lowes- 
toft, Brixham and Ramsgate, off which good fish are 
obtainable and which are within easy access of good 
markets, have retained their importance as smack 
ports ; on the other hand, the development of steam 
trawling has led to the rapid growth of deep water 
ports, such as Fleetwood, Grimsby, Hull, Aberdeen, and 
Milford Haven. In Grimsby, originally one of the 
greatest strongholds of smack fishing, smacks have been 
entirely displaced by steam trawlers, owing to the special 
facilities which the port offers in being near cheap coal, 
in possessing deep water, and in being in direct rail 
communication with large markets for trawl fish. 

There is no doubt that the rapid development of steam 
trawling was accelerated by the invention of the otter 
trawl. This is not only a larger net than the beam 
trawl, but is for all but small, flat fish, a much more 
efficient instrument. From the study of market 
statistics between the years 1889 and 1898 Garstang 
has calculated that a steamer caught on the average 
between four and seven times as much fish in the year 
as a sailing smack. 

A modern steam trawler is from 150 to 160 ft. long 
by 25 ft. beam and 12ft. depth, constructed with a 
high bow and a low, flat stern. Her net tonnage is 


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TRAWL FISHERIES 83 


from 60 to 200, her bunker capacity 250 tons, with 
storage room for up to 120 tons of fish. She is fitted 
with triple expansion engines of from 40 to 85 horse 
power. The forward part of the ship is occupied by 
the living quarters of the crew, rope and net store, ice- 
room, and fish-hold. Larger vessels, making trips to 
distant grounds, will take as much as 30 tons of broken 
ice ; this ice is distributed over the fish in layers, after 
they have been cleaned and gutted. In practically all 
modern fishing ports there is a special ice factory situated 
near the quay, and ice is manufactured by the ammonia 
process, crushed, and delivered to the ships through 
zinc-lined chutes. The fish-hold in the forward part of 
the ship extends right across the ship and is from 9 to 
10 ft. high, divided by a partition into two compartments, 
each compartment fitted with two shelves 5 ft. long, 
on which the fish are piled. These shelves reduce 
compression and facilitate the storage of the fish, the 
front of each compartment being closed with boards as 
it becomes full. She generally carries three or four 
trawl nets, one on her starboard and the other on her 
port, one or two being down below in reserve. The 
boat is fitted with four gallows, two forward and two aft, 
one on each side of the boat. These gallows are 
used for lifting the otter boards out of the water 
when the trawl is hauled in. 

The ship carries nine hands, consisting of skipper, mate, 
boatswain, two deck hands, cook, two engineers and a 
fireman. 

On the fishing grounds, fishing is continuous. The 
net is trawled for from two to four hours, although on 
grounds where fish is plentiful (e.g. Iceland) the trawl 
is frequently hauled every half-hour. It is then hauled 
aboard, and the cod end containing the fish is swung 
over the deck. The cod line is unfastened so that the 


84 THE FISHING INDUSTRY 


cod end of the net opens, and the fish are discharged 
into a pound formed on the deck by horizontal 9” x 3” 
deal boards. The net is cleaned and shot again. 

On smooth ground trawling is commercially possible 
at all depths down to 300 fathoms. In few cases, 
however, is trawling carried on at greater depths than 
200 fathoms. 

Owing to the large amount of stores and repairs, 
etc., connected with the maintenance of a fleet of steam 
trawlers, most large owners maintain fairly elaborate 
premises in the neighbourhood of the fish dock. These 
premises generally consist of a net-making hall in which 
nets are made by women working with shuttles, a large 
bath of tar or tanning material below in which the net 
is soaked, also a wood yard and blacksmith’s shop, 
containing a steam hammer, a plumber’s shop, a boat- 
builder’s shop, a large store-room fitted with the 
necessary stores and spares. 

During the war the steam trawlers were comman- 
deered by the Government for use as patrol boats and 
mine sweepers. It is estimated that 10 per cent of our 
steam trawlers and drifters and their crews were lost 
during the war. 

When steam trawling was first introduced it aroused 
general opposition, for there was not only the fear that 
their efficiency would lead to over-fishing in certain 
grounds, but it was said that the trawl, when dragged 
along the bottom, destroyed the eggs and killed the 
immature fish. The line fisherman found that steam 
trawling made it more difficult to catch demersal fish 
with baited hooks. He attributed this to the effect of 
over-fishing, but it is probable that contact with the otter 
trawls had made the fish rather more shy and, therefore, 
more difficult to catch by this method. It is unlikely 
that steam trawling will lead to serious over-fishing, 


length =_ about 10 feet ——__—_> 


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| B.—Attachment of board to net. OB. Otter board. B. Iron _ brackets. 
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HL. Head line. UW. Upper wing. LW. Lower wing. . Lacing connecting 
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* diameter (FF). 


86 THE FISHING INDUSTRY 


except possibly amongst such sedentary fish as soles 
and plaice. It must be remembered that trawling 
is only commercially possible on comparatively smooth 
ground and down to depths of about 200 fathoms. 
Probably, therefore, the actual area trawled is only a small 
proportion of the total area that is inhabitea by fish. It 
is possible, of course, that extensive and long continued 
trawling in a confined and relatively isolated area may 
scare the fish away ; it is probable, however, that any 
area in which over-fishing appears to have produced 
temporary exhaustion will tend to recover automatically, 
since it would naturally be abandoned temporarily by 
the trawlers for more profitable fishing grounds. There 
is no doubt that trawling, unless the size of the mesh 
is carefully controlled, tends to remove large numbers of 
immature fish. Generally in ordinary beam trawling— 
cod, plaice, haddock, etc.—the mesh varies from 3 ins, 
diameter near the mouth of the net to about 1} ins. 
diameter at the cod end. Ifa much smaller mesh were 
used the resistance encountered by a full-sized net 
would be so great that it would be almost impossible to 
draw the net through the water. Smaller trawls of 
4 in. mesh are used in shallow coastal waters for catch- 
ing shrimps, small plaice and whiting. The size of mesh 
largely determines the size of fish that will be retained 
by the net, since the smaller, immature fish readily escape 
through the meshes. Of recent years the various 
fishery boards, with a view to preventing the catching 
of such small, immature fish, have increased the size 
of mesh that is to be used—particularly when trawling 
within the three mile limit, where the greatest proportion 
of immature fish is generally encountered. For steam 
trawlers working in deep water a 2} in. mesh is generally 
used, but within the three mile limit it is frequently 
increased from 3 to 3} ins, 


Gduvodv HOLVO AHL 
sl 9 


88 THE FISHING INDUSTRY 


Herring are caught with drift nets at night near the 
surface. In the daytime they frequent the sea bottom 
and can then be caught with a trawl net. Trawling for 
herrings was first practised by the fishermen of Milford 
Haven and Fleetwood in 1901. They used an ordinary 
otter trawl lined with a piece of herring net. A 
specially constructed herring trawl is now used, of which 
the cod end is made of 2} in. mesh instead of the usual 
34 in. 

When trawling for herrings the steamer goes at full 
speed, generally for two to four hours, unless a shoal 
is encountered, when half-an-hour is frequently 
sufficient. 

Herrings are trawled in from 70 to 100 fathoms of 
water over a soft bottom. The main centre for trawled 
herrings is North-West of Ireland, other fisheries being 
carried on off the South-West of Ireland, the West of 
Scotland, and in the North Sea. In 1913 over 500,000 
cwts. of herrings were taken with trawl nets in these 
areas, 

This method of catching herrings aroused serious 
opposition among the drift net fishermen. They 
asserted that the trawl catches and destroys a high 
proportion of immature fish, and also destroys the 
herring eggs as it passes along the sea bottom. In 1913 
the matter was investigated by a Parliamentary 
Committee, but any Government action was checked by 
the outbreak of war. 

Since 1905 the trawling grounds frequented by 
British steam trawlers have been divided for statis- 
tical purposes into eighteen fishing areas. Thenamesand 
areas of these regions are shown in the chart of the 
trawling grounds (Fig. 19). 

Table I shows in hundredweights the average catch 
per day’s absence ‘from port in different areas. 


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TRAWL FISHERIES 89 


TABLE I 

1906 1913 1920 
White Sea ; : - 40-15 44-12 25-45 
Iceland . : $ . 44-22 46-10 58-54 
Faroe , . , : 31-19 28-19 27-03 
Rockall . . ‘ . 38-98 39-27 49-53 
North of Scotland . . 25-01 25-76 27-31 
North Sea : ‘ . 17-60 14-08 24-94 
English Channel : . 11-36 8-95 25-70 
Trish Sea . : : . 15-66 11-94 18-79 
Bristol Channel : ~- 13-15 13-98 26-38 
West of Scotland 4 . >» 21-18 28-11 28-17 
West of Ireland. : . 21-48 30-22 25-87 
South of Ireland : . 26-97 23-74 26-63 
Biscay . : : - 15-98 13-22 18-73 
Portugal and Morocco . 6-55 13-81 19-29 


In England and Wales more fish is landed by trawlers 
than by all other methods of fishing combined. Trawl- 
caught fish—soles, plaice, turbot, halibut, cod—are 
much more valuable than fish caught by drift nets, 
e.g. herring and mackerel. In England and Wales, 
in 1913, the weight of pelagic fish caught amounted to 
389,262 tons, and of demersal fish 418,038 tons. Although 
the quantity of the demersal fish was, therefore, only 
little larger than of the pelagic fish, its value was 
£7,463,003, compared with £2,531,979, the value of the 


pelagic fish. 


7~{1457) 


CHAPTER VII 
SHELLFISH 


SHELLFISH are divided into two classes: Crustacea, 
including the lobster, crab, shrimp, prawn, and mollusca, 
including the oyster, mussel, cockle and periwinkle. 
Shellfish generally abound in comparatively shallow 
water near the shore. 

Perhaps the most important members of the crustacea 
are the various minute, pelagic copepoda, of which 
incalculable myriads form an important constituent 
of the plankton in all seas. These copepoda live upon 
the diatoms and other microscopic, marine vegetable 
life floating at the surface of the sea. The most impor- 
tant edible members of the crustacea are the lobster and 
the shrimp. 

The lobster is found along the coasts of the North 
Atlantic and Mediterranean, particularly along the 
European coasts from Norway to the Mediterranean, 
and off North America from Labrador to Cape Hatteras. 
The lobster lives in shallow water at about 12 fathoms 
depth, and frequents a rocky bottom. The lobster’s 
eggs remain attached to the female until the larvae hatch 
out. From 10,000 to 12,000 eggs are carried in this way 
by a female lobster. She protects them from the ravages 
of fish that will otherwise consunie them as food, and by 
keeping them constantly irrigated with fresh sea-water 
she promotes their healthy life and development. The 
eggs may take as long as twelve months to hatch, and 
although “‘ berried ’’ lobsters are seen in greatest numbers 
in the spring they are also captured at all seasons of 


the year. 
90 


SHELLFISH 91 


When hatched the young lobster larvae leave their 
mother and float up to the surface wacer, where they 
develop ior a time among the plankton. During the 
larval period the lobster is a sree and active swimmer. 

