Supermarine Spitfire variants: specifications, performance and armament

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Spitfire
RoleFighter
Manufacturer Supermarine
Designer R. J. Mitchell
First flight5 March 1936
Introduction1938
Retired1955, RAF
Primary user Royal Air Force
Produced1938–1948
Number built20,351
Variants Seafire, Spiteful
K9795, the 9th production Mk I, with 19 Squadron. SpitI19a.jpg
K9795, the 9th production Mk I, with 19 Squadron.
Spitfire LF Mk Vb of 316 (Polish) "Warszawski" Squadron. This Spitfire has the "cropped" Merlin 45 series engine and the "clipped" wings. Spitty with clipped wings.jpg
Spitfire LF Mk Vb of 316 (Polish) "Warszawski" Squadron. This Spitfire has the "cropped" Merlin 45 series engine and the "clipped" wings.

The British Supermarine Spitfire was one of the most popular fighter aircraft of the Second World War. The basic airframe proved to be extremely adaptable, capable of taking far more powerful engines and far greater loads than its original role as a short-range interceptor had allowed for. This would lead to 24 marks of Spitfire, and many sub-variants within the marks, being produced throughout the Second World War and beyond, in continuing efforts to fulfill Royal Air Force requirements and successfully combat ever-improving enemy aircraft.

Contents

The Spitfire was also adopted for service on aircraft carriers of the Royal Navy; in this role they were renamed Supermarine Seafire. Although the first version of the Seafire, the Seafire Ib, was a straight adaptation of the Spitfire Vb, successive variants incorporated much needed strengthening of the basic structure of the airframe and equipment changes in order to survive the demanding maritime environment. As a result, the later Seafire variants were usually heavier and, in the case of the Seafire XV/XVII and F. 47 series, they were very different aircraft to their land-based counterparts.

It is notable that throughout the entire development process, which took place over twelve years, from 1935 through to 1948, there were no outstanding failures of the basic design: this is a real testament to the original genius of Reginald J. Mitchell, his successor Joseph Smith, and the design teams they led. [1] [ attribution needed ]

The Rolls-Royce Merlin and Griffon engines

A key factor which allowed the continued development of the Spitfire was the development of progressively more powerful and improved engines, starting with the Rolls-Royce Merlin and progressing to the bigger and more powerful Rolls-Royce Griffon. The evolution of high octane aviation fuels and improved supercharger designs enabled Rolls-Royce to extract increasing amounts of power from the same basic designs. For example, the Merlin II and III which powered the Spitfire I produced a maximum of 1,030 hp (770 kW) using the 87 octane aviation fuel which was generally available from 1938 through to 1941; from early 1940 increasing supplies of 100 octane fuel allowed the maximum power to be increased to 1,310 hp (977 kW) with an increased supercharger boost pressure, albeit for a maximum time limit of 5 minutes. [2] In 1944 100/150 grade fuels enabled the Merlin 66 to produce 1,860 hp (1,387 kW) at low altitudes in F.S gear.

Single stage superchargers

Depending on the supercharger fitted, engines were rated as low altitude (e.g.; Merlin 66, Griffon III), where the engine produced its maximum power below about 10,000 feet (3,000 m), medium altitude (Merlin 45), where the engine produced its maximum power up to about 20,000 feet (6,100 m), and high altitude (Merlin 70), where the engine produced its maximum power above about 25,000 feet (7,600 m). As a result, the prefixes which were used on most later Spitfire variants; LF, F, and HF; indicated whether the engines fitted were suited for low, medium or high altitude, respectively. The use of these prefixes did not change according to the wings, which could be fitted with "clipped" tips, reducing the wingspan to about 32 ft 6 in (9.9 m) (this could vary slightly), or the "pointed" tips which increased the wingspan to 40 ft 2 in (12.29 m).

Spitfire F Mk XIIs of 41 Sqn. The Griffon IIs or VIs used a single-stage supercharger generating maximum power at low altitudes. These aircraft have "clipped" wings optimised for low altitude use Supermarine Spitfire F Mk XIIs of 41 Sqn.jpg
Spitfire F Mk XIIs of 41 Sqn. The Griffon IIs or VIs used a single-stage supercharger generating maximum power at low altitudes. These aircraft have "clipped" wings optimised for low altitude use

