Читать книгу British Battleships of World War One - R. A. Burt - Страница 9
ОглавлениеDesign Procedure
The designs for British capital ships were generally governed by certain requirements intended to ensure the ship’s capability for survival. Layouts had to conform to ‘standard Admiralty practice’, which took into account four features that were deemed essential:
1. Safety (stability, structural strength, etc.)
2. Potential foreign opponents
3. Time and cost
4. Docking facilities.
On any design committee would sit not only constructors but ship’s officers, engineers, ordnance experts, dockyard controllers and other specialist personnel experienced in warship construction. Each participant would be given a hearing and all opinions taken into consideration. This procedure meant more often than not that some essential features of the design could not necessarily be reconciled with others, and compromises would have to be reached, sacrifices being made in an endeavour to achieve a balance that would suit all the members of the committee. In most cases, this resulted in an ‘ideal’ warship being marred, usually because of the constant displacement restriction that was always of prime concern. Faced with innumerable problems, the British constructors not only came up with adequate designs, but more often than not with innovatory ideas that placed British ships well ahead of their rivals.
The British capital ship was expected to go anywhere and to operate as effectively in the Pacific Ocean as in the North Sea. Furthermore, they were expected to counter effectively any challenge from foreign navies, all of whose ships had differing features: the devotion to compartmentation and heavy armour plating of the German Navy; the prime importance of machinery and speed in Italian ships; and the ‘one-off’ experimental types of the French and Russians, which usually followed current trends in naval architecture and had no homogeneity among their respective fleets. Abroad, there was a strong tendency to design ships for the waters in which they would serve, and for the majority of powers, this meant home waters. The British warship, however, had to be a compromise of all these features and still be able to bring any antagonist to battle without being outclassed.
Builders
Ten yards were responsible for the construction of the battleships and battlecruisers that served in the Royal Navy during the First World War.
Armstrong An engineering firm founded in 1847, and a constructor of warships since 1882; in 1897 took over the firm of Joseph Whitworth; main yards at Elswick and Walker on the Tyne; other factories included ammunition works at Scotswood on the Tyne, Erith Engineering Works and an ordnance factory at Pozzuoli, near Naples.
Beardmore Warship constructors since the beginning of the twentieth century; also armour and ordnance manufacturers; yard at Dalmuir.
John Brown Sheffield steelworks; initially supplier of plates for warships; took over Thompson Shipyard on the upper Clyde in 1897 to become John Brown Construction Co.
Cammell Laird William Laird & Son were constructors in the 1840s of some of the very earliest iron vessels; became large warship builders from 1885; amalgamated with Charles Cammell Co., steel manufacturers of Sheffield, in 1903; yard at Birkenhead.
Devonport H.M. Dockyard, Devonport; warship construction here began in the last decades of the eighteenth century; the last battleship built here was Royal Oak, completed in May 1916.
Hercules at the Fleet Review, Spithead, in July 1914. This photograph was taken from the Royal Yacht by Mr Stephen Cribb, the official photographer.
Fairfield Founded 1864 by John Elder and Charles Randolph; 1869 carried on by W. Pierce and became Fairfield Shipbuilding and Engineering Co. in 1885; constructors of machinery, merchant ships and warships of all sizes; yard at Govan on the Clyde.
Harland & Wolff E. J. Harland bought Robert Hickson & Co. in 1859, and was joined by G.W.Wolff two years later; builders of great liners and merchant vessels as well as major warships; yard at Belfast.
Palmer Founded 1852; built early iron warships including Defence, Triumph and Swiftsure in the 1860s; yard at Jarrow on the Tyne.
Portsmouth H.M. Dockyard, Portsmouth, the oldest of the Royal dockyards; major dry dock facilities, repair shops, etc., as well as construction yards; the last battleship built there was Royal Sovereign, which was completed in May 1916.
Scotts Founded in 1711; builders of cargo vessels, then turned to marine engineering in 1823; began warship construction in 1849 at Greenoch.