The young larvae are consumed in large quantities by 
fish such as herring, mackerel and sprat, especially 
during the summer months when they are most abundant. 
While developing into a complete lobster it passes 
through at least three distinct changes of form. When 
the larva has attained the length of about 2 in. it already 
possesses many of the characteristic features of the 
adult. Soon afterwards, it sinks to the sea bottom and 
gradually grows into a complete adult. During the 
growth of the lobster it frequently casts its shell and 
grows a new one. Growth only takes place when the 
shell is cast and while the new shell is hardening. During 
the first few weeks of its life the lobster casts its shell 
about once a week, but this casting happens less and less 
frequently as the lobster grows older. The new shell 
is formed beneath the old one, and although at first 
quite soft rapidly hardens when the old one has been 
cast off. Most adult lobsters cast their shells in 
July, August and September. 

A lobster grows slowly, and when from 9 to 10 ins. 
long is probably from four to five years old. It becomes 
mature when about 6 ins. long—that is when about 
three years old. 

The lobster is usually caught in creels or “ pots ” 
baited with portions of stale fish—generally flounder, 
skate, eels, etc. Lobster fisheries tend to deteriorate 
in value very rapidly Owing to the lobsters’ keen sense 
of smell, the method of capture by means of creels or 
pots is very efficient, so that the lobsters are caught in 
great numbers, with the result that the fishery soon 
shows signs of exhaustion, the average size of the lobster 


92 THE FISHING INDUSTRY 


caught becoming smaller. The lobster fishery is entirely 
confined to the shallow water near the shore, and can 
only be replenished and maintained by the young 
lobsters that hatch out in that neighbourhood. Large 
quantities of lobster spawn are destroyed every year 
when berried lobsters are caught. It is estimated that, 
on an average, 30 per cent of the lobsters caught are 
berried females. The fishermen either remove the 
spawn and throw it back into the sea—where, of course, 
it almost certainly becomes fish food—or sell it to be 
used in making certain special sauces. 

Various attempts have been made by legislation in 
different countries to prevent the capture of berried 
females, and so protect the lobster spawn, but, since 
berried females are found all the year round and comprise 
about 30 per cent of all the lobsters captured, it is 
practically impossible to prohibit the capture of berried 
lobsters without seriously penalizing the fishermen. 

A better policy would be to hatch lobster eggs in large 
numbers artificially, and when the young lobsters are 
well established add them to the natural stock. This 
is actually done on a large scale and with excellent 
results in America and Norway. 

In Europe lobsters are generally sent to market in 
a fresh state, but in America they form the basis of an 
extensive canning industry. In 1913 over 2,500,000 
lobsters were captured round the coasts of Great 
Britain and Ireland, the total value of the fish being more 
than £110,000. 

Shrimping is one of the most important methods of 
inshore fishing, and gives employment to a large number 
of fishermen round our coasts. The shrimp is found on 
sandy or muddy ground in shallow water near the coast. 
A female shrimp, like the lobster and the crab, carries 
its eggs under its tail. . 


* SHELLFISH 93 


Shrimps are caught with a fine-meshed trawl net, 
drawn by a boat or by horse and cart, or with push nets or 
hose nets. One great objection to shrimping is that the 
shallow, sandy areas on which it takes place are much 
frequented by young fish—particularly dabs, plaice, 
soles, whiting and codling. Owing to the small mesh 
of the shrimp trawl, these small fish are captured in 
large numbers and are generally dead or dying when 
discharged from the net. Generally, the shrimps are 
separated from the small fish by riddling, and the 
smaller shrimps are then separated from the larger ones 
by a second riddling process, and are returned to the 
sea. The shrimps are thrown into boiling salt water, 
rapidly stirred for a few seconds, and spread out on the 
deck to cool. From three to four hauls are made per 
day, a good day’s fishing consisting of from 30 to 40 
quarts of shrimps. Large numbers of shrimps are 
potted. 

The other important group of shellfish is the mollusca. 
Molluscs, i.e. “soft creatures,” are essentially soft, 
mobile animals, protected by shells. They are classed 
as bi-valves, for example oyster and mussel, and 
uni-valves, for example limpet and whelk. There 
is no real difference between a bi-valve and a uni-valve, 
for what appear to be the two shells of the bi-valve 
are really one shell divided into two parts by a line of 
soft, uncalcified material which forms a hinge between 
the two halves of the shell ; this hinge tends to keep the 
shell open, but the muscular action of the living animal 
inside keeps it closed when required. 

With the exception of the mussel, very few shellfish 
actually live. on the shore between the tide marks. 
Most of the seashore shells are brought by the sea from 
animals that lived in from 10 to 20 fathoms of water. 
The cockle lives buried in the sand, about an inch below 


94 THE FISHING INDUSTRY 


the surface. The oyster lives on stones and shells below 
low-water mark. 

All molluscs are attached tightly to the shell at one or 
two points, and cannot be removed from the shell alive. 
In the case of the bi-valves the animal is attached to 
the two shells by a muscle which draws the two valves 
of the bi-valve together. When this muscle is relaxed, 
for example in normal circumstances, when feeding at 
the bottom of the sea—the shell remains open. Some 
shellfish—notably the scallop—actually swim by opening 
and shutting the two valves of their shell. 

The most important uni-valves are the periwinkle, 
the limpet and the whelk. Uni-valves possess a well- 
marked head and neck, a pair of eyes and a mouth. 
They are remarkable for the possession of a tongue, 
formed like a ribbon rasp, furnished on its upper surface 
with a large number of small teeth. The number and 
arrangement of these teeth differ in different species. 
With this ribbon rasp the uni-valve, for example a 
dog-whelk, can rasp a hole through the shell of an 
oyster and feed upon the contents. 

Bi-valves do not possess a ribbon rasp, neither have 
they a projecting head, nor in most cases any eye. 
They possess a mouth, furnished with four flapper- 
like lips or gill plates. They feed on microscopic, 
floating plants that are drawn within their mouth by 
currents set up in the water by the rhythmic vibra- 
tions—from three to four hundred strokes per minute— 
of millions of hairs that hang down from soft plates 
supported under the protecting arch of the shell and 
called the ‘‘ beard.” These’ currents of water not only 
bring food to the mouth of the bi-valve, but also irrigate 
the gill plates and so enable the animal to breathe. 
The oyster lies on the sea bottom with its muscle relaxed 
and its shell gaping. 


SHELLFISH 95 


A North European oyster acts alternately as female 
and male. It produces eggs—as many as a million in 
a season—and a fortnight after the eggs have been shed, 
the same oyster produces millions of spermatazoa, which 
form a cloud of fine dust in the water. These sper- 
matazoa rapidly scatter in all directions, and, entering 
the tubular reproductive sacs of oysters that are 
producing eggs, fertilize them. 

American and Portuguese oysters are definitely male 
and female, the eggs being discharged by the female and 
fertilized subsequently in the sea by the male. 

The eggs remain attached to the parent’s gill plates, 
and in a day or so develop into minute, shell-less oysters. 
The parent oyster is then said to be “ white-sick.” 
About two days later the young oysters have become 
dark-coloured and are found to have formed minute 
convex shells, rather like those of a cockle. The parent 
is then “ black-sick.”” A week later the young oysters 
escape and rise in thousands to the surface water, 
swimming by means of fine hairs or cilia that are attached 
to the upper edge of the shells. They are carried far 
and wide by tides and surface currents. Many are 
eaten by young fish and shrimps. As they grow the 
shells become heavier, and after a time they sink to the 
sea bottom. This is known as the “ fall of spat.” If 
they fall.on stony ground, where they will be well 
irrigated and nourished through the movement of the 
water, they will. thrive. Many, however, fall on soft, 
unsuitable ground and perish. 

The European oysters spawn in the summer (from 
May toSeptember). They become mature in three years, 
are at their prime in from five to seven years, and 
rarely live longer than ten years, 

Oysters are gathered from natural beds or from 
artificial grounds The oyster breeders place movable 


96 THE FISHING INDUSTRY 


tiles or frames for the spat to fall on. When the young 
have become affixed to these ‘“‘ stools” they are fre- 
quently carried away to develop in a different locality. 
The oysters are finally fattened in sea ponds or inlets 
that contain a large diatom population. At Marennes, 
on the west coast of France, the water in which the 
oysters are grown contains a particular blue diatom. 
After feeding upon these diatoms, the beard of the 
oyster becomes stained a bluish-green colour—the 
well-known “ Marennes vertes”’ oysters. 

A natural oyster bed is formed on stony ground free 
from mud and sand, so that the oyster, after becoming 
attached to a stone, is completely surrounded by clear 
sea-water. Oysters do not flourish in water containing 
less salt than ordinary sea-water. Thus, there are no 
oysters in the Baltic Sea. 

The chief enemies of the oyster are the dog-whelk 
that bores through the shell, and the starfish that pulls 
the valves apart and attacks the oyster inside. 

The oyster is widely distributed in tropical and 
temperate seas all over the world. The approximate 
value of the annual oyster crop of the world is £4,000,000, 
representing a crop of 10 billion oysters. 

In Europe up to 75 per cent of the oysters are reared 
from spat in artificial beds—not more than 7 per cent 
being “native.” In the United States, however, over 
40 per cent are still obtained from natural beds. 

The simplest form of oyster culture is the preservation 
of the natural bed. These beds are easily destroyed or 
made unproductive by over-dredging. Colonies are 
broken up. Other animals are admitted. Breeding 
oysters are covered up by stones and shells, and 
suffocated. Ridges suitable for the development of the 
spat are broken down. 

After the beds have been properly protected and 


SHELLFISH 97 


preserved the next stage is to extend the area of the 
natural beds. This involves a knowledge of the con- 
ditions of depth, temperature, salinity and character 
of bottom that are necessary to the successful growth 
of the oyster. Finally the productivity of an oyster 
“park ”’ and the quality of its produce can be greatly 
improved by providing artificial “‘ stools ” for the recep- 
tion and development of the spat. Many substances 
can be used for this purpose. The Romans used 
earthenware tiles, and similar tiles are used to this day 
in France. Brushwood, trees, stones and stakes, and 
old oyster shells (cultch) are also used. 

The earthenware tiles used in France are hollowed 
on one side to receive the spat, and are coated with lime 
to facilitate the removal of the oysters when they are 
a year old. They are then from } to 1 inchin diameter, 
and are picked off the stools and placed on stands 
where they are thinned out from time to time as they 
grow. 

The chief oyster fisheries in Britain are at Whitstable, 
Colchester and Brightlingsea. Nearly 40,000,000 
oysters were gathered on the coasts of England and 
Wales in 1920, and were sold for about £250,000. 