The original Merlin and Griffon engine designs used single-stage superchargers. For engines equipped with a single-stage supercharger the air being forced through the supercharger air intake was compressed by the supercharger's impeller. In the case of the Merlin II/III, XII and 40 series as the air was being compressed it was mixed with fuel which was fed through an SU carburettor before being fed into the engine's cylinders. The Merlin III produced 1,030 hp (770 kW) at +6¼lb/in² (43 kPa) of "boost" (the "boost" is the pressure to which the air/fuel mixture is compressed before being fed to the cylinders). [3] The limitation of the single stage supercharger was that the maximum power dropped quickly as higher altitudes were reached; because air pressure and air density decreases with altitude the efficiency of a piston engine drops because of the reduction in the weight of air [nb 1] that can be drawn into the engine; for example the air density, at 30,000 feet (9,100 m) is 1/3 of that at sea level, thus only 1/3 of the amount of air can be drawn into the cylinder and only 1/3 of the fuel can be burnt.

A supercharger can be thought of either as artificially increasing the density of the air by compressing it – or as forcing more air than normal into the cylinder every time the piston moves down. [4]

Two-Stage, Two-Speed superchargers

The most fundamental change made to the later Merlin (60, 70, 80, and 100 series) and Griffon engines (60 and 80 series) was the incorporation of a two-stage, two-speed supercharger, which provided a considerable increase in power, especially at higher altitudes. Two-stage refers to the use of two impellers on a common driveshaft, constituting two superchargers in series. [nb 2] As air was drawn through the air intake, fuel was pumped into the airstream by the carburettor. [5] The first-stage impeller compressed the air-fuel mixture and this was then fed to the smaller second-stage impeller which further compressed the mixture.

The impellers were driven by a hydraulically operated two-speed gearbox. [6] At low to medium altitudes, the supercharger was in Moderate Supercharger or M.S. gear (this referred to the gearing and thus the speed, at which the impellers were operating). Once the aircraft reached and climbed through a set critical altitude, (20,000 feet (6,100 m) for the Merlin 61 and 70 series) the power would start to drop as the atmospheric pressure (the density of air) dropped. [7] As the critical altitude was passed a pressure-operated aneroid capsule operated the gearbox, which changed speed to Full Supercharger (F.S.) gear, which drove the impellers faster, thus compressing a greater volume of the air-fuel mixture. [8] [nb 3]

An intercooler was required to stop the compressed mixture from becoming too hot and either igniting before reaching the cylinders (pre-ignition knocking) or creating a condition known as knocking or detonation. The intercooler, which was separate from the engine cooling system, with its own supply of glycol and water coolant, was mounted in the induction system, between the outlet of the second-stage supercharger and behind the cylinder blocks. The hot air-fuel mixture from the supercharger was circulated though and around the coolant tubes and was then passed on to the main induction manifold, through which it was fed into the cylinders. The intercooler also circulated coolant through passages in the supercharger casing and between the impellers. [9] Finally, an extra radiator (mounted in the starboard radiator duct under the wing of the Spitfire) was used to dissipate the intercooler's excess charge heat. [9]

Spitfire Mk VIII. Merlin 63, 66, or 70 engine with a two-stage, two-speed supercharger. Spitfire VIII MT928.jpg
Spitfire Mk VIII. Merlin 63, 66, or 70 engine with a two-stage, two-speed supercharger.

With the two-stage, two-speed supercharger, two sets of power ratings can be quoted. As an example, the maximum power generated by the Merlin 61 was 1,565 hp (1,167 kW) at 12,250 feet (3,730 m) (critical altitude) at M.S. speed, using + 15 lb/in² "boost". [7] The F.S. gear required approximately 200 hp (149 kW) to drive it. As a result, the maximum power generated by the Merlin 61 in F.S. was 1,390 hp (1,036 kW) at 25,900 feet (7,900 m) using + 15 lb/in² of boost. [7] [10] The Merlin 66 used in the LF Mk IX produced slightly more power but because of the use of slightly different gear ratios driving smaller impellers, the critical altitude ratings of the supercharger stages were lower, 7,000 feet (2,100 m) and 18,000 feet (5,500 m) respectively. By contrast the Merlin 70, which was optimised for high-altitude flight, had critical altitudes of 14,000 feet (4,300 m) (M.S) and 25,400 feet (7,700 m) (F.S). [11] (Unlike the Merlin engines the Griffons used superchargers which were designed to achieve maximum performance over a wider altitude band; as such there were no Griffon engined LF or HF Spitfire variants.)