Thames Iron Works Warship builders since the beginning of the nineteenth century; constructed Warrior, the first iron-hulled sea-going warship in 1859; yard at Blackwall; the firm went into liquidation in 1912 on completion of Thunderer, which was the last major warship to be built on the Thames.
Vickers Originally a steel firm, based in Sheffield; amalgamated with Maxim in 1883 and began the manufacture of guns; subsequently manufacturer of warships, weapons, ammunition and aircraft; yard at Barrow in Furness.
Armament
The primary raison d’être of a battleship or battlecruiser was to carry her armament and use it successfully against an enemy. The change from mixed calibres to an all-big-gunned ship in 1906 (as described on page 20) certainly brought no shortage of problems. Dreadnought adopted an echelon system of turret layout, with one turret forward and one aft, one amidships and one staggered on each beam, port and starboard. At the time, however, many authorities still looked upon the mixed calibre as the better method of arming a battleship, and hailed the Lord Nelson class as the final answer. There was indeed something to be said for mixed calibres: the most telling argument in favour of including a weapon of approximately 9.2in calibre (as in the Lord Nelson and King Edward VII classes) was the effective amount of metal that could be thrown per minute compared with fewer numbers of 12in guns:
Marlborough looking aft from the forecastle showing forward 13.5in turrets and bridgework, summer 1914.
If the smaller gun could be judged by these figures, the discharge at any given time would have been more than half as much more metal than from the 12in. It was inevitable that those who considered the 9.2in battery ought not to have been abandoned could strengthen their argument with facts such as these. Moreover, although Dreadnought carried ten big guns, she could fire only eight on either broadside because of the disposition of her echelon turrets.
Such deficiencies in the design were outweighed by the advantage gained in fitting all large-calibre guns – a necessity given the greatly increased ranges at which engagements were now being fought as shown by the Russo-Japanese War of 1904–5. The call for a main armament of eight or more guns of uniform heavy calibre was prompted by the need for maximum destructive effect and to facilitate long-range fire control by means of salvo firing and spotting the fall of shot.
The adverse criticism of those opposed to the new system did not deter the other major naval powers from following Britain’s lead, and all but the USA gave their early dreadnoughts the echelon fashion of mounting the big guns. The main armaments of the early dreadnoughts, both British and German, were adequate for the job and there was little to choose between them. But when the Queen Elizabeth class with their 15in guns were constructed, the lead in firepower and turret technology went to the Royal Navy. In fact, this gun and turret arrangement of four guns forward and four aft became ‘standard’ fitting for many successive warships.
Little good can be said of the British secondary batteries, which plainly lacked the punch required of them; they most certainly were not on a par with their German and French counterparts. From Dreadnought to the King George V class of 1910, the secondary battery of 4in guns was the subject of constant severe criticism, to which the Admiralty would not bend. The Board’s Victorian attitude was responsible for the major weakness in all British battleships and battlecruiser designs from 1906 to 1910, when the 6in gun was introduced in Tiger and the Iron Dukes.
Fire Control
At the turn of the century, the quality of big guns in warships was improving rapidly, with increasing accuracy and longer ranges. However, to shoot the guns to good effect and obtain an adequate percentage of hits on any given target efficient rangefinding equipment was vital. This applied in particular at ranges over 8,000 or 9,000 yards.
Optical rangefinders of various types were fitted in all warships, and many experiments took place to obtain a suitable system. By the time Dreadnought had arrived in 1906, rangefinders had evolved into a practical standard type of instrument; the best known, and most widely used in the world’s warships, was the Barr and Stroud ‘coincidence’ system, which was a short-base, split-image rangefinder of varying length (depending on position, between 3ft 6in and 9ft). The largest of these was quite capable of taking ranges accurately up to 8,000 yards. This system of improved rangefinding, however, did not give provision for passing information to the gunlayers within the turrets in order to modify ranges relative to the target’s course and speed. Electro-mechanical equipment had been introduced for this purpose some years earlier (basically an electrical transmitter that conveyed information from the rangefinders to the guns), but it did not prove successful. Later Captain J. S. Dumaresq and Sir Percy Scott developed improved types, while the fitting of Vickers rate-of-change clocks provided some further answers. A follow-the-pointer system was introduced in 1908; in this the range and deflection were transmitted from the fire control position direct to the sights of the guns by means of electrically-controlled pointers, which were rotated in front of the respective dials and indicated the point to which the dials had to be set for correction.