Perhaps the next most important edible bi-valve is 
the mussel. Frequently, mussel beds are situated near 
the mouth of rivers, and consequently tend to be con- 
taminated by sewage. It has been established by 
various investigators—notably Dr. Klein and Professor 
James Johnstone—that mussels are able to cleanse 
themselves of sewage pollution in a comparatively short 
time if they are re-laid in sterilized water. Experi- 
ments on a large scale have been carried out with the 
mussel beds at the mouth of the Conway river since 
September, 1916. The mussels are gathered from the 
beds and placed about two deep on wooden grids in a large 


98 THE FISHING INDUSTRY 


concrete cleansing tank of 40,000 gallons capacity. 
The mussels are first thoroughly hosed with water at 
high pressure to remove all adherent mud, etc. The 
tank is then filled with sterilized sea-water and the 
mussels are allowed to remain in it for 24 hours. During 
this period the mussels effectually free themselves from 
bacteria. The tank is then emptied, the mussels are 
hosed again, the tank is again filled with sterile water 
and after a further 24 hours is emptied. The mussels 
are once more flushed with the hose. After this treat- 
ment the mussels reach a high standard of purity. 
The scheme has proved to be a complete success, not only 
from a scientific point of view, but also as a commercial 
proposition. The sum of ls. per bag of mussels (140 Ibs.) 
is charged to the fishermen for this treatment. 


CHAPTER VIII 
FISHERIES FOR WHALES 


WHALES are the most important members of a large 
family of land animals including also the seals, walrus, 
and porpoise, that have gradually become adapted to 
live in the sea. They have acquired an externally 
fish-like form, but in every other respect they retain 
the characteristic features of mammalian structure. 
They are warm-blooded, air-breathing quadrupeds, that 
suckle their young. In the whale, the fore-limbs have 
become simple five-fingered flippers, while only isolated, 
vestigial bones of the hind-limbs remain buried uselessly 
in the body. Unlike fishes, the tail is set horizontally, 
thus enabling the creature to rise easily to the surface 
to breathe. The warm-blooded body is kept warm by 
a layer of fat placed immediately beneath the skin, 
and varying in thickness from 8 to 20 ins., and known as 
the blubber. The nostrils, instead of being situated at 
the end of the snout, are placed far back at the apex of 
the head to form the blowhole. 

Whales are divided into two well-marked groups, 
known as the whaleboned and the toothed whales 
respectively, according to the particular form of their 
dentition. 

The most important of the whaleboned whales is the 
Greenland, or Arctic Right, whale. It attains a length 
of upwards of 45 to 50 ft., and is remarkable for the 
enormous extent of its head and mouth cavity. The 
head extends for a third of the length of the body, so 
that the mouth cavity may be as much as 18 ft. long, 
12 ft. broad and 11 ft. in height, the dimensions of a 
small chapel! The upper jaw is narrower than the 
lower and arches backwards, thus increasing the actual 

99 


100 THE FISHING INDUSTRY 


height of the mouth cavity and providing’ample room 
for the blades of whalebone with which the jaws are 
furnished in place of teeth. These blades of whalebone 
number about 380, and range. in length from 8 ft. to, 
in exceptional cases, 12 ft. They are suspended in the 
mouth of the whale like stalactites, set fairly close 
together, and, since the edges of each blade are fringed 
with fine whalebone, the whole arrangement forms a 
very efficient strainer. This enables the whale to feed 
upon the plankton—or “ krill,’ as it is called by the 
whalers—and._ small fish, e.g. herring and capelan. The 
whale fills his enormous cavern of a mouth with water 
containing the floating food particles, and then, by 
raising his tongue, slowly expels the water through the 
whalebone sieve. The food particles are retained by the 
whalebone, and are then licked off and swallowed. 

The Greenland whale inhabits the Arctic seas north of 
latitude 54°N. A closely related variety, the Bowhead 
whale, forms the basis of a fishery in the Behring Sea. 

The largest whales known are the so-called Rorqual 
whales. The name of these whales is derived from the 
large number of longitudinal folds or pleatings that 
form a characteristic feature of their throat. Rorqual 
whales attain a length of from 80 to 85 ft. The head is 
relatively small, and the long, slender body carries a 
distinct dorsal fin. The whalebone is coarse and short. 
The Rorqual whales are the most abundant and widely 
distributed of all whales. They are found in all open 
seas, with the exception of those in the extreme Arctic 
and Antarctic regions. 

The Southern Right whale, or Black whale, is found 
in the temperate seas of both Northern and Southern 
hemispheres. 

Of the toothed whales, the most important is the 
Cachalot or Sperm whale. It is chiefly captured in 


Fic. 20 
A WHALE’S MOUTH 
The carcass is ready for cutting up at a Shetland whaling station. 


102 THE FISHING INDUSTRY 


Southern seas, and is killed in large numbers for the sake 
of the spermaceti and sperm oil that occur in iarge 
quantities in its head cavity. Sperm and other toothed 
whales feed upon fish and cuttlefish. 

The breeding habits and migrations of the different 
species of whales are at present little understood. 
During the summer, when the water in the Polar circles 
swarms with certain varieties of pelagic crustacea, the 
whales congregate in these regions and are then 
most profitably hunted. At the end of the summer 
they appear to migrate towards warmer water nearer the 
Equator. They bring forth their young in warm, shallow 
water, and return to the whaling grounds in the spring. A 
young whale calf may be as much as 20 ft. long at birth. 

Whales were captured by the Norwegians over 1,000 
years ago. In the Middle Ages—from the ninth to the 
seventeenth centuries—the Basques hunted the Black 
whale in the Bay of Biscay, and supplied Europe with 
oil and whalebone. Towards the end of the sixteenth 
century, as the Biscay whales became rare and more 
difficult to find, the whalers ventured further afield, and 
in 1612 discovered the Greenland whale. The Black 
or Biscay whale is now almost extinct, and there is every 
likelihood that the Greenland Right whale will also 
soon be exterminated. The capture of Sperm and 
Rorqual whales, although equally important, is a 
comparatively modern development. 

Modern whale fishing has become a very efficient art, 
owing largely to the invention of the shot-harpoon by 
a Norwegian, Sven Foyn, in 1870. This harpoon is 
discharged from a gun from the deck of a fast steamship. 
It penetrates the body of the whale in the vital region 
just behind the flipper. The invention of this weapon 
has made the killing of whales a matter of comparative 
ease and certainty. The inevitable consequence of this 


Ee 


FISHERIES FOR WHALES 103 


is that the whales are being killed in such large numbers 
that they are in danger of general extermination. Even 
before the introduction of the shot-harpoon, whales 
were being destroyed at an astonishing rate. Thus, 
during 40 years in the middle of the last century, over 
300,000 whales were captured by the United States 
whale fisheries alone. The value of these whales was 
£65,000,000, so that each whale realized on an average 
£216. Of recent years—before 1914—a single large 
Greenland whale has realized as much as £900 for 
whalebone and £300 for oil. At the present time, over 
20,000 whales are killed each year. 

The old eighteenth century whaler of about 400 tons 
burden carried about 30 officers and men, and was 
equipped for a three years’ voyage. Each whaler 
carried six whale boats. These whaleboats were about 
27 ft. long and built sharp at each end. Each boat was 
furnished with mast and sails, and was provided with two 
200-fathom whale lines. When a whale was sighted 
four of these boats, each manned by six men, started 
in pursuit. The boats ranged themselves alongside 
the whale and a harpoon was driven into it from each 
boat. The whale immediately dived to the bottom of 
the sea and remained there sometimes for as long as 
forty minutes. When he returned to the surface to 
breathe, more harpoons were chrown and he dived again. 
Ultimately, owing to loss of blood, the whale kept near 
the surface and was then dispatched by a lance thrust 
behind the flipper into the vital parts. 

The modern Greenland whaler is an iron vessel of 
about 500 tons. She is fitted with auxiliary engines of 
75 horse-power. She carries from fifty to sixty hands and 
eight whaleboats. She is fitted with tanks for 250 tons of 
oil. Before the war she would cost about £17,500 to 
build and £500 a month to maintain. Each whaleboat 


104 THE FISHING INDUSTRY 


carries a harpoon gun in order to make sure of the 
first harpoon getting a good hold. 

In Rorqual fishing, off Newfoundland, the harpoon is 
tipped with a bomb and time fuse. This explosive 
harpoon is discharged into the whale from the deck of the 
whaler—a fast steamer—and explodes with fatal effect. 

The chief whale fisheries are carried on off Greenland 
for the Greenland whale, off the coast of Newfoundland 
for Rorquals. There is the Norwegian bottlenosed- 
whale fishery around Iceland, and the American Bow- 
head-whale fishery in the Behring Sea. In Southern Seas 
the Humpback, Fin whale, and Blue whale (Sibbald’s 
Rorqual) constitute an overwhelming majority of the 
whales captured. The Right whale and the Sperm 
whale, although captured in relatively small numbers, 
are individually more valuable. Other smaller species, 
e.g. the Sei whale (Rudolph’s Rorqual), the lesser 
Rorqual and the Killer or Grampus, are also found in 
large numbers in the Antarctic. 

When the whale has been killed it is either made fast 
alongside the whaler and cut up, or it is towed ashore 
to a “‘ factory ” to be cut up and stripped. The blubber 
is stripped off, cut up into small pieces, and boiled down 
with water to separate the oil. The yield of oil varies 
for different species, as shown in Table II. The whale- 
bone is removed and, if a Sperm whale, the oil is removed 
from the skull cavity with buckets. An average large 
Sperm whale will yield from 2} to 3 tons of Sperm oil. 


TABLE II 
Average Yield of Oil in Barrels 
Species of Whale. (6 Barrels = 1 Ton). 
Right z : ; : 60 to 70 
Blue j ; : : 2370; 480 
Fin ; ; ; ; F, SOO CRM 
Sei Q ‘ ; os don eee 
Humpback : ; ; 8 a 


Sperm. ; F ‘ - 60°; 65 


Oe 


a 


FISHERIES FOR WHALES 105 


Whale oil is marketed in five grades: Nos. 0, 1, 2, 3, 
and 4. Nos. 0 and 1 are made entirely from blubber ; 
No. 2 from tongues and kidney fat and from the residue 
of the blubber boilings ; No. 3 is made from the flesh and 
bones, and No. 4 from refuse. The different grades 
contain progressively from 4 to 1 per cent water and 
dirt, and from 2 to 30 per cent free fatty acid. 

Grades 0, 1 and 2 of whale oil are used in the manu- 
facture of soap, glycerine being obtained from it as a 
by-product. In its natural condition the oil is soft, 
and has to be “‘ hardened ”’ before it can be used for soap 
making. The hardened whale oil is white, odourless 
and tasteless, and is an excellent substitute for tallow. 
In this condition it is also used as a substitute for lard 
and, to a small extent, is used in making margarine. 

Grades 3 and 4 are used in the manufacture of lubri- 
cating greases. Whale oil alone is used for shafting and 
machinery bearings. When mixed with mineral oil, 
it is used for looms, spindles and textile machinery. 
Whale oil is also used as an illuminant, for currying 
leather, and in making chamois leather, for batching flax 
and other vegetable fibres, and in oiling wool for combing. 