Carburettors

The original production variants of the Merlin used an SU manufactured carburettor in which the fuel flow was metered through a float. In most circumstances this proved to be sufficient but during the air battles over Dunkirk and during the Battle of Britain it was found that whenever the Merlin was subjected to negative "g" forces, such as a quick "bunt" into a dive, the engine would briefly lose power through petrol starvation. This was because the petrol in the float was being thrown away from the feed pipe to the supercharger. The fuel injected Daimler-Benz DB 601 engine gave the Bf 109 especially an advantage over the carburettor-equipped engine; no Spitfire could simply "bunt" and dive away from an opponent as the 109 could. [12] The remedy, invented by Beatrice "Tilly" Shilling, was to fit a metal diaphragm with a hole in it, across the float chambers. It partly cured the problem of fuel starvation in a dive. The device was commonly referred to as 'Miss Shilling's Orifice'.

The full remedy was to use the Bendix-Stromberg pressure carburettor, which allowed more precise metering of the amount of fuel used by the engine and prevented fuel starvation. This new carburettor was used from the Merlin 66 series and on all Griffon engines. In these engines the carburettor injected fuel at 5 psi through a nozzle direct into the supercharger and the compressed air-fuel mixture was then directed to the cylinders. The final development was the SU injection carburettor, that injected fuel into the supercharger using a fuel pump driven as a function of crankshaft speed and engine pressures; although this was fitted to the 100 series Merlins, which were not used in production Spitfires, it was used in the Griffon 60 and 80 series.

Spitfire F.24 of 80 Squadron. This was the final mark of Spitfire powered by a Griffon 85 driving a five bladed Rotol propeller. Spit f24.jpg
Spitfire F.24 of 80 Squadron. This was the final mark of Spitfire powered by a Griffon 85 driving a five bladed Rotol propeller.

Boost pressure measurements

The British measured boost pressure as lbs./sq.inch (or psi) above a nominal value of atmospheric pressure at sea level. A reading of +6 meant that the air/fuel mix was being compressed by a supercharger blower to 20.7 (rounded figure) psi before entering the engine; +25 meant that the air/fuel mix was being compressed to 39.7 psi – 14.7 psi atmospheric pressure added to the "boost" pressure of 25 psi.

Inches of Mercury (" Hg)Pounds of Boost [13]
80.9" of mercury=+25 lb boost
66.6" of mercury=+18 lb boost
60.5" of mercury=+15 lb boost
48.3" of mercury=+9 lb boost
42.2" of mercury=+6 lb boost

Ram jet assistance

In an attempt to boost the performance of the Spitfire Mk1 in May 1940, RAe scientists (including Hayne Constant) developed a 'propulsive duct'. This was in essence a simple ram jet, fed by petrol, utilising the Meredith effect. It was housed in a 48-by-30-by-15-inch (122 cm × 76 cm × 38 cm) deep duct mounted on the fuselage centre line and resembled a third radiator. Bench tests showed that the increase in speed was not significant and the device was not flight tested. In 1943 the idea was reconsidered as a counter to the threat of the V1. Aircraft such as the Hawker Tempest and Gloster Meteor were not widely available and the Spitfire would only be able to intercept in a diving attack. A. D. Baxter and C. W. R. Smith at Farnborough reviewed the 1940 work and concluded that it was practical but problems with drag and pressure loss were encountered and the V1 had been beaten before they were solved. [14]

Dimensions, performance and armament

Due to the many differences in production Spitfires, performance could vary widely, even between aircraft with the same Mark number. Factors such as weight, external fittings, airframe and engine condition, among others, influenced how an aircraft performed. For example, even relatively minor damage on the wing leading edges could drastically reduce top speed. The most reliable performance figures and weight measurements came from the tests carried out throughout the Second World War by the Aeroplane & Armament Experimental Establishment (A&AEE) based at Boscombe Down.