By 1916, the Royal Navy was using what was considered a highly elaborate ‘director control’ to back up a first class armament, a combination quite unmatched in foreign navies. Witness progress aboard Bellerophon, for example: she was fitted with a revolving tower aloft in which was located a 9ft Barr and Stroud rangefinder and a Vickers fire control table. Personnel in the tower consisted of the control officer, the rangefinder and rate keeper. This method was relatively new within the Royal Navy, but quickly became standard procedure. Most of the Grand Fleet’s battleships and battlecruisers were fitted with similar equipment, backed up by extra rangefinders in the turrets and bridgework. Doubts among contemporary fire control staff can be ascribed to inefficient training and hunting arrangements within the electro-mechanical gear. The principle itself was sound enough, allowing as it did the personnel to retain the same position regardless of the angle of the target; but the director towers in all British battleships afforded a restricted view because of the tripod masts.
After Jutland, in May 1916, director control came under close examination. It was now fully realized that this was one of the most important departments of a fighting ship, and certain aspects of the systems then in use had failed during the battle – the Barr and Stroud rangefinders had not given the required results because of the poor lighting conditions during the action. It was generally known that the Germans had Zeiss stereoscopic rangefinders, and a different method of fire control; the former was slightly superior to that used in British ships, but the latter, according to intelligence reports, was inferior to British equipment, and not up to requirements laid down by the Admiralty. This was borne out in 1919 after tests had been carried out in the captured battleship Baden: although much of the equipment had been sabotaged by the Germans, the fire control gear was examined and found to be relatively primitive.
From 1917, the Admiralty strove for a balanced and adequate fire control system, but an ideal layout was not in service until the middle of 1918. The war was nearly at an end by the time inclinometers were introduced, and highly trained staff were functioning with much improved director towers. By the end of 1918, all existing British capital ships were fitted with improved fire control, placed aloft as usual, but if possible the towers were repositioned on the control top rather than underneath it; if this were not possible, then additional rangefinders were fitted on top of the control top to give them an all-round vision. Small towers for the secondary armament were also being fitted on each side of the bridge, and there was also provision for director control to be worked from within one of the main turrets (usually ‘X’ turret). The towers themselves had been revamped and consisted of improved rangefinders, with many of the Barr and Stroud types having been replaced by different makes, and improved Dreyer or Argo electro-mechanical equipment. Personnel and their functions for the control was as follows.
Port quarter of Ajax in Devonport 1914. Note the director fire control in place.
HM King George V, Sir George Callaghan and Prince Albert on the forecastle of Neptune watching competition rough weather firing trials to try out Sir Percy Scott’s director system which was fitted to Thunderer against Orion without the system. Thunderer scored eight or nine hits compared with none for Orion.
1. Control officer: spotted the fall of shot to correct elevation and direction with direct fire, and maintained communications with the plotting and transmitting stations.
2. Rate officer: worked the inclinometer and decided the rate of fire due to enemy movement in conjunction with the transmitter office and the station rate officer.
3. Direction layer: laid and fired, but also worked the gyro direction training lamp.
4. Direction trainer: trained the tower on to the target and worked the synchronized training transmitter (by power or hand) and corrected the vertical datum line.
5. Direction sight setter.
6. Telephone operator.
7. Rangefinder.
8. Voice pipe and human link operator.
9. Tower trainer (back up).
10. Inclinometer operator (back up).
The crews for the secondary directors were identical, except that numbers 8, 9 and 10 were not required. Further aids to control were seen at the end of 1917, when deflection scales and range clocks came into existence. The deflection scales were painted on turret sides and tops (usually ‘B’ and ‘X’) and told the leading or following ship the angle of fire. They were only used if the ship ahead or astern could not use her own rangefinders owing to smoke or other conditions affecting her vision. The range clocks told other ships what range the guns were firing at (in thousands of yards) so that all ships could fire their guns in a concentrated effort even if only one ship could see or had operable rangefinding equipment.
