The design of the T-class submarines was dictated by the requirements of an extremely large forward torpedo salvo capability and long patrol endurance for operations in the Pacific against Japanese warships, as well as the need to comply with treaty restrictions. These extremely challenging requirements led to many compromises in the design. Operational experience before and during the war led to many alterations and modifications to the class, and individual boats often differed noticeably from each other.
Hull and superstructure To accommodate the external forward torpedo tubes, most of the T class had distinctive bulbous bows. The original bow shape of the Group One boats adversely affected the speed while surfaced and two of the Group One boats had the external bow tubes omitted during refitting ( and , formerly
Thetis), resulting in a finer bow shape. Group Two boats had the external bow tubes moved further back, allowing for a finer bow shape that ended the speed loss. They also had two of the external torpedo tubes reversed to face aft along with an additional rear torpedo tube, resulting in a characteristic hump. The final Group Three boats had the bows further fined and the casing around the conning tower and rear-facing torpedo tubes flattened, resulting in a smoother profile. Pre-war T-class submarines were of riveted construction. The riveted hull proved remarkably strong, with many of the T-class boats exceeding the rated diving depth of during combat. survived a dive to on 23 April 1940. Welding in the hull construction was officially sanctioned by the Admiralty, after much hesitation, in July 1942 for the pressure hulls of the Group Three boats, later extended to the entire hull. Welded hulls were considerably stronger, allowing a diving depth of , with additional fuel carried in external
ballast tanks for increased endurance. Partly welded Group Three boats had riveted external ballast tanks; these were welded up before being sent to the Far East to prevent telltale oil leaks betraying the submarine's presence. The estimated crush depth was . The lead ship,
Triton, was completed with a very high open
bridge, which was very draughty. The following Group One boats had a slightly different bridge shape but these too were exposed, particularly problematical in heavy weather. Some of the Group One boats were fitted with closed cab-type bridges to resolve this problem; this became standard in the Group Two boats, but wartime experience found that the greater visibility from the open bridges was more important in action than the better habitability of the cabs, and the final Group Three boats reverted to the open bridge. T-class boats had eleven main (ballast) tanks, two auxiliary tanks for adjusting trim, five compensating tanks for adjusting to changes in water density and the displacement of the submarine as stores were used up, and the bow Q tank used for quick dives or rapid changes in depth. Two of the main tanks were converted into fuel tanks in the Group Three boats to increase endurance for operations in the Far East. Diving time from a 50 per cent buoyancy condition was good by British submarine standards at 30 seconds. The Group Two and Three boats had the fuel capacity increased on many boats to , giving a surfaced range of at .
Propulsion The T-class boats used a variety of
diesel engines depending on where they were built. Vickers-built boats used Vickers engines, while those from the
Royal Dockyards used Admiralty diesel engines; Cammell Laird boats used
Sulzer engines, while the pre-war Scotts boats had German
MAN supercharged diesel engines. These engines drove two shafts, each capable of for a top surfaced speed of about . The lead boat
Triton achieved on her first-of-class trials; this speed was never equalled by any of the other T-class boats, which usually managed about . The Vickers 6-cylinder 4-stroke injection diesel engines fitted to the majority of the T class proved to be very reliable, although less advanced than the diesels used by the German
U-boats. The engine could continue running even if one cylinder failed, by disconnecting the cylinder from the crankshaft. The 12 boats completed at the Royal Dockyards fitted with Admiralty diesel engines proved equally reliable although the engines were somewhat more complicated than the Vickers ones. The MAN diesels proved to be rather troublesome; they were built under license, and once the Second World War broke out in 1939, technical support from the German MAN company stopped. By 1943, only two of the T-class boats with MAN engines were left ( and ), and they were relegated to training. Even when the Royal Navy in the Far East was facing a critical submarine shortage in March 1944,
Tuna was not sent there due to her untrustworthy engines. The Cammell Laird Sulzer 2-stroke engines received mixed reviews; some boats, including and , were perfectly satisfactory, while the engines caused problems on others. They were insufficiently engineered for running at full speed, and the cylinder rings and blocks tended to crack. Submerged propulsion was provided by a 336-cell battery driving two Laurence Scott electric motors. These provided an endurance of 48 hours at , or only one hour at the maximum submerged speed of . The battery proved vulnerable to shock damage from
depth charge attacks. This contributed to the loss of in 1942, which sustained depth charge damage from the that ruptured her battery tank and filled the submarine with
chlorine gas, forcing her to surface and eventually surrender. This problem was resolved by strengthening the battery compartment and fitting rubber shock absorbers. In contrast to
Tempest, the modified survived a prolonged depth charge attack from Japanese escort vessels which rendered her hull a
constructive total loss but caused no damage to her battery cells.