Early Merlin engines

Supermarine Spitfire- Merlin engine variants
Mk Ia (K9793-early production, de Havilland two speed propeller) [15] Mk IIa (P7280) [16] Mk Vb (W3134) [17] LF Mk Vb (W3228) [18] [nb 4] Mk VI (AB200) [19]
Wingspan36 ft 10 in (11.23 m)36 ft 10 in (11.23 m)36 ft 10 in (11.23 m)32 ft 10 in (10.01 m)40 ft 2 in (12.24 m)
Wing area242.1 ft2 (22.5 m2)242.1 ft2 (22.5 m2)242.1 ft2 (22.5 m2)231 ft2 (21.46 m2)248.5 ft2 (23.1 m2)
Length29 ft 11 in (9.12 m)29 ft 11 in (9.12 m)29 ft 11 in (9.12 m)29 ft 11 in (9.12 m)29 ft 11 in (9.12 m)
Height9 ft 10 in (3.02 m)9 ft 10 in (3.02 m)11 ft 5 in (3.48 m)11 ft 5 in (3.48 m)11 ft 5 in (3.48 m)
Empty weight4,306 lb (1,953 kg)4,541 lb (2,059 kg)4,963 lb (2,251 kg)4,963 lb (2,251 kg)
Loaded weight5,935 lb (2,692 kg)6,172 lb (2,799 kg)6,525 lb (3,071 kg)6,450 lb (2,925 kg)6,740 lb (3,057 kg)
Engine Rolls-Royce Merlin IIIRolls-Royce Merlin XIIRolls-Royce Merlin 45Rolls-Royce Merlin 50MRolls-Royce Merlin 47
Power1,030 hp (770 kW) at 16,000 ft (4,877 m) 87 Octane fuel, +6 lb/in² boost [nb 5] 1,135 hp (846 kW) at 12,250 ft (3,734 m) 100 Octane fuel, +9 pounds lb/in² boost1,470 hp (1,096 kW) at 11,000 ft (3,353 m)1,585 hp (1,181 kW) at 3,800 ft (1,158 m)1,415 hp (1,054 kW) at 14,000 ft (4,267 m)
Maximum speed 367 mph (582 km/h) at 18,600 ft (5,669 m)354 mph (570 km/h) at 17,550 ft (5,349 m)371 mph (597 km/h) at 20,000 ft (6,096 m)350.5 mph (564 km/h) at 5,900 ft (1,798 m)354 mph (570 km/h) at 17,400 ft (5,349 m)
Rate of climb 2,175 ft/min (11.0 m/s) at 9,700 ft (2,956 m)2,995 ft/min (15.3 m/s) at 10,000 ft (3,962 m)3,250 ft/min (16.5 m/s) at 15,000 ft (4,572 m)4,720 ft/min (24.0 m/s) at sea level2660 ft/min (13.5 m/s) at 28,000 ft (8,534 m)
Service ceiling [nb 6] 34,400 ft (10,485 m)37,600 ft (11,460 m)35,000 ft (10,668 m)35,700 ft (10,881 m)39,200 ft (11,948 m)
Wing loading 24.5 lb/ft2 (117 kg/m2)25.4 lb/ft2 (122 kg/m2)27.9 lb/ft2 (137 kg/m2)26.6 lb/ft2 (130 kg/m2)27.0 lb/ft2 (137 kg/m2)
Power/mass 0.17 hp/lb (0.28 kW/kg)0.18 hp/lb (0.30 kW/kg)0.22 hp/lb (0.36 kW/kg)0.21 hp/lb (0.35 kW/kg)0.21 hp/lb (0.35 kW/kg)
Combat range248 mi (400 km) on internal fuel248 mi (400 km) on internal fuel248 mi (400 km) on internal fuel248 mi (400 km) on internal fuel248 mi (400 km) on internal fuel
Ferry range1,135 mi (1,827 km)1,530 mi (2,462 km) with 170 Imp gal (204 US gal) drop tank
Armament
  • 8 × 0.303" Browning machine guns; 350 rpg
  • 2 × 20 mm (0.79 in) Hispano II cannon; 60 round drum
  • 4 × 0.303" Browning machine guns; 350 rpg
  • 2 × 250 lb (113 kg) or 1 × 500 lb (227 kg) bombs
  • 2 × 20 mm (0.79 in) Hispano II cannon; 60 round drum
  • 4 × 0.303" Browning machine guns; 350 rpg
  • 2 × 250 lb (113 kg) or 1 × 500 lb (227 kg) bombs
  • 2 × 20 mm (0.79 in) Hispano II cannon; 60 round drum
  • 4 × 0.303" Browning machine guns; 350 rpg

