Hispano-Suiza 12Y
The Hispano-Suiza 12Y was an aircraft engine produced by Hispano-Suiza for the French Air Force before the Second World War. The 12Y became the primary French 1,000 hp (750 kW) class engine and was used in a number of famous aircraft, including the Morane-Saulnier M.S.406 and Dewoitine D.520.
12Y | |
---|---|
Type | V-12 piston aero engine |
National origin | France |
Manufacturer | Hispano-Suiza |
First run | 1932 |
Major applications | Dewoitine D.520 |
Developed from | Hispano-Suiza 12X |
Developed into | Hispano-Suiza 12Z |
Its design was based on the earlier and somewhat smaller, 12X. The 12X did not see widespread use before the 12Y replaced it and became one of the most powerful French designs on the eve of the war. The 12Z was being designed but this was ended by the fall of France and the German occupation.
The 12Y was produced under Hispano-Suiza licence in the Soviet Union as the Klimov M-100. This design led to the highly successful Klimov VK-105 series that powered the Yakovlev and Lavochkin fighters as well as the Petlyakov Pe-2 bomber. Licensed production of the early models was also undertaken in Czechoslovakia as the Avia HS 12Ydrs and in Switzerland as the HS-77.
Design and development
Early development
The 12Y was a fairly traditional in construction, a 36-litre water-cooled V-12 with the two cast aluminium cylinder banks set at 60 degrees to each other. The cylinder heads were not removable, instead both cylinder banks could be quickly removed from the crankcase section of the engine. This made it somewhat famous for being leak-proof, a design feature that was considered by other designers and almost became a part of the Rolls-Royce Merlin.
The major design change from the earlier 12X was to use a master-articulated connecting rod system, instead of the fork-and-blade type. A single overhead camshaft (SOHC) drove the valves, which were filled with liquid sodium for cooling. Only a single intake and exhaust valve were used, unlike most designs of the era which had moved to three or four valves per cylinder. A single-stage, single-speed supercharger was standard, although the art of designing a useful intake was not as well developed as in other countries, and high altitude performance was always lacking.
The first 12Y test articles were constructed in 1932, and almost immediately the entire French aviation industry began designing engines based on it. At the time the engine developed only 760 hp (570 kW), but it was clear it had potential to the 1,000 hp (750 kW) class. An early modification led to the Hispano-Suiza 12Ycrs which used a hollow propeller shaft to allow a 20 mm cannon to fire through the propeller spinner (a combination known as a moteur-canon). All later versions shared this feature. The 12Ydrs was the next major series, with a basic rating of 836 hp (623 kW) at sea level with a compression ratio of 5.8:1.
The Armée de l'Air changed their nomenclature, so the next version was the Hispano-Suiza 12Y-21, which increased the compression ratio to 7:1, when running on 100 octane gasoline. This boosted power to 867 hp (647 kW). In 1936 the connecting rod design was changed slightly to create the 12Y-31, but the lower 5.8:1 compression ratio was retained and the power was increased only slightly over the drs model to 850 hp (630 kW). Nevertheless, this became one of the most used engine designs of the pre-war era, used in almost all French fighter designs and prototypes.
Late variants
A real effort to improve the performance of the engine in 1938 resulted in the Hispano-Suiza 12Y-45, which used the S-39-H3 supercharger co-designed by André Planiol and Polish engineer Joseph Szydlowski. The Szydlowski-Planiol device was larger, but much more efficient than the indifferent Hispano-Suiza models. When used with 100 octane fuel, the supercharger boosted to the -21's 7:1, increasing power to 900 hp (670 kW). Combined with the Ratier constant-speed propeller, this allowed the D.520 to perform as well as contemporary designs from Germany and England.
Another improvement in supercharging led to the Hispano-Suiza 12Y-49, whose performance improved from 850 hp (630 kW) at sea level to 920 hp (690 kW) at just over 10,000 ft (3,000 m). This improvement in power with altitude was a common feature of most engines of the era, the result of the supercharger "robbing" power at low altitudes while not boosting the power due to the possibility of detonation.
The final major version was the 1,085 hp (809 kW) Hispano-Suiza 12Y-51, which had just started into production at the time of the Armistice with Germany. The -51 was the first version that came close to the performance limits of the engine, although the single-stage supercharging meant that it was unable to compete with designs from England and Germany above 15,000 ft (5,000 m).
Foreign derivatives
In the early 1930s the Czechoslovakian Republic gained rights to build a license version of the HS-12Y. This was produced by Avia (Škoda) at Prag - Čakovice. The engine was intended to become the standard powerplant of all Czech military aircraft. Both the HS-12Ycrs and HS-12Ydrs were built in quantity and were more commonly known by these names rather than any Czech designation. Aircraft powered by these engines included the Avia B-34, Avia B-534, Avia B-71, Avia B-35, Avia B-135 and Rogožarski IK-3 .