Armour and Protection
The subject of armour applied to British and German ships has long furnished fuel for heated debate. The main armour strakes fitted to both nation’s ships were generally considered adequate to withstand heavy shell impact under normal battle ranges of the day. (It was envisaged that action would take place in about the 10,000-yard zone.) Although the German ships were given slightly thicker belts than their British opponents, there was very little to choose between them. War experience was to show, however, that as battle ranges frequently increased to over 10,000 yards, shells reached the target at a steeper trajectory, so that it was the deck armour that was threatened rather than the side of the ship. Here both British and German designs were deficient.
With regard to the oft-quoted superior strength and quality of German steel plates, it is interesting to note that when tests were carried out in the captured battleship Baden in 1919, only a slight difference was found between British and German steels; and when fired upon during the tests, her plates did not meet the strict standards required of British plates. Baden’s vitals were protected by Krupp armour, and it was very gratifying for the British to discover that the armour plates used in their later dreadnoughts were slightly superior to the Krupp process.
One feature in which many of the British battleships failed was the lack of adequate underwater protection against mine and torpedo attack. Dreadnought herself was fitted with protective screens covering the magazines and shell rooms, and this protection was seen as very innovatory at the time. It did not compare in any way with the first German dreadnought, however; Nassau was fitted with a continuous 1¼in anti-torpedo bulkhead protecting her vitals.
Some measure of rectification was seen in the Bellerophon class of 1907, in which particular attention was paid to suitable underwater protection. The screens were extended from ‘A’ to ‘Y’ barbettes and ran down to the double bottom, this forming a continuous anti-torpedo bulkhead that protected not only the magazines and shell rooms, but also the machinery and boilers. This was every bit as good as that fitted in the first two classes of German dreadnoughts (Nassau and Helgoland classes), but this great improvement over Dreadnought was not followed up in British designs, and a return to the small magazine screens was witnessed in the classes from Colossus to Iron Duke (1908–11 designs).
The last two British battleship classes to serve in the war (the Queen Elizabeth and Royal Sovereign classes) were provided with an anti-torpedo bulkhead protection system second to none and easily equal to anything produced for German ships throughout the entire war.
Shortly before the outbreak of war in 1914, work was undertaken to provide British battleships with adequate underwater protection. Experiments were hastily started at Portsmouth and Cambridge test centres. At Cambridge targets of in steel plating three feet square backed with angle iron ribs were constructed. The target formed the bottom of a floating tank, and a charge of 6–8oz of gun-cotton was detonated underwater a few inches away from it. Similar targets were prepared at Portsmouth, but scaled up to two and a half times the size, with proportionate charges under them. The targets at Portsmouth weighed about a ton. The distortion in both cases was compared and it was found that the smaller charge was relatively less effective than the larger one, but that the difference could be more than compensated by increasing its weight by 25 per cent. More tests of 1in plate with framing four feet apart, corresponding to a battleship’s hull, were carried out using a 400lb charge. The results provided the Admiralty with excellent data for the protection of big ships as for example, was applied to Ramillies, while she was under construction in 1915.
The Admiralty was aware that the largest torpedo used by the German Navy contained as much as 400lb of high explosive, and a charge of this order was capable of blowing a hole in a steel plate 6in thick. The protection of a ship by underwater armour was, therefore, impracticable because of the weight of armour required. Moreover, it was accepted that at the mean point of impact the ship’s structure would be destroyed over a very large area; with the ordinary plating then in use, it would work out at about 30 square feet. So protection would have to consist of either longitudinal bulkheads strong enough to remain intact and watertight after the explosion, or of an external hull fitting which would cause the torpedo to detonate outside the hull.