Late Merlin and Griffon

Supermarine Spitfire- Late Merlin and Griffon engine variants.
LF Mk IXe [21] Mk XII [22] Mk XIVe [23] F Mk 24 [24]
Wingspan32 ft 6 in (9.9 m)32 ft 6 in (9.9 m)36 ft 10 in (11.23 m)36 ft 11 in (11.25 m)
Wing area231 ft2 (21.46 m2)231 ft2 (21.46 m2)242.1 ft2 (22.5 m2)243.6 ft2 (23.6 m2)
Length31 ft 1 in (9.47 m)31 ft 7 in (9.62 m)32 ft 8 in (9.95 m)32 ft 11 in (10.03 m)
Height12 ft 8 in (3.86 m)12 ft 8 in (3.86 m)12 ft 9 in (3.89 m)13 ft 6 in (4.11 m)
Empty weight5,090 lb (2,309 kg)5,564 lb (2,524 kg)6,653 lb (3,034 kg)7,160 lb (3,247 kg)
Loaded weight7,400 lb (3,354 kg)7,415 lb (3,363 kg)8,574 lb (3,889 kg)9,900 lb (4,490 kg)
EngineRolls-Royce Merlin 66: 150 Octane fuel, +25 lb/in² boost. Rolls-Royce Griffon III or IV Rolls-Royce Griffon 65Rolls-Royce Griffon 85
Power1,720 hp (1,283 kW) at 11,000 ft (3,353 m)1,735 hp (1,293 kW) at 1,000 ft (300 m)2,050 hp (1,530 kW) at 9,800 ft (2,987 m)2,120 hp (1,771 kW) at 12,250 ft (3,734 m)
Maximum speed 404 mph (650 km/h) at 21,000 ft (6,400 m)397 mph (639 km/h) at 17,800 ft (5,425 m)449 mph (722 km/h) at 24,500 ft (7,468 m)454 mph (731 km/h) at 26,000 ft (7,802 m)
Rate of climb 4,745 ft/min (24.1 m/s) at 10,000 ft (3,048 m) [25] 3,760 ft/min (19.1 m/s) at 2,000 ft (609 m)4,700 ft/min (23.8 m/s) at 8,000 ft (2438 m)4,100 ft/min (21.0 m/s) at 17,000 ft (5,182 m)
Service ceiling 42,500 ft (12,954 m)39,000 ft (11,887 m)43,000 ft (13,560 m)43,000 ft (13,560 m)
Wing loading 30.6 lb/ft2 (149 kg/m2)32.0 lb/ft2 (155 kg/m2)35.0 lb/ft2 (171 kg/m2)40.6 lb/ft2 (198 kg/m2)
Power/mass 0.23 hp/lb (0.39 kW/kg)0.23 hp/lb (0.39 kW/kg)0.20 hp/lb (0.33 kW/kg)0.23 hp/lb (0.39 kW/kg)
Combat range248 mi (400 km) on internal fuel493 mi (793 km) on internal fuel460 mi (740 km) on internal fuel390 mi (627 km) on internal fuel
Ferry range980 mi (1,577 km)791 mi (1,272 km)855 mi (1,375 km)965 mi (1,553 km) 90 gal drop tank
Armament
  • 2 × 20 mm Hispano II cannon; 120 rpg
  • 2 × 0.50 in Browning M2 machine guns; 250 rpg or 4 x 0.303 ; 1400 rounds for the IXc
  • Up to 2 × 250 lb (110 kg) bombs (wing racks), plus 1 × 500 lb (230 kg) bomb (centre-section rack).
  • 2 × 20 mm Hispano II cannon; 120 rpg
  • 4 × .303 in Browning machine guns; 350 rpg
  • Up to 2 × 250 lb (110 kg) bombs (wing racks), plus 1 × 500 lb (230 kg) bomb (centre-section rack).
  • 2 × 20 mm Hispano II cannon; 120 rpg
  • 2 × 0.50 in Browning M2 machine guns; 250 rpg
  • 4 × 20 mm Hispano V cannon; 175 rpg inboard, 150 rpg outboard
  • Up to 2 × 250 lb (110 kg) bombs (wing racks), plus 1 × 500 lb (230 kg) bomb (centre-section rack).

Seafire

Supermarine Seafire
Seafire Mk IIc [26] [27] Seafire L Mk III [28] [29] Seafire F Mk XV [30] [31] Seafire F Mk 47 [32] [33]
Wingspan36 ft 10 in (11.23 m)32 ft 2 in (9.8 m)/

13 ft 4 in (4.0 m) (wings folded)

36 ft 10 in (11.23 m)/

13 ft 4 in (4.0 m) (wings folded)

36 ft 11 in (11.25 m)/

19 ft 1 in (5.82 m) (wings folded)

Wing area242.1 ft2 (22.5 m2)231 ft2 (21.5 m2)242.1 ft2 (22.5 m2)243.6 ft2 (23.6 m2)
Length29 ft 11 in (9.12 m)29 ft 11 in (9.12 m)31 ft 10 in (9.70 m)/

32 ft 3 in (9.83 m)(late production larger fin and rudder)