Switzerland license built and assembled several different versions of the basic 12Ycrs for use in several aircraft: the reconnaissance biplane the EKW C-35, the multipurpose EKW C-36, the Swiss assembled D-3800 copy of the French M.S. 406 fighter and Swiss built versions of the French M.S.412 fighter called the D.3801. Saurer developed the engine further after the Fall of France into the YS-2 and YS-3 engines. These were used in more powerful follow-on versions of the same basic French fighter design, the M.S.450 called the D.3802 and then the final version called the D.3803.
In the mid-1930s, Russian engineer Vladimir Klimov was sent to France to obtain a license for local production of the 12Y. A series of design changes were added to cope with cold weather operation, and the engine entered production in 1935 as the Klimov M-100 with about 750 hp (560 kW).[1] However a series of continual upgrades increased the allowable RPM from the 12Y's fairly low 2,400 to 2,700, thereby increasing power to 1,100 hp (820 kW). The resulting design, the Klimov M-105 (VK-105) became one of the major Soviet engine designs during the war, powering all Yakovlev fighters.
Variants
Tabulated data from Lage 2004[2]
Model | Year | Compression | Power (hp) | @ r.p.m. | T-O power (hp) | Output reduction | Supercharger optimum altitude (m) | Weight (kg) | Cannon (y/n) | Comments |
---|---|---|---|---|---|---|---|---|---|---|
12Ybr 650 hp | 1932 | 6.4 | 785 | 2,200 | 785 | 1.5 | 0 | 415 | n | Rated power (650 hp) less than nominal 785 hp |
12Ybrs | 1934 | 5.8 | 860 | 2,400 | 835 | 1.0625 | 4,000 | 470 | y | |
12Ycrs | 1934 | 5.8 | 860 | 2,400 | 835 | 0.67:1 | 4,000 | 470 | y | |
12Ygrs 650 hp | 1932 | 5.8 | 850 | 2,400 | 800 | 1.5 | 4,000 | 430 | n | Rated power (650 hp) less than nominal 850 hp |
12Ydr | 1934 | 6.4 | 800 | 2,200 | 800 | 1.5 | 0 | 440 | n | As 12Ybr, variable-pitch propeller, left turning. For this and all later entries in both tables, Rated power = Nominal power = Power |
12Ydrs | 1934 | 5.8 | 860 | 2,400 | 835 | 1.5 | 4,000 | 470 | n | As 12Ybrs, variable-pitch propeller, left turning |
12Ydrs1 | 1934 | 5.8 | 880 | 2,400 | 890 | 1.5 | 2,400 | 470 | n | Variable-pitch propeller, left turning |
12Ydrs2 | 1934 | 5.8 | 930 | 2,400 | 992 | 1.5 | 900 | 470 | n | Variable-pitch propeller, left turning |
12Yfrs | 1934 | 5.8 | 860 | 2,400 | 835 | 1.5 | 4,000 | 470 | n | As 12Ydrs, right turning |
12Yfrs1 | 1934 | 5.8 | 880 | 2,400 | 890 | 1.5 | 2,400 | 470 | n | As 12Ydrs1, right turning |
12Yfrs2 | 1934 | 5.8 | 930 | 2,400 | 992 | 1.5 | 900 | 470 | n | As 12Ydrs, right turning |
12Y-21 | 1935 | 7.0 | 910 | 2,400 | 880 | 1.5 | 3,600 | 470 | n | |
12Y-25 | 1935 | 5.8 | 860 | 2,400 | 943 | 1.5 | 3,600 | n | As 12Ydrs, variable ignition timing | |
12Y-26 | 1935 | 5.8 | 900 | 2,400 | 950 | 1.8 | 850 | 483 | opposite rotation to -27 | |
12Y-27 | 1935 | 5.8 | 900 | 2,400 | 950 | 1.8 | 850 | 483 | opposite rotation to -26 | |
12Y-28 | 7.2 | 920 | 2,400 | 910 | 0.67:1 | 3,600 | 475 | y | LH rotation | |
12Y-29 | 7.2 | 920 | 2,400 | 910 | 0.67:1 | 3,600 | 475 | y | Identical to -28 but RH rotation | |