In 1913, the world’s annual catch of whale oil had 
reached 800,000 barrels. During the war the supply 
was considerably less, for example in 1917 it was only 
358,000 barrels. 

Whalebone. Whalebone from the mouths of the 
Right or whaleboned whales is in considerable demand 
among dressmakers and milliners. Its principal use 
is in the brush trade, chiefly in making brushes for 
mechanical purposes. It is prepared for use by being 
boiled in water for about 12 hours until it is quite soft. 
It is then cut into strips or bristles or filaments, according 
to the use for which it is intended. It is light, flexible, 
tough and fibrous. 


8—(1457x) 


106 THE FISHING INDUSTRY 


Bid 

Sperm Oil. Sperm oil is really a liquid wax. It is 
an excellent lubricant—particularly for rapidly inoving 
machinery, e.g. spinning spindles, or for delicate 
machinery such as watches. It does not become 
gummy or rancid, and retains its viscosity at high 
temperatures. It has no corrosive action. 

When cooled to low temperatures, it deposits a solid 
wax—spermaceti—which is used in the manufacture of 
high grade candles. Sperm oil is also used for dressing 
leather, in oil tempering steel, and as an illuminant. 

Ambergris. Ambergris is a solid, fatty, inflammable 
substance, dull grey in colour, which occurs as a concre- 
tion in the intestines of sperm whales. It is generally 
found floating in the sea or on the shore. It is used in 
the perfume industry mixed with other perfumes. 

The development of the whaling industry in the south 
seas has led to the industrial development of previously 
uninhabited islands. On South Georgia, which was 
previously uninhabited, actual industrial villages have 
been established. A church has been erected, and there 
are three slips for cutting up the whales, two guano 
factories, reservoirs for the oil, and houses for the staff. 
This Antarctic island has a floating population of many 
hundreds of sailors and workmen. A doctor resides 
there during the whaling season and, since 1908, the 
British Government has established a post office in this 
polar land. In 1922 the eyes of all the world were 
turned to this far-away land, the Gate of the Antarctic, 
as the body of Sir Ernest Shackleton, the hero of the 
Antarctic, was laid to rest there. 


CHAPTER IX 
THE CURING AND PRESERVATION OF FISH 


THE preservation of fishes for use as food long after they 
have been caught is a matter of constantly increasing 
importance to the prosperity of the fishing industry. 
In most other food supplying industries the produce can 
be kept fresh for the market comparatively easily. Dry 
grain will keep indefinitely ; vegetables and fruits with 
proper care will generally remain “ fresh ’”’ long enough 
to reach distant markets. Oxen, sheep and pigs may be 
transported to the market alive, and then slaughtered 
as required. But a fish as soon as it is taken from the 
water dies and speedily begins to decay. 

Fish, like other foodstuffs, whether animal or vegetable, 
decays as a result of the growth in it and on it of certain 
micro-organisms (bacteria, moulds). These micro- 
organisms swarm in the air and on exposed surfaces all 
the world over. Generally speaking, they flourish 
best at ordinary temperatures and in a moist environment. 

Foodstuffs can be preserved from decay only by 
preventing the growth and development of these decay 
organisms. They can be killed outright by any of the 
ordinary sterilizing processes such as exposure to 
sufficient extremes of heat or cold, or by treatment with 
disinfectant substances (germicides) such as carbolic 
acid or hypochlorites. Clearly, however, foodstuffs 
cannot be preserved indefinitely by the simple process 
of killing all the organisms that are resident on the 
foodstuff at the time of treatment, for, as soon as the 
foodstuff is exposed to the air, it will become infected 
afresh. 

107 


108 THE FISHING INDUSTRY 


They can be preserved— 

(1) By boiling, and packing immediately afterwards 
in air-free containers. 

This process is, of course, the basis of the great meat 
packing industry. The meat is packed in a tin, the tin 
and its contents are heated in steam or boiling water 
until the meat is cooked and all the decay organisms are 
destroyed. The tin is then sealed, air-free and air-tight. 

(2) By freezing. 

Cold storage is a widely used method of preserving 
foodstuffs. The low temperature prevents the growth 
and development of decay organisms and, as long as 
the foodstuff is kept sufficiently cold, arrests decay. 

Prehistoric animals long extinct are sometimes 
found firmly embedded in the Polar ice, as fresh as they 
were on the day they were drowned. 

It is found that the stability and subsequent quality 
of frozen meat or fish depend directly upon the manner 
in which it has been frozen. It may be frozen in air, 
or when immersed in brine. Of these two methods the 
latter is much quicker, because brine is over twenty-five 
times as good a conductor of heat as air is. During the 
slower air-freezing process the quality of the flesh is im- 
paired by the separation of the contained water into com- 
paratively large crystals ofice. This leads to the displace- 
ment of the membrane and tissues of the meat, so that 
in thawing again the meat drips and becomes tough. 
When immersed in brine freezing occurs too rapidly for 
this separation of water to occur to any marked extent. 

The keeping qualities of brine-frozen fish also are 
greater than those of air-frozen fish, owing to the pro- 
tecting coating of ice which effectively prevents contact 
with bacteria or mould spores. 

(3) By drying. 

Primitive man preserved his meat by drying it in the 


THE CURING AND PRESERVATION OF FISH 109 


sun, or in the smoke of a fire. To-day the prepara- 
tion of fish, dried fruits, desiccated vegetables, etc., is 
a world-wide industry. 

Generally speaking, decay organisms can only develop 
in a moist environment. All fresh foodstuffs contain a 
large proportion of water. The removal of this water 
effectively checks decay. Drying alone, however, 
does not always produce a permanent “cure,” as the 
foodstuff is always liable to get moist again. For that 
reason it is customary to combine the drying process 
with treatment with an antiseptic substance such as 
salt. Smoke drying is better than sun drying, for 
although the ultra-violet rays of the direct sunlight 
effectively kill bacteria and mould spores wood smoke 
contains antiseptic substances with which the meat 
becomes impregnated, so that even the chance of any 
subsequent infection is greatly reduced. 

(4) By treating with an antiseptic substance such as salt. 

Antiseptic substances differ from disinfectant sub- 
stances in that they do not kill micro-organisms, but 
only arrest their development. 

As a rule, they are effective preserving agents, and do 
not make the food poisonous or unpalatable. 

All these methods can be, and are, used for preserving 
fish, the method most commonly used being treatment 
with salt. Fish, however, are often kept in ice on board 
during a fishing trip and are then either packed in ice 
for transit under special storage conditions (if required 
fresh) or they are salted down. 

Methods of Salting. Different methods of salting 
are used, according to the character of the fish and the 
locality. The fish are either cleaned (split and gutted) 
or salted “‘round” (whole). In general, the method 
used is one of the following— 

(1) Dry-saLttinc. The fish are cleaned, rolled in 


110 THE FISHING INDUSTRY 


dry salt, and packed in layers in open casks. Each 
layer of fish is covered with a layer of salt. 

(2) BrinE Pickiinc. The fish are immersed in 
saturated brine, salt being added from day to day to 
restore the strength of the brine as it becomes weakened 
by the water which it extracts from the fish. 

(3) KencuinG. The fish, either split or round, are 
piled in layers in the hold of the ship, or on the floor of 
the warehouse, each layer being covered in turn with 
a layer of salt. The brine, as it forms, is allowed to 
drain away. 

Of all these three methods, the first is undoubtedly 
more effective, more economical, and requires less atten- 
tion than the second. The third method is often used 
on board ship and sometimes on shore as a temporary 
expedient when the catch is too large for the number of 
containers available. 

In the dry-salt method, the fish are packed tightly 
in the casks, and are not afterwards disturbed. When 
cured they possess a characteristic dry, shrunken 
appearance. 

Fish pickled in brine need attention every day. The 
brine has to be closely watched so that it shall not become 
too weak. Fresh salt has to be added daily, and the 
fish stirred up with wooden paddles to ensure uniform 
pickling. 

Fish cured in this way are softer and more plump 
than those cured by the dry-salting method. 

When a fish is packed in salt the salt rapidly extracts 
water from the flesh and a strong brine results. 

The salt dissolves in the remaining flesh juices of the 
fish, and rapidly diffuses throughout the fish, thoroughly 
permeating it. By this process, therefore, the fish is 
partially dried and becomes thoroughly impregnated 
with salt, 


THE CURING AND PRESERVATION OF FISH 111 


The gradual change in the composition of the flesh 
is reflected in the following analysis— 


ee ee ae fae: 
Sage pr Water. | NaCl. | Fat. 
Fresh herring, ungutted . 67-33 0-63 13-78 
Herring Pee salted, before 
gutting . 66-33 1-27 12-11 


Herring from rousing ‘tub, gutted 
and salted, ready to pack into 
barrel . ‘ : ‘ - | 61-09 1-41 16-14 

Herring, after 7 days salted in 
barrel . 52-67 7-43 17-10 

Herring, after 8 3 days salted in 
barrel 46-90 11-49 | 22-50 


The efficiency of the cure and the appearance of the 
finished product will be influenced by the following 
factors— 


(a) The temperature—whether summer or winter ; 

(0) The freshness of the fish ; 

(c) The quality of the salt—its purity and grain ; 

(d) The quantity of salt used ; 

(e) The duration of the process. 

(a) The Temperature. As soon as a fish is dead, it 
commences to decay. 

In hot weather, decay proceeds more rapidly and the 
interior portion of the meat may become soured before 
the salt reaches it. Clearly, if the rate at which the salt 
penetrates the fish is retarded by the salt being impure, 
or of too fine a grain, or by the brine being too weak, the 
probability of the fish being spoilt is very much increased. 

The dry salt method leads to a much quicker penetra- 
tion of the fish than the brine method, and should always 
be used in warm weather. 

(6) The Freshness of the Fish. The decay processes 
gather impetus day by day. It is clear, therefore, 


112 THE FISHING INDUSTRY 


that in order to avoid the possibility of ‘‘ souring,” the 
fish should be salted with the least possible delay. 

(c) The Quality of the Salt. (1) Its Purity. The 
impurities commonly present in Fishery Salt are the 
sulphates and chlorides of calcium and magnesium. 

The following analysis show the composition of 
typical samples of Fishery Salt. 


German 
Composition. aot Italian. | Spanish.| French. | English. 
alt. ah 
% % % %. % 


Salt (Sodium chloride)} 97-28 96-59 96-63 95-86 | 98-9 


Calcium chloride — 0-32 — 0-16 — 
Magnesium chloride . 0-25 1-19 0-96 0-35 0-08 
Magnesium sulphate — 1-75 0-73 — — 
Sodium sulphate 3 0-44 — — — 0-04 
Sodium bicarbonate . 0-01 — — — —_ 
Insoluble (Calcium 
sulphate, sand, etc.) 2-02 0-15 1-68 3-63 0-98 
100-00 100-00 | 100-00 | 100-00 | 100-00 
Moisture ‘ ; 0-20 6-54 4-47 1-39 3°25 


The Spanish and Italian salts are solar salts, obtained 
by evaporating sea-water by the heat of the sun. Solar 
salt nearly always contains more magnesium salts 
than brine salt does. This constitutes a _ serious 
disadvantage to the fish curer. : 

Of the calcium salts which occur as impurities in 
Fishery Salt, the sulphate is practically insoluble in 
brine, and is probably without action upon the salting 
process. 