Weaponry Torpedoes It was expected from British work on
ASDIC sonar that other nations would develop something similar for submarine detection. In the face of expected enemy
anti-submarine measures any submarine attack would probably have to be made at long range without the aid of the periscope, using only ASDIC. To counter the resulting inaccuracy, a large salvo of at least eight torpedoes would be needed. British operational planning at the time also assumed that international treaties would prevent unrestricted submarine warfare, so that the main purpose of the submarine would be to attack dangerous enemy warships, often giving a commander only one chance to attack, so a large salvo was essential. The ten-torpedo salvo of the pre-war T-class boats was the largest ever fitted to any operational submarine. All T-class submarines had six internal
torpedo tubes in the bow. These were fitted with bow shutters on early Group One boats to reduce underwater drag; the benefits proved to be minimal and the shutters were prone to jamming from flotsam, so the idea was dropped in favour of reshaping the torpedo tube orifices for minimal drag. After the loss of due to the unintentional opening of the rear door of a torpedo tube while its bow cap was open, a special safety clip known as the "Thetis clip" was introduced to prevent the rear torpedo tube door from being opened by more than a fraction if the bow cap was not in place. Each T-class boat carried six reload torpedoes for the internal tubes in the torpedo stowage compartment. Reloading was manual, although a power-loading system was experimented with on
Triumph in 1939 based on one developed on . This system proved to be underpowered, and the pressures of wartime production led to development being curtailed. The internal torpedo tubes were complemented by four forward-facing external ("E-type") 21-inch torpedo tubes on Group One T-class boats; external tubes were used to avoid compromising the structural integrity of the pressure hull with too many openings. These tubes could not be reloaded from within the submarine, and it was also not possible to conduct maintenance on or withdraw the torpedo once it was loaded into the external tube. These tubes were angled downwards at a 5° bow angle to ease operations, except on the lead boat
Triton. Two of these external tubes were located in the bow, and another two located amidships at the base of the
conning tower. Unlike the internal tubes, the bow caps for the external tubes had to be operated manually, requiring considerable effort. The tubes were also vulnerable to damage. Two of the T-class boats had their bow external tubes omitted during reconstruction:
Thunderbolt (ex-
Thetis) and
Triumph. Prior to the outbreak of war, there had been much debate over the introduction of stern torpedo tubes on British submarines. The effectiveness of a two-torpedo stern salvo was considered to be doubtful and these tubes would take up valuable space on the submarine. Experience soon led to complaints from British submarine commanders including Commander
Anthony Miers (
Torbay) about the lack of stern torpedo tubes. Consequently eight of the Group One boats,
Taku,
Thunderbolt,
Tigris,
Torbay,
Tribune,
Trident,
Truant, and
Tuna, were retrofitted with an eleventh external torpedo tube facing rearwards, which became standard on boats starting from Group. On Group Two boats, the amidships torpedo tubes were also moved aft of the conning tower and pointed rearwards. Initially these were angled at 10° off the centerline, but this created an area of flat casing that made maintaining depth difficult and for the last two Group Two boats,
Traveller and
Trooper, and all of the Group Three boats, the angle was reduced to 7°. The primary torpedo used by the T-class submarines was the 21-inch
Mark VIII torpedo, principally the Mark VIII** variant. This torpedo weighed with a
Torpex warhead and used a Brotherhood burner-cycle engine for a range of at or at . It had a greater propulsive efficiency than any contemporary torpedo of a similar size, but shortages of the Mark VIII early in the war led to some submarines using the older Mark IV. The Mark VIII was primarily fitted with a
contact pistol which detonated the torpedo upon impact. A non-contact
magnetic pistol known as the CCR (Compensated Coil Rod) was also developed and used during the war. Like the magnetic pistols developed by many other countries, the CCR gave endless trouble and was eventually withdrawn. Due to development problems with British postwar torpedoes, the Mark VIII remained the standard torpedo used by all Royal Navy submarines, including the T class, until the
Mark 23 wire-guided torpedo was introduced in 1971.
Deck guns All T-class submarines, as built, were fitted with one deck gun as a weapon of surprise and self-defence. This was either the
4-inch QF Mark XII or XXII (both interchangeable) on an S1 mounting. The mounting was located above the casing and forward of the conning tower, with a characteristic breastwork that rotated with the gun to provide room for the crew to operate the gun. No armour or overhead protection for the 4-inch gun crew was provided as built due to weight restrictions, except on
Tabard,
Talent, and
Teredo. Many other T-class boats received improvised
gun shields manufactured by
depot ships in the Far East, providing some degree of protection. The gun had a crew of five, and T-class submarines were initially supplied with 100 rounds of ammunition, which proved insufficient and was soon increased; by the end of the war, T boats would often carry more gun ammunition instead of reload torpedoes. The standard anti-aircraft armament carried by T-class submarines was three .303-inch machine guns. These were initially
Lewis guns, replaced from 1941 onwards by the better
Vickers gas-operated (VGO) machine gun. The Vickers was sometimes substituted by the
Bren gun if
the Army could spare supplies. Later, most T-class boats were retrofitted or completed with the ubiquitous
20 mm Oerlikon, located aft of the conning tower. Most T-class boats were fitted with only one, but
Tantivy carried two 20 mm cannon side by side on pedestal mountings, while
Tireless was completed with a twin Oerlikon Mark 12A mounting. The crew of
Terrapin was able to acquire a
.50 inch Browning air-cooled machine gun on their own initiative, but this weapon was had too powerful a recoil for the conning tower's structure, made of brass instead of steel to prevent interference with the magnetic compass, and was eventually dropped. ==Service history==