Of the two, the first method was the most widely used, and was fitted in its simplest form. The bulkheads were fitted approximately ten feet inboard from the outer hull, the space between being left empty to allow the gases from the explosion to expand and lose pressure and velocity. The problem, however, was that when the hull’s skin plating shattered, the small fragments were projected against the inner bulkhead at a velocity as high as 3,000fps which was capable of piercing up to 2in of steel plate.
Experiments were carried out to full scale on the old pre-dreadnought Hood, which was fitted with various bulkheads and structures on the hull. One test showed that when the space between the outer hull and the inner bulkhead was filled with oil, the fragmentation problem was overcome to some extent. The oil caused the blast pressure to be dispersed in all directions, which pointed to the need to strengthen the transverse bulkheads within the inner compartments of the hull, but in general it was better to have these compartments full than empty.
In August 1915, a possible solution to the problem of underwater defence was seen in a design submitted by Vickers to the Board of Invention and Research for a first class battleship having a speed, armament and above-water armour equal to the latest Admiralty designs, but having in addition an entirely new form of underwater construction for defence against torpedo attack. The novel defensive arrangement in this Design 742 consisted of a strong structural defence in combination with the subdivision of the side compartments in such a way as to allow the expansion of the explosive gases into empty compartments with the minimum of damage. After the gas pressures had diminished they would, in theory, be resisted by strong, circular, outer explosion bulkheads, which were termed the main defence. The arrangement was designed to resist 220lb of gun-cotton detonated against the ship’s side and, pending further investigations, could be made to resist a charge of 400lb. The system was made up of the following components:
1. The shell plating and frames of the ship, reinforced by horizontal timbers.
2. A perforated baffle screen of ¼in nickel steel, reinforced by a central, strong vertical steel stiffener and by horizontal timbers. The screen was approximately six feet from the ship’s outer shell.
3. The interior of each explosion compartment was provided with the above baffle screen which was liberally perforated by 12in diameter holes for the penetration of gases, and arranged so that the screen would, under pressure, fracture gradually.
4. Small transverse oil fuel compartments were placed between the explosion compartments in the wings of the ship in order to add to the oil fuel stowage, with the transverse bulkheads in these compartments so shaped that no direct thrust would be transferred from the outside of the ship onto the main bulkheads.
VICKERS BATTLESHIP DESIGN 742
September 1915
ADMIRALTY PROPOSALS
May 1915
The Board of Invention examined the design and reported to the Admiralty. The design, they reported, differed from existing Admiralty designs mainly in the provision of curved instead of flat bulkheads. The breakdown of inner transverse bulkheads under pressure after being struck was due primarily to the projectile action of fragments of the outer skin. These were sometimes projected with such velocity that bulkheads of up to 2in thick or more became riddled with holes and weakened to the extent that gas pressure could tear large holes in the structure. Vickers’ design would be damaged in the same way. Both the baffle screen and the main defence would certainly be pierced or badly damaged by an explosion, and the system was not viewed as very promising. Concluding remarks from the Assistant DNC, W. J. Berry, summed up the general feeling about the revolutionary system:
On the whole it is considered that the ship proposed would be slightly less vulnerable than the battleships now building, but this is entirely due to the feature of the underwater system being made the principal one. It is probable, however, that further investigations into the problem would result in a superior arrangement being arrived at; but not at the expense of modifying the machinery and armament from existing practice as seen necessary; the extra length, displacement and beam of this ship being accepted as part of the price paid.
Although this novel system of underwater protection was rejected, its submission shows that the problem was understood and a great deal of initiative was being used in an endeavour to come up with an adequate protective barrier against torpedo attack. At the beginning of the war, the need for this type of protection was not paramount in the design, but took second place to armour, armament and speed. Within a few short months, however, it was to become one of the most important features in ensuring a warship’s survival. That the Germans did not feel obliged to enhance their ships’ underwater protection reflects the obvious: their ships’ bulkheads were quite adequate for the job.