Calcium chloride, onthe other hand, resembles mag- 
nesium chloride and is an undesirable constituent of 
Fishery Salt, for calcium chloride, and to a lesser extent 
magnesium chloride and magnesium sulphate, diminish 
the rate at which the salt penetrates the fish. Curing 


THE CURING AND PRESERVATION OF FISH 113 


will, therefore, be delayed, and in warm weather (above 
70°F.) this may result in the souring of the fish. 

To obtain rapid and thorough curing, therefore, it 
is necessary—especially in warm weather—to use salt 
which contains as little calcium and magnesium salts as 
possible. 

Pure salt, used dry, produces a soft, yellow-meated 
fish which is flexible in the hand. Salt containing 
calcium chloride or magnesium chloride produces a 
harder and stiffer fish with a markedly whiter colour. 

Salted fish can only be stored satisfactorily in a dry 
place. Fish which has been cured with impure salt 
is hygroscopic and will run wet in the store. 

This hygroscopic moisture weakens the preserving 
action of the salt. Fish that has been cured with a 
pure salt will keep much drier under ordinary storage 
conditions. 

(2) Its Grain. The crystals of Fishery Salt should be 
coarse and hard. Coarse crystals dissolve slowly, and 
so produce a more gradual cure than fine-grained salt 
does. Fine-grained salt extracts the water so rapidly 
from the surface tissues that it coagulates them. This 
retards the further penetration of the salt into the fish, 
so that the fish has the appearance of being slack salted. 

Round versus Cleaned Fish. The thoroughness with 
which a cut fish is cleaned and washed influences the 
temperature at which the fish can be salted success- 
fully, and materially affects the quality and taste of 
the product. Tressler? has shown that the chief cause 
of fish spoiling when salted in hot weather is the decom- 
position of the blood which remains in the flesh. Even 
in cold weather, it is found that the extra washing and 
cleaning greatly improve the quality of the fish. As the 
presence of blood in the fish also leads to discolouration 

1 U.S. Bureau of Fisheries, Document No. 884 (1920). 


114 THE FISHING INDUSTRY 


during the salting process, a thoroughly cleaned and 
washed fish is, after salting, much whiter in appearance 
and has a finer taste. 

Many fish are skinned before they are salted. It has 
been observed that a skinned fish will cure almost 
twice as quickly as an unskinned fish. This is because 
salt penetrates the meat of the fish at approximately 
twice the rate at which it penetrates the skin. It is 
desirable, therefore, particularly in hot climates, to skin 
the fish before salting. This, of course, is only com- 
mercially practicable with certain large kinds of fish 
such as cod, 

The Reddening of Salted Fish. Salted fish some- 
times undergo a change, either during the salting 
process if improperly carried out, or more generally 
in the store, which is characterized by the development 
on the surface of the fish of irregular red and brown 
patches. This reddening occurs not only on the fish, 
but also on the floors and walls of the curing factories, 
on the sides and decks of fishing boats, and even on the 
salt itself. It occurs most readily in warm weather. 

The reddening has been shown to be due to the growth 
of a micro-organism (a micro-coccus). With this micro- 
coccus are generally associated a bacillus and a 
micro-fungus which produce the brown mould on the fish. 

Fish become infected with these micro-organisms by 
contact with boats or docks or warehouses. 

Every precaution should be taken to keep such 
places clean and properly disinfected. 

The “rusting” of fatty fish, e.g. herring, is due to 
the oxidation of certain free, fatty acids split off from 
the fats by enzyme action. 


CHAPTER X 
THE FOOD VALUE OF FISH 


WirTH few exceptions, the different species of fishes that 
are caught industrially are important because of their 
food value. 

Some fishes are unsuitable for food because they have 
an unattractive taste ; others are directly poisonous. 
Thus, in the Japanese fish of the genus tetrodon, the 
roe is poisonous, although the remainder of the fish is 
edible. Some fishes are poisonous during the spawning 
season. Others are provided with a special poison 
gland connected with special spines or barbs. In edible 
fishes, given the suitable conditions, poisons may be 
formed by bacterial activity in the flesh of the fish. 
Poisons so formed give rise to the kind of fish poisoning 
known as botulism. Cases of botulism have resulted 
from eating canned salmon and sardines that have 
become spoiled. In some cases, bacteria present in a 
diseased fish may produce poisonous substances in the 
body ofthefish. Bacillus paratyphosus has been isolated 
from some poisonous fish, and certain poison-producing 
bacteria have been found in others. 4 

Certain shellfish are notoriously liable to be poisonous. 
The exact nature of the microbes concerned in the 
production of poisonous substances in shellfish is at 
present unknown; it is clear, however, that such 
poisonous substances may be produced in shellfish in three 
ways— 

(1) Microbes of various infectious diseases, such as 
typhoid fever, may be absorbed by the shellfish from 
sewage. 

1 Marshall, Microbiology. He 


116 THE FISHING INDUSTRY 


(2) The shellfish may be diseased, or be seriously 
contaminated, by living in dirty water. 

(3) Decomposition may set in after the shellfish have 
been removed from the water—particularly if they have 
been kept too long in a warm place. 

It has been found recently that shellfish that have 
been deliberately fattened on sewage can be effectively 
cleansed in such a way as to get rid of ingested sewage 
bacteria. This process has been carried out success- 
fully on a commercial scale at Conway by the Ministry 
of Agriculture and Fisheries. Danger from infected 
shellfish may also be safely avoided by boiling them. 
When shellfish are gathered at the right season of the 
year and from suitable localities, they are a perfectly 
safe and wholesome food. 

Of the many species of edible fishes that are known 
and used, the number is by no means complete, and new 
species are added from time to time. Thus, in 1916, 
the United States Bureau of Fisheries introduced a new 
edible fish (Lopholatilus chamaeleonticeps), which they 
christened the tile fish. After this fishery had been in 
existence for twelve months, the known catch of tile 
fish amounted to over 10,000,000 lbs., valued at more 
than $400,000. In 1917, the same Bureau introduced 
the dog-fish under a new name. As people were 
prejudiced against the name ‘“‘ dog fish,” the Bureau 
altered it to “ gray fish,” “ which is descriptive, not 
preoccupied, and altogether unobjectionable.” The 
fish is now caught in large numbers, and forms the basis 
of a very flourishing canning industry. Attempts have 
been made recently to utilize as food the edible portions 
of the shark (which is closely related to the dog fish) 
and the porpoise. 

The food value of most fishes varies very much 
according to the condition of the fish when it is caught— 


THE FOOD VALUE OF FISH 117 


that is whether it is spawning or not. Further, it may 
be considerably modified by the changes that take 
place subsequently in the composition of the flesh during 
the processes of curing, cooking or preserving. 

Generally speaking, all marine fish annually pass 
through a well-marked series of seasonal changes, the 
stages of which appear to depend upon changes in the 
temperature, salinity and alkalinity of the sea. These 
changes are directly connected with the development of 
roe and milt, with the fluctuation in the percentage of 
oil and fat in the liver and body tissues, and also with 
the rate of growth. Thus the chemical composition 
of the fish, and hence its food value, varies greatly 
according to the season at which it is caught. 

Norwegian brisling (“ Skipper Sardines ”) are caught 
in the summer just before spawning time. At this 
time the fat content is high ; in winter the fat content 
is low, and the fish possesses small commercial value. 

The gradual change in the composition and food 
value (in calories per pound) of the herring as spawning 
time approaches is well shown in Table III. (Prof. 
J. Johnstone, Trans., Liverpool Biolog. Soc., Vol. xxxiii 
(1919), p. 106.) 


TABLE III 


Manx SUMMER HERRINGS, 1916 
COMPOSITION OF THE FLESH OF THE FISH: MONTHLY MEANS 


Oil | 
Date. | Condition. Water.) and | ea Ash. | Total. gon 

Fat. | el | ’ ue 
May Empty | 75-0 | 2-5 | 21-1 | 2-3 | 100-9 | 1,100 
June Filling 66-1 | 11-4 | 18-6 | 2-0 | 98-1 | 1,806 
July Filling 55-8 | 21-6 | 18-4 | 2-3 | 98-1 | 2,762 
August; Half full | 48-4 | 31-5 | 165 | 2-3 | 98-7 | 3,608 
Sept. | Full 51-9 | 25-2 | 17-3 | 2-6 | 97-0 | 3,050 


118 THE FISHING INDUSTRY 


The herrings are caught in September when they 
assemble in shoals for the purpose of spawning. They 
are thus most easily caught at the time when their food 
value is at a maximum. 

The flesh of clupeoid fish—herrings, sprats, pilchards, 
sardines—contains a quantity of oil disseminated 
throughout the flesh in the form of fine globules. From 
the above table it will be seen that the percentage of 
oil in the flesh of the herring may be as low as 2-5 per 
cent in May, and as much as 31-5 per cent in August. 
In summer the adipose tissue forms two distinct layers, 
one situated just below the skin, the other being parallel 
to the first, but separated from it by a layer of muscular 
tissue. In winter the oil content becomes so small 
that these layers of adipose tissue disappear. A com- 
paratively small amount of oil is contained in the liver 
of the fish. 

In gadoid fishes, e.g. cod, as well as in skates 
and rays, the oil is almost entirely confined to the 
liver. During the summer the liver grows larger and 
richer in oil, until sometimes the oil amounts to more 
than half the total weight of the liver. (When cod are 
caught the livers are removed and kept apart, to be 
treated subsequently for their oil.) The percentage of 
oil in the flesh of the cod varies from 0-1 per cent to 1-0 
percent. Unlike that of the herring, therefore, the food 
value of the flesh of the cod does not fluctuate markedly 
according to the season. 

When fish are dry-salted a certain proportion of the 
proteins and mineral salts in the flesh is extracted by the 
brine pickle that is formed. In Russia and Poland, 
where the greater proportion of salted herrings are 
consumed, the peasants eat them without further 
cooking, and also consume the pickle. 

A great gain in food value per pound results from the 


THE FOOD VALUE OF FISH 119 


removal of so much water from the flesh of the fish. 
Freshly caught cod flesh contains about 80 per cent 
water and 17 per cent protein ; after being dry-salted 
for export it contains about 25 per cent of water and 
55 per cent protein. 