34 ft 4 in (10.46 m)
Height (Over propeller, tail down)11 ft 5 in (3.48 m)11 ft 5 in (3.48 m)12 ft 8 in (3.86 m)12 ft 9 in (3.88 m)
Empty weight5,300 lb (2,404 kg)5,450 lb (2,472 kg)6,300 lb (2,857 kg)8,680 lb (3,937 kg)
Loaded weight7,145 lb (3,240 kg)7,220 lb (3,275 kg)7,995 lb (3,626 kg)10,700 lb (4,853 kg) loaded, clean;

12,530 lb (5,683 kg) with 50 gal drop tank and two 500 lb (230 kg) bombs

EngineRolls-Royce Merlin 46Rolls-Royce Merlin 55MRolls-Royce Griffon VIRolls-Royce Griffon 88
Power1,415 hp (1,055 kW) at 14,000 ft (4,267 m)1,585 hp (1,182 kW) at 2,750 ft (838 m)1,850 hp (1,379 kW) at 2,000 ft (609 m)2,350 hp (1,752 kW) at 1,250 ft (380 m)
Maximum speed 345 mph (299.7 knots), (555 km/h) at 19,000 ft (5,791 m)359 mph (312 knots), (578 km/h) at 5,100 ft (1,514 m)392 mph (341 knots), (631 km/h) at 12,800 ft (3,901 m)452 mph (393 knots), (727 km/h) at 20,500 ft (6,250 m)
Rate of climb 2,380 ft/min (12.0 m/s) at 16,000 ft (4,876 m)3,460 ft/min (17.5 m/s) at 4,000 ft (1,219 m)4,600 ft/min (23.4 m/s) at 4,000 ft (1,219 m)4,800 ft/min (24.4 m/s) at sea level (0 m)
Service ceiling 37,600 ft (11,460 m)32,000 ft (9,753 m)37,000 ft (11,277 m)43,100 ft (13,135 m)
Wing loading 29.5 lb/ft2 (133 kg/m2)30.3 lb/ft2 (137 kg/m2)33.0 lb/ft2 (161 kg/m2)43.9 lb/ft2 (205 kg/m2)

or 51.4 lb/ft2 (240 kg/m2)

Power/mass 0.20 hp/lb (0.33 kW/kg)0.22 hp/lb (0.36 kW/kg)0.23 hp/lb (0.39 kW/kg)0.22 hp/lb (0.36 kW/kg)

0.18 hp/lb (0.30 kW/kg)

Combat range434 mi (698 km) on internal fuel510 mi (821 km) on internal fuel376 mi (605 km) on internal fuel405 mi (652 km) on internal fuel
Ferry range750 mi (1,207 km) with 60 gal drop tank770 mi (1,239 km) with 60 gal drop tank903 mi (1,453 km) with 90 gal drop tank1,475 mi (2,374 km) with 90 gal drop tank
Armament
  • 2 × 20 mm Hispano II cannon; 120 rpg
  • 4 × .303 in Browning machine guns; 350 rpg
  • 2 × 250 lb (110 kg) with 1 × 500 lb (230 kg) bomb
  • 2 × 20 mm Hispano II: late Seafire IIIs Hispano V cannon; 120 rpg
  • 4 × .303 in Browning machine guns; 350 rpg
  • 2 × 250 lb (110 kg) with 1 × 500 lb (230 kg) bomb
  • 2 × 20 mm Hispano II cannon; 120 rpg
  • 4 × .303 in Browning machine guns; 350 rpg
  • 2 × 250 lb (110 kg) with 1 × 500 lb (230 kg) bomb
  • 4 × 20 mm Hispano V cannon; 175 rpg inboard, 150 rpg outboard
  • up to 8 × "60 lb" RP-3 rockets on zero-length launchers
  • up to 3 × 500 lb (230 kg) bombs

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<span class="mw-page-title-main">Supermarine Spitfire (late Merlin-powered variants)</span> Late Merlin-powered variants of the Supermarine Spitfire

The British Supermarine Spitfire was facing several challenges by mid-1942. The debut of the formidable Focke-Wulf Fw 190 in late 1941 had caused problems for RAF fighter squadrons flying the latest Spitfire Mk Vb. Rolls-Royce engineers were already working on a new version of the Merlin incorporating a two-stage supercharger; the combination of the improved Merlin and the Spitfire Mk Vc airframe in a "stop-gap" design allowed the RAF to combat the Fw 190 on equal terms.

<span class="mw-page-title-main">Packard V-1650 Merlin</span> Piston aircraft engine

The Packard V-1650 Merlin is a version of the Rolls-Royce Merlin aircraft engine, produced under license in the United States by the Packard Motor Car Company. The engine was licensed to expand production of the Rolls-Royce Merlin for British use. The engine also filled a gap in the U.S. at a time when similarly powered American-made engines were not available.