Anti-Torpedo Nets
When the torpedo made its appearance in about 1873, consideration was given in warship design towards a suitable method of protection against the menace. Progress was slow, and the torpedo’s menace seen as limited by its slowness and short range. By 1885, however, the torpedo-boat had arrived, capable of delivering a much-improved Whitehead torpedo reaching 30 knots and holding 200lb of gun cotton. When Dreadnought was completed in 1906, the Hardcastle torpedo then in use reached a speed of 33 knots, and had a range of approximately 7,000 yards. Countermeasures until then had been in the form of partially-armoured bulkheads within the ship’s hull, and anti-torpedo nets. The former in its original form, which did not cover all of the important areas of the hull, was limited in value; the latter in practice was not that successful either.
The idea went back to approximately 1876. The method was to surround the ship with heavy wire netting, which would catch the torpedo in its path and render it harmless. The nets were suspended from long booms fitted along the ship’s side; the depth of the nets when thrown out in to the water usually corresponded with the ship’s keel, and the nets hung vertically while she was at rest. If the ship were moving, however, the nets tended to drag and sway, which reduced their effectiveness.
EVOLUTION OF THE BATTLESHIP
In the event, the nets proved useless even when the ship was stationary. The old battleship Majestic was torpedoed during the Dardanelles campaign in 1915, while stopped and with her nets out. She was sunk, nevertheless, simply because the torpedo in question had been fitted with wire cutters in its nose.
Provision for anti-torpedo nets within the Royal Navy’s capital ship designs continued until 1911 (Iron Duke class), and was discarded in following designs. Those already fitted in ships were retained as late as 1916, even though it was accepted that they were of limited value.
Machinery
When Dreadnought was completed in October 1906, the Royal Navy was provided with the world’s first turbine-driven battleship. The German Navy, however, although conducting experiments, were prepared to procrastinate so far as turbine installation was concerned, and fitted their first four dreadnoughts with standard triple-expansion reciprocating engines. The Nassau class was provided with 20,000shp driving three screws, which gave them a designed speed of 19½knots. Their second group of four ships, the Helgoland class laid down in 1908, were also given reciprocating machinery, with a slight increase in power to 25,000shp, to provide a nominal speed of 21 knots – which gave them parity with British ships.
Ramillies, November 1917. Port quarter.
The German battlecruisers Von der Tann and the Moltke class, however, were fitted with Parsons turbines, which were much the same as those fitted in the Invincible class. Von der Tann was given a nominal 46,000shp for a speed of 24–25 knots, while Moltke’s was 52,000shp for 25–26 knots. On trials, however, the former reached 27½knots at 79,000shp; the latter 28½knots at 85,700shp. The boiler/machinery installation was pressed far beyond British safety limits, which reflects the great importance the Germans attached to having ships that could match or outstrip their British contemporaries.
One feature peculiar to the German ships was the weight saved in machinery and boiler rooms by using small-tube boilers and lighter materials than in British ships. The percentage of space and weight saved made the British designs look bulky in comparison. By Royal Navy standards, however, the German installations were decidedly cramped.
During the war there were frequent reports that the German dreadnoughts, both battleships and battlecruisers, suffered from machinery problems. Von der Tann had trouble with her turbine installation and both the Nassau and Helgoland classes were prone to engine-room trouble. Many of the difficulties were overcome in later ships. The British standard, well-proven turbine and large tube boiler installations were generally very reliable in all sea conditions throughout the war.
Camouflage
Although camouflage itself pre-dated the First World War, it was only in 1914 that protective colouring on warships began to make an appearance. The paucity of photographic evidence leaves some degree of uncertainty as to the patterns used, but it is certain that a high proportion of capital ships received such treatment at one time or another. During September 1914, in an experiment to ascertain what shades were most effective in making ships less visible, and in what lighting the shades would change, the battleships Audacious and Orion were treated to a ‘leopard’ pattern that featured large splashes of light grey, almost white tones, mixed on to a darker grey.