Thus, 1 Ib of dry cod is equal in food value to about 
3 lbs. of fresh cod. The increased food value of salted 
fish will be seen from the following analyses— 


Tue EFFECT OF CURING AND DRYING UPON THE FooD 
VALUE OF DIFFERENT FISHES 


Carbo- 
Pro- | Food 
Food. an Fat. | hyd- | Ash. |Water. Value 

| rate. | 
Cal. 
' j per Ib. 
Haddock (fresh) 120} 02) — | 09 | 51-6] 232 
» (smoked) | 149 | 0-2| — | 3-4 | 57-4 | 286 
Herring (fresh) 14-0 | 10-4 | — | 1-5 | 457 | 699 
»» (salted) 21-2 | 154 | — | 7:7 | 309 | 944 
; (bloater) | 15-7) 96, — | 1-5 | 520] 697 
tkipper) | 14-1] 11-1 | —"|-3-4 base | 790 
Sprats (fresh) 12-6 | 10-7 | — | 1-3 | 49-4 | 686 
: (smoked) | 21-2 | 149 | — | 3-2 | 39-4 | 1,023 


Thus, the food value of salted sprats or herrings per 
pound is 50 per cent more than that of the same fish 
when fresh. 

The original food value of a fish is generally diminished 
by the cooking process. The fish may be boiled or broiled 
for direct consumption, or it may be steam cooked in 
cans and sealed up for future consumption, as in the 
canning industry. When oily fishes, such as herrings, 
are cooked, the oil globules burst and some of the oil 
is lost, and the food value of the fish becomes correspond- 
ingly less. When salted fish is soaked in fresh water 
before being cooked, some of the gelatin and other 
coagulable proteins are extracted from the flesh. This 
loss of protein can be checked either by broiling the 


120 THE FISHING INDUSTRY 


fish, when the protein near the surface becomes coagulated 
and so prevents the loss of protein from the interior of 
the fish, or by placing the fish that is to be boiled direct 
into boiling water, and not into the cold water before 
the heating has begun. 

In addition to this diminution of the food content of 
the fish, the process of cooking, contrary to general 
expectation, also diminishes slightly its digestibility. 

In the canning process the fish to be canned are 
cleaned (gutted) and boned, and packed into tins, 
together with the necessary sauce or seasoning. The 
tins are then closed, a small hole being left temporarily 
in the lid. The tins are placed on steam-heated racks, 
and the contents thoroughly cooked. In this way the 
contents are sterilized as well as cooked, and the air origin- 
ally present in the tin is all driven out by the steam 
through the small hole in the lid. This hole is sealed 
with a spot of solder while the contents of the tin are 
still at boiling point. The tin and its contents are 
allowed to cool down, and are dispatched to the store- 
room. During storage the contents of the sealed tin 
gradually ‘‘ mature.” This maturing process may last 
from six months to ten years. During this period 
the bones soften, the flesh becomes soft and pasty, and- 
the taste becomes richer. The precise nature of the 
changes that take place during this maturing process is 
not fully understood; probably maturing is partly 
due to the action of certain enzymes in the flesh of the 
fish, and partly to the slow but continuous chemical 
action of the various juices present in the tin. Attempts 
to pickle herrings from the Zuyder Zee have been 
unsuccessful owing to a lack of the enzyme action that 
makes other herrings tender when pickled. The 
enzyme, although present, is apparently rendered inactive 
by the presence of an anti-enzyme. 


THE FOOD VALUE OF FISH 121 


The last, but by no means the least, important 
factor to be considered in estimating the food value of 
any particular fish is its retail price. The price of the 
different kinds of fishes is by no means proportional to © 
their individual food values. It is determined primarily 
by the abundance or otherwise of the available supply 
of each individual species. Thus, the various pelagic 
fish—mackerel, herring, sprat—that are easily caught in 
enormous quantities at certain seasons of the year are 
by far the most valuable. Of trawl-caught fish, cod and 
whiting are more plentiful and are, therefore, cheaper 
than hake, although, again, the cheaper fish has the 
greater food value. 

In some cases certain fish, although fairly abundant, 
are in poor demand owing to some prejudice on the part 
of the public, and are generally sold in poorer districts, 
or to the fried fish trade, at a disproportionately low 
price, for example skate, dog-fish, angler fish, john 
dory. 

Taste and appearance also contribute to the popular- 
ity and, therefore, indirectly to the retail price of fish, 
such as the sole and the salmon. F 

In Table IV the present retail prices (Sept., 1921) 
and the food values of a number of different fishes are 
compared. From these figures, the actual food value 
per shillingsworth of each fish has been calculated. 

The cheapest fish, therefore, are also those possessing 
the greatest food value, e.g. the herring in all its forms, 
dried cod and ling, and mackerel. These compare 
favourably both in cost and food value with meat, such 
as beef and mutton. 

Finally, the popularity or otherwise of any food- 
stuff necessarily depends upon its flavour. Fishes 
differ greatly in this respect. In many cases the flavour 
of a fish can be seriously impaired by an unsuitable 

9—({14575) 


122 THE FISHING INDUSTRY 


TABLE IV 
Foop VALUE PER SHILLINGSWORTH OF DIFFERENT 
FISHES 
Retail |Food Value 
Fish. Eb ee Price per 
°- |\Sept. 1921} Shilling. 
Cals. per lb. 
per |b. sdk 

Halibut (cuts) . ‘ ‘ 258 2-3 115 
Sole : : ; : 346 Ze 138 
Turbot z , j , 270 .-6 180 
Brill ‘ s : d 327 1 8 196 
Haddock . 3 : ; 232 Le 198 
Hake - ; : 256 is 204 
Smoked haddock : : 286 Leg 228 
Plaice J 3 : é 367 16 244 
Cod (section) ; : : 296 sey | 252 
Whiting . : : : 215 — 10 258 
Salmon (section) . ; ; 847 3 - 282 
Eels . : ‘ : ‘ 799 1 10 436 
Dried ling . ; i : 560 1 - 560 
Mackerel . = : * 515 -— 10 618 
Dried cod . : A 750 1 - 750 
Kippered herring ‘ ‘ 730 - 9 972 
Herring . : : 709 - 8 1062 
Bloaters . ; : - 715 - 8 1072 
Red herrings. ; . 1220 - 8 1830 
Salt herrings . ; ; 1129 — 5 2712 


method of cooking. A full-flavoured fish like the 
mackerel lends itself to a variety of methods of cooking, 
equally good results being obtained by baking, grilling, 
frying in fillets or boiling. The plaice, sole, ling, hake, 
mullet, and turbot are essentially fish for frying, while 
cod, haddock and whiting are best boiled. To prepare 
a fish for the table requires considerable skill, but it is 
an art that, once acquired, can be used to render even 
what are regarded as inferior varieties both wholesome 
and palatable. In this country, fishes have long been a 
neglected form of food. They have a high food value, 
they are easily digestible, and are cheap and plentiful. 


THE FOOD VALUE OF FISH 123 


It has been shown recently that edible fish contain 
vitamins. Vitamins are complex chemical compounds 
of hitherto unknown composition, and of little under- 
stood properties, that occur in minute quantities in a 
great variety of natural food stuffs. These vitamins 
appear to be essential to healthy animal existence. 
Without them, the body rapidly becomes attacked by 
certain diseases, e.g. rickets, beri-beri, scurvy, and 
unless this deficiency of the diet is corrected, death soon 
follows. Three different vitamins have been discovered, 
known as vitamins A, B, and C. Vitamin A is con- 
tained in the oily part of most fish, while Vitamin B is 
present in certain fish roes. 


CHAPTER XI 
FISH PRODUCTS 


THE industrial value and importance of fishes is by no 
means limited to their use as food. They yield large 
quantities of valuable oil. The fish waste, or offal, 
chiefly heads, skins, bones and viscera—that is discarded 
by the fish curer, is worked up to yield fish glue, fer- 
tilizers and cattle food. The skins of certain large 
fishes, for example the shark, are tanned and 
manufactured into a valuable leather. 

The story of the fishing industry would not be complete 
without a brief description of the methods by which 
these products are manufactured. 

Fish Oils. The various kinds of oil that are obtained 
from different species of fish and other marine animals, 
such as whales and seals, may be divided into three 
classes, according to the part of the fish from which 
they are extracted. 

(1) Fish oils proper are disseminated throughout the 
flesh of the fish in the form of fine globules. They are 
extracted from the entire fish, e.g. herring, sardine, 
sprat, menhaden. 

(2) Liver oils are located in the fish liver, e.g. cod, 
shark. 

(3) Blubber oils constitute'a thick layer of adipose 
tissue just under the skin of the marine mammalia, 
e.g. whale, seal, dolphin, porpoise. 

In oily fish, such as herrings and sprats, each minute 
globule of oil is enclosed within a thin skin. It is prac- 
tically impossible to rupture this skin and liberate the 
oil simply by the application of pressure, When, 

124 


FISH PRODUCTS 125 


however, these globules are heated the skin shrivels, 
the oil globules expand and burst the skin, and the liquid 
oil is liberated and can then be extracted from the flesh 
by pressure. To obtain the oil, therefore, the fish are 
boiled or steam heated in large vats until the oil is set 
free. The hot mass is then placed in a press and the oil 
squeezed out. The residue is made into cattle food and 
fertilizer. 

In obtaining the best sorts of liver oils, e.g. codliver 
oil, the livers are taken from the fish assoon as they are 
caught, and are heated in steam-jacketed vessels until 
the cell membranes burst and the oil exudes. The oil 
is then separated by pressure. 

Inferior qualities of oil are obtained by treating 
putrid livers in the same way at the end of the voyage. 
These tainted liver oils are unfit for medicinal purposes, 
but are used in large quantities in the leather industry. 

Blubber (which is from 8 to 20 ins. thick) is stripped 
from the whale as soon after capture as possible. 
Generally the dead whale is made fast alongside the 
whaler, a deep, spiral cut is made round its body, and the 
blubber is stripped off and hauled aboard. This is then - 
cut into pieces, chopped up in mincing machines and fed 
into melting pans and heated with steam, often 
under pressure. The oil gradually exudes and 
collects upon the water, the cell membranes, etc.—the 
greaves—settling to the bottom. At the conclusion 
of the boil, the oil is drawn off from above the aqueous 
(gluey) layer, and is clarified by straining through sieves 
or filters. The “ greaves”’ is placed in hair or woollen 
bags and-submitted to hydraulic pressure, by which 
means a further quantity of oil is obtained. - 

Fish oils, unless specially purified for medicinal pur- 
poses, are dark-coloured liquids, with a characteristic, 
unpleasant, fishy smell, due to the presence of small 


126 THE FISHING INDUSTRY 


quantities of fishy decomposition products, for example 
trimethylamine. 

When cooled, many samples of fish oil deposit solid 
masses of fish tallow (fish stearine). 

Fish oils, and, to a less extent, the marine animal 
oils, e.g. whale, seal, porpoise, are drying oils like 
linseed oil, that is they possess to a very marked degree 
a capacity for absorbing oxygen from the air, and so 
become thickened and viscous. This thickening is 
generally induced by blowing air through the warm 
oil. Oils that have been thickened in this way are 
known as “blown ”’ oils. 

Blown fish oils are mixed with mineral oils for use as 
lubricants for heavy machinery. They have been used 
as vehicles for paints in place of linseed oil, but with 
somewhat disappointing results. They are used 
successfully in place of linseed oil in the manufacture of 
printers’ ink, and in making paints for painting smoke 
stacks. Such paints resist successfully the action of 
heat and light. 