<span class="mw-page-title-main">Rolls-Royce Griffon</span> 1930s British piston aircraft engine

The Rolls-Royce Griffon is a British 37-litre capacity, 60-degree V-12, liquid-cooled aero engine designed and built by Rolls-Royce Limited. In keeping with company convention, the Griffon was named after a bird of prey, in this case the griffon vulture.

<span class="mw-page-title-main">Supermarine Spiteful</span> 1944 British fighter aircraft

The Supermarine Spiteful was a British Rolls-Royce Griffon–engined fighter aircraft designed by Supermarine to Air Ministry specification F.1/43 during the Second World War as a successor to the Spitfire. It had a new wing design to improve its critical Mach number, and allow safe operations at higher speeds. The new design also had a modern inwards-retracting undercarriage. Other changes included a larger fin to improve the somewhat marginal stability of Griffon Spitfires and changes to the mounting of the engine to tilt it down slightly for better visibility over the nose.

<span class="mw-page-title-main">Rolls-Royce Peregrine</span> 1930s British aircraft piston engine

The Rolls-Royce Peregrine was a 21-litre (1,300 cu in), 885-horsepower (660 kW) liquid-cooled V-12 aero engine designed and built by the British manufacturer Rolls-Royce in the late 1930s. It was essentially the ultimate development of the company's Kestrel engine, which had seen widespread use in military aircraft of the pre-war period.

<span class="mw-page-title-main">Rolls-Royce R</span> 1929 British aero engine

The Rolls-Royce R is a British aero engine that was designed and built specifically for air racing purposes by Rolls-Royce Limited. Nineteen R engines were assembled in a limited production run between 1929 and 1931. Developed from the Rolls-Royce Buzzard, it was a 37-litre capacity, supercharged V-12 capable of producing just under 2,800 horsepower (2,090 kW), and weighed 1,640 pounds (770 kg). Intensive factory testing revealed mechanical failures which were remedied by redesigning the components, greatly improving reliability.

<span class="mw-page-title-main">Rolls-Royce Eagle (1944)</span>

The Rolls-Royce Eagle Mk XXII is a British 24-cylinder, sleeve valve, H-block aero engine of 46 litre displacement. It was designed and built in the early-1940s by Rolls-Royce Limited and first ran in 1944. It was liquid-cooled, of flat H configuration with two crankshafts and was capable of 3,200 horsepower at 18 psi boost.

<span class="mw-page-title-main">Rolls-Royce Crecy</span> 1940s British piston aircraft engine

The Rolls-Royce Crecy was a British experimental two-stroke, 90-degree, V12, liquid-cooled aero-engine of 1,593.4 cu.in capacity, featuring sleeve valves and direct petrol injection. Initially intended for a high-speed "sprint" interceptor fighter, the Crecy was later seen as an economical high-altitude long-range powerplant. Developed between 1941 and 1946, it was among the most advanced two-stroke aero-engines ever built. The engine never reached flight trials and the project was cancelled in December 1945, overtaken by the progress of jet engine development.

<span class="mw-page-title-main">Klimov VK-107</span> 1940s Soviet piston aircraft engine

The Klimov VK-107 was a V-12 liquid-cooled piston aircraft engine used by Soviet aircraft during World War II.

<span class="mw-page-title-main">Supermarine Seafang</span> 1940s British fighter aircraft

The Supermarine Seafang was a British Rolls-Royce Griffon–engined fighter aircraft designed by Supermarine to Air Ministry specification N.5/45. It was based on the Spiteful, which was a development of Supermarine's famous Spitfire aircraft. By that time the Spitfire was a 10-year-old design in a period of rapid technical development in aviation. The Seafang was outmoded by jet aircraft, and only 18 were built.

<span class="mw-page-title-main">Supercharger</span> Air compressor for an internal combustion engine

In an internal combustion engine, a supercharger compresses the intake gas, forcing more air into the engine in order to produce more power for a given displacement.

The Hawker Hurricane was a British single-seat fighter aircraft designed and predominantly built by Hawker Aircraft. Some versions were built in Canada by Canadian Car and Foundry.