In some of the early schemes, black was the colour most frequently used, but it seems to have been confined to the smaller vessels (up to the size of destroyer), and soon became discredited in favour of a light-blue with greyish tints. Observations were carried out by Admiralty-appointed specialists with art experience, and G. Clark, who was one of these investigators, claimed that ‘of all the colours used, light grey, in my opinion, is best; it reduced visibility under nearly all atmospheric conditions, and when other ships painted normally stood out quite sharply in the early grey morning, the light-grey definitely made for better hiding.’ Such suggestions were passed on to the Admiralty, and the result was the appearance of more experimental schemes during the winter of 1914/15. The battlecruisers Princess Royal and Indomitable were painted in very strange patterns during the last months of 1914, as the evidence of existing photographs shows. During the winter of 1915, Superb sported a scheme of light patches on a medium-grey background; the light patches were white – see layout of camouflage in the colour plates section.
Taken from King George V showing Ajax and Centurion 1917/18, cleared for action giving a good ‘show’ from their funnels. Probably during a routine sweep in the North Sea.
Many of the ships deployed to the Dardanelles were camouflaged, the speciality of the time being a false bow wave intended to give a misleading impression of a ship’s speed through a U-boat’s periscope; it was soon discredited, however. If photographic evidence is anything to go by, most of the experiments were abandoned during the summer of 1915, especially in the big ships, but they reappeared in the spring of the following year, when various battlecruisers were to be seen with tiger-stripes around the funnels and long, dark-grey panels on their hulls to give the impression of a ship alongside. St Vincent, Bellerophon, Superb, Collingwood, Conqueror, Monarch, Tiger, New Zealand, Indefatigable, Queen Mary and Repulse were all photographically recorded with some type of experimental camouflage between 1915 and 1918, as the illustrations in the pages of this book show. How successful these unofficial experiments were is not certain because of the scarcity of official records on the subject. They can but have been of limited effectiveness, however.
A standard approach to camouflage did not appear until late 1917, when ‘dazzle’ was introduced by Lieutenant-Commander Norman Wilkinson, RNVR, who had submitted his ideas to the Admiralty in April of that year after being allowed to paint a test-piece, ‘HMS Industry’. It was generally recognized that it was impossible to render warships totally invisible at sea, especially to a submarine, when the ship was seen in full silhouette against the sky. No matter how light the shade of paint used, parts of the ship would always be in deep shadow, providing an angular contrast to betray her. However, the principal factors required by an attacking submarine were an accurate estimate of the target’s course and speed. The relative perspective position of masts and funnels provided the key to this. If invisibility were out of the question, at least it might be possible to mislead the enemy submariner: by painting a ship in such strongly contrasted colours and shapes, estimating her course or speed should be made considerably more difficult.
In June, experiments were carried out at the Royal Academy of Arts in Burlington House, London, where rooms were allotted for a ‘camouflage school’. Officers, modellers and artists were recruited for the project, and the application of ‘dazzle’ began in July. The Admiralty decided to paint fifty transport ships along the lines of Wilkinson’s first experiment and later, as a result of reports received, the entire mercantile fleet and a few selected warships were ‘dazzle’ painted. The 10th Cruiser Squadron, a few convoy cruisers and a number of sloops and gunboats joined the merchantmen in these strange patterns; so too did the battleships Ramillies and Revenge and the battlecruiser Furious. Unlike the merchant ships, however, the capital ships each received an individually-designed pattern. Ramillies was painted from November 1917 to March 1918; Revenge, although started in the same month as her sister, was only partially painted (hull only), and did not receive her full scheme extending over guns, masts, funnel and bridgework, etc., until January/February 1918. Both ships were repainted medium grey by April. Furious received her ‘dazzle’ during the Christmas period of 1917 and kept it until the spring of 1918.
Ordinary light and dark greys were deemed insufficiently contrasting, so the colours used were far stronger, ranging through greens, light and dark blues, blue-grey, four shades of grey, white, black, yellow and mauve. And it seemed to work: it was found that warships painted this way were more difficult to pick out at night than others painted entirely in dark grey. However – curiously enough – after the war, German U-boat officers denied that the dazzle painting of British warships ever confused them; yet German warships were seen with similar schemes during the Second World War!
Audacious showing her ‘one-off’ camouflage which was painted during September and October 1914.
Starboard quarter view of Repulse in her one-off experimental camouflage in early 1918.