More particularly, they are used in the leather 
industry. Fish oils are used chiefly in the manufacture 
of chamois leather. “Ordinary chamois or wash-leather 
is made from the flesh-splits of sheep skins. The skin 
is well washed and softened, and freed from hair by 
treatment with lime. It is then split, and the loose and 
fatty middle layer removed by a sharp knife. The lime 
is removed by a short bran-drench and the superfluous 
moisture is pressed out. The skin is thus rendered 
porous and easily able to absorb the oil. It is stretched 
on a table and oiled with fish or whale oil. The oiled 
skin is folded up and worked for two or three hours in 
the faller stocks and then shaken out and hung up for a 
short time to cool and partially dry. The process is 
repeated a number of times, until all the water originally 


a a a ee 


a ee 


FISH PRODUCTS 127 


present in the skin has been replaced by oil. The oiled 
skins are then piled in a warm place. The oil gradually 
oxidizes—probably owing to some fermentation process— 
and the skins become yellow and very hot. From time 
to time the skins are strewn on the floor to cool and then 
re-piled, the process being repeated until the oxidation 
of the oil is complete. In France the freshly-oiled 


‘skins are hung in hot stoves, and the oxidation of the 


oil is completed in one operation. . 

The skins are then dipped in water and passed through 
hydraulic presses, by which the surplus oil is removed. 
This surplus thick, oxidized oil is known as “ degras” 
or ‘‘ moellon,” and is used for stuffing leathers that have 
already been tanned. Stuffed leathers are supple and 
impervious to water, and are used for harness, belting, 
etc. A further quantity of oil may be removed from the 
“chamoised ”’ leather by treating it with potash or 
carbonate of soda, “‘ sod ” oil being recovered from the 
extract by neutralization with sulphuric acid. The value 
of sod oil for oiling dressed leather is due to a resinous 
acid of unknown composition, that is soluble in alkali 
but insoluble in petroleum ether. 

Enamel or patent leather is generally coated, after 
tanning, with a linseed oil varnish, boiled with prussian 
blue, and dried in a steam heated chest at 70° to 80°C., 
the process being repeated until a sufficiently thick 
coat is produced. Fish oils are now used successfully 
in place of linseed oil. The enamel leather produced, 
although not quite so glossy as that made with linseed 
oil, is said to be more pliable. 

Fish oils are also employed in the manufacture of 
such closely-related, although happily diverse, substances 
as soap and margarine. All animal and vegetable 
fats and oils are essentially compounds of glycerine, 
with one or other of three acids : palmitic, stearic and 


128 THE FISHING INDUSTRY 


oleic. Palmitic and stearic acids and their compounds 
are solids at the ordinary temperature, whereas oleic 
acid and its compounds are liquid. This difference 
appears to be connected in some way with the molecular 
structure of these substances. When oleic acid is heated 
with hydrogen gas under pressure, in the presence of 
finely-divided nickel, it absorbs hydrogen and is trans- 
formed into stearic acid. Oleic acid, therefore, is said to 
be unsaturated with respect to hydrogen, whereas 
stearic acid is called a saturated acid. This process, 
whereby a liquid oil is transformed into a solid fat, is 
called hydrogenation, or hardening. 

Both the margarine industry and the soap industry 
require large quantities of hard fats. Originally the 
soap industry absorbed the available supplies of hard 
animal fats such as beef suet, hog’s lard, and mutton 
suet. The margarine industry depended upon these 
same supplies of animal fats, and the rapid growth in 
the production of margarine during recent years has 
seriously diminished the supply of hard fats necessary 
for the manufacture of soap. 

The hydrogenation of whale oil and various fish oils 
has now made it possible to supply this demand, and 
has also made possible the industrial utilization of 
substances, such as fish oils, for which formerly 
comparatively little use could be found. 

Hardened whale oil melts at 40° to 50°C., and is a 
white solid entirely devoid of taste or smell. It is used 
for making soap, and as a lard substitute for cooking 
purposes. 

Fish Glue. Fish glue is the most important liquid 
glue on the market. The bulk of the fish glue manufac- 
tured to-day is made from the waste and offal that are 
discarded by the curers. This waste consists of heads, 
bones, viscera and skins. The best glue is obtained from 


FISH PRODUCTS 129 


the skins of non-oily, demersal fish, for example cod, 
haddock, soles, plaice and hake. 

The waste is washed in running water to free it from 
salt. Sometimes the waste—particularly the heads— 
is decomposed with hydrochloric acid and afterwards 
neutralized with lime. It is then charged into a cooker 
provided with a perforated, false bottom. The stock 
is covered with water and heated with steam. The glue 
is extracted and gradually concentrates in the water. 
When this glue liquor is sufficiently concentrated 
(from 5 to 6 per cent), it is run off (the first run) and more 
water is added to the waste and the cooking continued. 
After about 10 hours cooking, nearly all the glue has been 
extracted and the liquor is again run off (the second run). 
The cooked waste is then withdrawn, and any remaining 
glue liquor is pressed out of it and added to the second 
run. From 2 to 4 per cent of phenol or boric acid are 
added to prevent decomposition by bacteria. 

The glue liquor is evaporated down to a concentration 
of 32 per cent in open vats or closed evaporators, and is 
bleached with sulphurous acid. A small amount of 
some essential oil, e.g. cassia, clove, wintergreen, is 


- added to check mould growth and mask the fishy 


odour. Glue is also made in a similar way from the 
“‘ greaves ”’ obtained from whale blubber. 

Fish glue is manufactured in three grades. 

GRADE I is made from skins, only the first run being 
used. It is used for photo-engraving work, for the 
production of half-tone plates. 

GRADE II is made from second run skin liquors and 
fish waste. It is sold in small cans and bottles for 
general repair work. 

GRADE III is prepared from fish heads, and is sold 
in large cans and barrels for sizing, box making, cabinet 
making, and general joiner work. 


130 THE FISHING INDUSTRY 


The glue is sometimes made more flexible by the 
addition of glycerine and glucose. The flexibility of 
fish glue makes it useful for the manufacture of court 
plaster, labels, stamps, and in book-binding. 

The residue from the press is dried and sold as chicken 
feed or fertilizer. For the latter purpose it is frequently 
mixed with Carnallite. 

Fish Gelatine. Fish gelatine or isinglass is obtained 
from the swimming bladder of the sturgeon and also 
of the cod. The bladders are exported, either opened 
(pipe isinglass) or washed, split open and dried (purse, 
lump or leaf isinglass). . 

Isinglass is the purified and dried inner skin of the 
bladder. It has but feeble adhesive power. It is used 
for clarifying wines, ciders and beers, and for making 
jellies and plasters. 

Fertilizers. In many places near the sea, fish are 
employed whole as manure. Sprats particularly are 
caught in large numbers and distributed over the fields, 
and left to decompose. Fresh sprats contain 63°7 per 
cent of water, 1°94 per cent nitrogen, 2°1 per cent ash 
(0-43 potash and 0-90 phosphoric acid). 

Fish guano or fish manure is generally prepared from 
the fish waste discarded by the curer. An average 
sample of this manufactured fish manure will contain 
12 per cent water, 60 per cent organic matter, yielding 
10 per cent ammonia, 16 per cent of calcium phosphate, 
and a residue of salt, sand, magnesia and potash, the. 
amount of potash being inconsiderable. Fish guano is 
mainly valuable as a source of ammonia, the ammonia 
content ranging from 6 to 11 per cent, according to the 
kind of fish used and its previous history, e.g. whether 
fresh or salted. 

In many places, such as London, the fish offal from the 
shops and restaurants is collected, dried and ground up 


, 
4 
] 


FISH PRODUCTS 131 


for use as manure. In Germany in 1918 herrings’ 
heads were removed by the curers to be utilized for the 
production of oil, albumen, and phosphate of lime. 
The herring meal contained up to 50 per cent of albumen 
and calcium phosphate, the latter being obtained from 
the bones and heads. The albumen was extracted 
chemically and prepared for human consumption. 
The oil was extracted with benzol or other solvents, 
and, after hardening, was used in the manufacture of 
butter substitutes. Fish waste or offal is fed into a 
continuous cooker. This cooker consists essentially 


’ of a long, cylindrical vessel, through which runs a hollow 


steel shaft on which are mounted perforated radial 
vanes in such a way that the whole arrangement forms 
a spiral conveyor. By means of the hollow shaft and 
vanes, steam is blown into the mass of fish waste as it 
travels slowly through the vessel, so that it is completely 
cooked and disintegrated by the time that it emerges 
at the other end. 

The cooked mass is then fed into a press in which a 
screw conveyor urges it through a gradually tapering 
cylinder with perforated sides. In this way the oil is 
extracted from it, and it is then dried and disintegrated 
by a rotary drier. 

There is always a little residual oil in fish manure 
that tends to delay its decomposition in the soil. It is 
important, therefore, that the oil be removed as 
completely as possible. 

Dry fish manure requires careful storing, as the 
presence of this.small amount of oxidizable oil tends to 
promote spontaneous combustion. 

In addition to its value as a fertilizer, the high content 
of protein (albumen)—namely, 50 per cent—makes fish 
meal a suitable food for live-stock and poultry. 

The commercial importance of this industry will be 


132 THE FISHING INDUSTRY 


realized when we remember that practically half of the 
total catch of fish in the world is discarded by the 
curers as waste. 

Fish Leather. The hides of such marine mammals 
as the walrus and the seal have long formed the basis 
of a regular tanning industry. 

Of recent years, however, particularly in America, 
successful attempts have been made to tan the skins of 
certain fish, notably the shark. The skins are treated 
with alkali to remove fat and oil, the alkali is then 
neutralized with acid, after which the skins are washed 
and tanned. The leather is said to be soft and pliable, 
and well adapted for many uses. 

Shark skins are also tanned hard, and used to print 
a grain on imitation pigskin. 

Shark fishing was commenced off the American coast 
in October, 1918. The fish are hunted from fast, power- 
ful motor boats, with specially constructed nets. A small 
shark 5 ft. long will yield a hide 10 sq. ft. in area. 

Shark skin is naturally very tough and durable, and 
in its untanned condition is used by jewellers as a natural 
emery paper for grinding and polishing metal surfaces. 
It is also used as an abrasive in working hard woods and 
ivory. 

A method has been devised by which a shark skin 
can be split into three. The first split, after tanning, 
is strong and thick, and suitable for high grade, heavy 
shoes. The second furnishes leather suitable for 
second grade foot wear, and the third resembles suede 
and is used in making fancy articles. In addition to 
the shark’s skin, the fins, blood, teeth, flesh, and oil 
of the fish are also utilized commercially and yield a 
satisfactory profit. 