<span class="mw-page-title-main">Supermarine Spitfire (early Merlin-powered variants)</span> Early variants of the Supermarine Spitfire

Supermarine Spitfire variants powered by early model Rolls-Royce Merlin engines mostly utilised single-speed, single-stage superchargers. The British Supermarine Spitfire was the only Allied fighter aircraft of the Second World War to fight in front line service from the beginnings of the conflict, in September 1939, through to the end in August 1945. Post-war, the Spitfire's service career continued into the 1950s. The basic airframe proved to be extremely adaptable, capable of taking far more powerful engines and far greater loads than its original role as a short-range interceptor had called for. This would lead to 19 marks of Spitfire and 52 sub-variants being produced throughout the Second World War, and beyond. The many changes were made in order to fulfil Royal Air Force requirements and to successfully engage in combat with ever-improving enemy aircraft. With the death of the original designer, Reginald J. Mitchell, in June 1937, all variants of the Spitfire were designed by his successor, Joseph Smith, and a team of engineers and draftsmen.

<span class="mw-page-title-main">North American P-51 Mustang variants</span>

Over twenty variants of the North American P-51 Mustang fighter were produced from 1940, when it first flew, to after World War II, some of which were employed also in the Korean War and in several other conflicts.

<span class="mw-page-title-main">Supermarine Spitfire (Griffon-powered variants)</span> Griffon-powered variants of the Supermarine Spitfire

The Rolls-Royce Griffon engine was designed in answer to Royal Navy specifications for an engine capable of generating good power at low altitudes. Concepts for adapting the Spitfire to take the new engine had begun as far back as October 1939; Joseph Smith felt that "The good big 'un will eventually beat the good little 'un." and Ernest Hives of Rolls-Royce thought that the Griffon would be "a second power string for the Spitfire". The first of the Griffon-engined Spitfires flew on 27 November 1941.

<span class="mw-page-title-main">Supermarine Spitfire</span> British single-seat WWII fighter aircraft

The Supermarine Spitfire is a British single-seat fighter aircraft used by the Royal Air Force and other Allied countries before, during, and after World War II. Many variants of the Spitfire were built, from the Mk 1 to the Rolls-Royce Griffon-engined Mk 24 using several wing configurations and guns. It was the only British fighter produced continuously throughout the war. The Spitfire remains popular among enthusiasts; around 70 remain airworthy, and many more are static exhibits in aviation museums throughout the world.

References

Footnotes

  1. The air at higher altitudes weighs less per cubic centimetre than it does at sea-level.
  2. Impellers were often referred to as "rotors".
  3. The second stage starting was often accompanied by a noticeable jolt, which inexperienced pilots often mistook for some type of engine malfunction.
  4. W3228 was tested with normal span wings. Most LF Mk Vbs used "clipped" wings
  5. Using 100 Octane fuel and +12 lb/in² boost the Merlin III was capable of generating 1,310 hp (977 kW). Harvey-Bailey 1995, p. 155. This overboost condition was sustainable for five minutes and was in use from March 1940. This boosted the maximum speed by 25 mph (40 km/h) at sea level and 34 mph (55 km/h) at 10,000 ft (3,000 m) and improved the climbing performance between sea level and full throttle height. Price 1996, p. 19..
  6. Note:The Service Ceiling in these reports denotes the altitude at which the rate of climb is reduced to 100 ft/min.

Citations

  1. McKinstry 2007, p. 25.
  2. Harvey-Bailey 1995, p. 155.
  3. Price 1999, p. 81.
  4. Smallwood 1995, p. 133.
  5. Smith 1942, p. 657.
  6. Smith 1942, p. 656.
  7. 1 2 3 Price 1995, p.14
  8. Flight 1945, pp. 315–316.
  9. 1 2 Smith 1942, pp. 657–658.
  10. Smallwood 1995, pp.132–136.
  11. Price 1999, p. 170.
  12. McKinstry 2007, p. 205.
  13. Lowrey 1943, p. 619
  14. Gibson & Buttler 2007, pp. 135–136.
  15. Price 1999, p.81
  16. Price 1999, p.114
  17. Price 1999, p.142
  18. Price 2010, p. 168.
  19. Price 1999, p.150
  20. Note: Rounds Per Gun.
  21. Morgan and Shacklady 2000, p.332
  22. Price 2010, p. 219.
  23. Morgan and Shacklady 2000, p.420
  24. Morgan and Shacklady 2000, p.490
  25. Price 2010, p. 196.
  26. Brown 1989, p. 168.
  27. Seafire IIc performance
  28. Robertson 1973, pp.194–196
  29. Morgan and Shacklady 2000, pp.534–543.
  30. Robertson 1973, pp.196–197.
  31. Morgan and Shacklady 2000, pp.551–560.
  32. Seafire Mk 47 Trials report Retrieved: 27 July 2008
  33. "Spitfires with Sea Legs; part 2". Air International Vol 15 No 4, October 1978 pp.185–187.

Bibliography

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