INDEX 


AMBERGRIS, 106 
Anadromous fish, 38 
Angler (devil) fish, 18, 32 


Beam trawl, 46, 77, 86 

Berried lobsters, etc., 35 

Bivalve, 94 

Black (southern right) whale, 
100, 102 

Bloater, 60, 66 

Blue whale, 104 

Brill, 24, 31, 78 

Brine pickling, 5, 110 


CACHALOT (sperm) whale, 100, 
104 


Canning of fish, 92, 93, 108,120 

Capelan, 70, 100 

Cast net, 52 

Cat-fish, 16 

Clams, 73 

Cockle, 25, 27, 53, 74, 90, 93 

Cod, 2, 19, 21, 22, 30, 31, 32, 
34, 37, 43, 48, 69, 78, 86, 89 

fishing, 69-76 

— liver oil, 69, 76 

Cold storage, 108 

Cooking of fish, 122 

Copepoda, 27, 30, 36, 90 

Crab,25, 35, 52, 90 

Cran, 58, 64 

Crustacea, 25, 27, 30, 31, 36, 
90, 102 

Cutter, 77 


DEMERSAL fish, 19, 21, 31, 89 
Diatom, 28, 90, 96 
Distribution of fishes, 18-27 
Dog-fish, 31, 32, 34, 35, 116 
— whelk, 94, 96 

Dolphin, 24 


Dory fishing, 70 
Drifter, 10, 50, 56 
Drifting, 50, 56-8, 88 
Drift net, 50, 56, 77 


_ Drying of fish, 75, 108 


EEL, 16, 38, 44 
Eggs of fishes, 27, 28, 32, 34, 
35, 69, 90 


Fin whale, 104 


| Fish fertilizer, 4, 62, 76, 130 


glue, 4, 76, 128 

—— hatching, 3, 4, 92 

leather, 4, 132 

— meal, 4 

oil, 4, 76, 124-8 

Fishery salt, 112-114 

Fishing grounds, 10, 30, 69, 
80-81, 83 

—— traps, 42 

weirs, 42 

Fixed engines, 43 

Flake drying, 75 


_ Flounder, 16, 19, 22, 32, 39 
Food of fishes, 25, 27, 30, 31, 


69, 94 


| —— value of fish, 37, 54, 115 


| Grits, 16, 24, 25, 31, 94, 95 


Grampus whale, 24, 104 

Grayfish, 116 

Greenland (Arctic right) whale, 
99, 102 

Gutting fish, 72, 113 


Happock, 2, 19, 22, 31, 32, 
34, 37, 48, 70, 78, 86, 119 

Hake, 22, 31, 70, 78 

Halibut, 22, 48, 89 

Harpoon, 42, 102, 104 


133 


134 


Herring, 19, 24, 27, 30, 31, 32, 
34, 36, 37, 50, 54, 55, 70, 74, 
89, 91, 100, 111, 117, 119 

fishing, 5, 9, 14, 48, 50, 
54, 60, 67, 68, 88 

Hose net, 44 

Humpback whale, 104 


Ice, 83 

Immature fish, 3, 52, 86, 88 

Incubation period of fish eggs, 
35 


Inshore fisheries, 11-13, 15, 50 
Isinglass, 69, 130 


JELLY fish, 28, 30, 77 


KATADROMOUS fish, 38 
Kenching, 72, 110 
Kipper, 60, 66 


LARVAE of fishes, 27, 30, 34) 
35, 36, 38, 91 

“Last ’”’ of herrings, 58 

Limpet, 94 

Line fishing, 42, 43, 70-72, 73, 
74, 78 

Ling, 22, 31, 32, 78 

Littoral fishes, 21 

Lobster, 25, 35, 52, 90-92 

Lobster pots (creels), 42, 91 


MACKEREL, 18, 25, 27, 30, 31, 
39, 44, 50, 89 

Mesh of nets, 47, 52, 86, 88 

Migration of fishes, 36-40 

Mollusca, 25, 27, 30, 31, 36, 
90, 93, 94 

Mullet, 19 

Mussel, 25, 27, 35, 53, 90, 93, 
97-98 


NEts, 43 


OTTER trawl, 48, 81 

Overday herrings, 60, 66 

Overfishing, 3, 11, 80, 84, 86, 
91, 96 

Oyster, 25, 27, 35, 90, 93, 94-97 

culture, 95-97 


INDEX 


PELAGIC fishes, 24, 30, 31, 89 

Periwinkle, 25, 35, 53, 94 

Phosphorescence, 18, 40, 41 

Pilchard, 25, 31, 44 

Plaice, 2, 16, 19, 22, 25, 30, 
32, 34, 35, 36, 37, 38, 44, 
46, 48, 78, 86, 89 

Plankton, 24, 27, 28-31, 33, 
35, 36, 40, 69, 90, 94, 100 

Poke net, 44 

Porpoise, 24, 99 

Prawn, 25, 30, 35, 90 

Preservation of fish, 15, 107 
(See also canning, drying, 
salting.) 

Productivity of the sea, 28 

Purse net, 44 

seine, 44 

Push net, 52 


Rep herring, 60, 64 

Reddening of salted fish, 114 

Reproduction of fishes, 32, 95, 
102 

Rorqual whale, 100, 102, 104 


Satmon, 19, 31, 38 

Salt herring, 60 

Salting of fish, 5, 6, 62-64, 72, 
74, 109 


Seal, 99 
Sei whale, 104 
Seine, 44 
Shad, 4, 19, 38 


Shark, 4, 16, 19, 24, 32, 34, 
43, 132 

Shellfish, 90-99 

Shrimp, 25, 30, 35, 52, 86, 90, 
92, 93 

Skate (ray), 6, 22, 24, 32, 34, 78 

Skin of fishes, 4, 16, 132 

Smack, 9, 46, 77 

Smoking of fish, 64, 65, 66 

Sole, 2, 16; 19, 22, 31, 32; 78; 
86, 89 

Spawning of fishes, 19, 24, 32, 
34, 35, 37, 38, 39, 50, 54-55, 
90, 95, 117 


INDEX 135 


Spermaceti, 102, 106 
Sperm oil, 102, 104, 106 
Sperm whale, 100, 104 
Sprat, 25, 27, 50, 91, 119 
Squid, 70 

Stake net, 43 

Starfish, 50, 96 

Steam fishing, 9, 78, 80, 84 
Steam trawler, 10, 77, 81 
Stickleback, 19, 35 
Sturgeon, 16 


Tre fish, 116 

Trawl (line fishing), 71 

net (See beam trawl, otter 
trawl.) 

—— —— (shrimps), 2, 52, 93 

Trawling, 2, 3, 9, 10, 46, 77-89 

for herrings, 88-89 


Tunny, 24 
Turbot, 24, 31, 32, 78, 89 


UNIVALVE, 94 
VITAMINS, 123 


WaALruws, 99 

War service of fishermen, 84 

Whale, 24, 99 

—hbone, 100, 102, 103, 104, 
105 

— fisheries, 99 

— oil (blubber), 103, 104, 
105 


, 94 
‘Whiting, 22, 31, 34, 52, 78, 86 


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Economic History. (See “ Economics ’’ below.) 
Elements of Commercial Geography.. 


By C. H. Grant, M.Sc., F.R.Met. Soc. . . Net 
Elements of Commercial History. 

By Freep Hatt, M.A., B.Com., F.C.1.S. . - Net 
Examination Notes on Commercial Goograna 

By W. P. Rutrer, M.Com. . - Net 
Principles of Commercial History: 

By J. STEPHENSON, M.A., M.Com., B.Sc. . Net 
The World and Its Commerce. Net 

ECONOMICS 


British Finance (1914-1921). 
Edited by A. W. KirKALpy, M.A., B.Litt.,M.Com. Net 


British Labour (1914-1921). 
Edited by A. W. KirKaupy, M.A., B.Litt.,M.Com. Net 


Dictionary of Economic and Banking Terms. 
By W. J. WESTON, M.A., B.Sc., and A. CREw Net 


Economic Geography. 
By JoHn McFAar.LAneg, M.A., M.Com. ‘ - Net 


Elements of Political escape 


By H. Hatz, B.A. . Fi - Net 
Guide to Political Boocotee: 
By F. H. Spencer, D.Sc., LL.B. . ° - Net 


8 


Economics—contd. 


History and Economics of Transport. 
By A. W. Kirgatpy, M.A., B.Litt. xtra M.Com. 
(Birm.), and A. DUDLEY EVANS z - Net 


Labour, Capitai and Finance. 
By “ Spectator ” (W. W. WALL, F.J.L, F.S.S.) . Net 


Local Government of the United ini! wet: 


By Joun J. CLARKE, M.A., F.S.S. ; Net 
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By Joun J. CLARKE, M.A., F.S.S. . : Net 


Outlines of Industrial and Social Réowatniees 
By Joun J. CLARKE, M.A., iitaicks aut Jase 


Pratt, A.C.LS. F - Net 
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By Joun J. CLARKE, M.A.,-F.S.S. . R - Net 


Outlines of the Economic History of England : 
A Study in Social Development. 


By H. O. MerRepiTH, M.A., M.Com. . - Net 
Plain Economics. 

By Joun Lee, M.A., M.Com.Sc. ' ; - Net 
The Housing Problem. 

By JouN J. CLARKE, M.A., F.S.S. . = - Net 
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BANKING AND FINANCE 


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Net 
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By J. F. Davis, M.A., D.Lit., LL.B. (Lond.) . Net 


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and in Practice. 


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Law. 


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Chairman’s Manual. 
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Edited by E. Martin, F.C.1.S. : Net 


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of Joint Stock Companies. 
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et 


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By L. M. GrBRETH : 4 - Net 
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BUSINESS HANDBOOKS AND WORKS 
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Business Man’s Encyclopaedia and Dictionary 
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17 


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Commercial Contracts. 
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PITMAN’S 
COMMON COMMODITIES AND INDUSTRIES 
SERIES 


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interesting non-technical style. Beginning with the life history 
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ea. Leather. 
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ee. Clays and Clay Products. 
By B. B. KEaB ie. By Aurrep B. SEARLE. 
. Paper. 
By Gro. Martryzav, C.B. Fis Harry A. Mappox. 
p. 
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By C. Beapite and H. P. Gums and Resins. 
Stevens, M.A., Ph.D., F.I.C. By Ernest J. Parry, B.Sc., 
Iron and Steel. F.LC., F.C.S. 
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Copper. By J. S. Harprxe. 
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By Horace Wvyart, B.A. 
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y R. J. 3 ARNES, F.C.S., 
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. 


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JAMES H. QUIETER. 
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KinGour. 
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Asbestos. 

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Silver. 

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By R. E. NEAtz, B.Sc. (Hons.). 
Butter and Cheese. 

C. W. WALKER TISDALE 

and JEAN JONES 
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Aluminium. 

By G. Mortimer, M.Inst. Met. 
Gold. 

By B. Waite. 
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By J. Atten Howe, O.B.E., 

B.Se., M.I.M.M. 
Lead. 

By J. A. Smyrue, Ph.D., D.Sc. 
The Clothing Industry. 

By B. W. Poouz, M.U.K.A. 
Modern Explosives. 

By 8. I. Levy, B.A., B.Sc., 

F.I.C. 
The British Corn Trade. 

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