12Y-30 | 1936 | 5.8 | 860 | 2,400 | 830 | 0.67:1 | 3,250 | 468 | y | Redesigned connecting rods,LH rotation |
12Y-31 | 1936 | 5.8 | 860 | 2,400 | 830 | 0.67:1 | 3,250 | 468 | y | Identical to -30 but RH rotation |
12Y-32 | 1936 | 5.8 | 960 | 2,400 | 955 | 0.67:1 | 2,300 | 468 | y | Redesigned connecting rods,LH rotation |
12Y-33 | 1936 | 5.8 | 960 | 2,400 | 955 | 0.67:1 | 2,300 | 468 | y | Identical to -32 but RH rotation |
12Y-36 | 1936 | 7.0 | 960 | 2,400 | 1,050 | 0.55:1 | 1,250 | 483 | y | LH rotation |
12Y-37 | 1936 | 7.0 | 960 | 2,400 | 1,050 | 0.55:1 | 1,250 | 483 | y | Identical to -36 but RH rotation |
12Y-38 | 1936 | 7.0 | 1000 | 2,400 | 1.5 | 3,400 | n | LH rotation | ||
12Y-39 | 1936 | 7.0 | 1000 | 2,400 | 1.5 | 3,400 | n | Identical to -38 but RH rotation | ||
12Y-41 | 1936 | 7.0 | 920 | 2,400 | 0.67:1 | 3,600 | 483 | y | ||
12Y-45 | 7.0 | 920 | 2,400 | 935 | 0.67:1 | 4,200 | y | Szydlowsky-Planiol (SP) supercharger | ||
12Y-47 | 1936 | 5.8 | 860 | 2,400 | 830 | 0.67:1 | 3,250 | 468 | y | |
12Y 49 | 7.0 | 910 | 2,400 | 910 | 0.67:1 | 5,250 | y | (SP) supercharger, variable ignition timing | ||
12Y-50 | 1939 | 7.0 | 1,000 | 2,500 | 1,100 | 0.67:1 | 3,260 | 492 | y | (SP) supercharger LH rotation |
12Y-51 | 1939 | 7.0 | 1,000 | 2,500 | 1,100 | 0.67:1 | 3,260 | 492 | y | Identical to -50 but RH rotation |
Model | Year | Compression | Power (hp) | @ r.p.m. | T-O power (hp) | Output reduction | Supercharger optimum altitude (m) | Weight (kg) | Cannon (y/n) | Comments |
Related
Licence built variants
- Czechoslovakia
- Avia HS 12Y
- USSR[3][4]
- Klimov VK-100
- Klimov VK-103 746 kW (1,000 hp)
- Klimov VK-103A 820 kW (1,100 hp) at 2,000 m (6,600 ft)
- Klimov VK-104
- Klimov VK-105P 820 kW (1,100 hp) at take-off
- Klimov VK-106 1,007 kW (1,350 hp) at take-off
- Klimov VK-107 1,342 kW (1,800 hp) at take-off
- Switzerland
- Hispano-Suiza HS-77
- 12 Ycrs
Users
- AEKKEA-RAAB R-29
- ANF Les Mureaux 110-119 series
- ANF Les Mureaux 113
- Aero A.104
- Amiot 110-S
- Amiot 143
- Amiot 354
- Amiot 370
- Arsenal VB 10
- Arsenal VG-33
- Arsenal-Delanne 10
- Avia 156
- Avia B-135
- Avia B-34
- Avia B-534
- Avia B.35
- Bernard 260
- Bernard 80 GR
- Bernard 82
- Bloch MB.170
- Bloch MB.177
- Bloch MB.200
- Bloch MB.210
- Blériot-SPAD S.510
- Bréguet 19
- Bréguet 270
- Bréguet 410
- Bréguet 482
- Bréguet 521 Bizerte
- CAMS 110
- CAMS 80
- Caproni Ca.335
- D.3800/01/02/03
- Dewoitine D.500
- Dewoitine D.510
- Dewoitine D.513
- Dewoitine D.520
- Dewoitine D.770
- Dornier Do 22
- EKW C-35
- EKW C-36
- Fairey Fantôme
- Fairey Fox
- Farman F.220
- Farman NC.223.3
- Farman NC.223.4
- Fauvel AV.29
- Ikarus IK-2
- Latham 47
- Latécoère 298
- Latécoère 300
- Latécoère 380
- Latécoère 521
- Lioré et Olivier LeO 25
- Lioré et Olivier LeO H-47
- Loire-Nieuport 161
- Loire-Nieuport LN.401
- Morane-Saulnier M.S.406
- Morane-Saulnier M.S.475
- Morane-Saulnier Vanneau
- Nieuport-Delage NiD-120
- Potez 230
- Potez 39
- Potez-CAMS 141
- Potez-CAMS 160
- Potez-CAMS 161
- Renard R-36
- Renard R.31
- Rogozarski IK-3
- Romano R.90
- SAB AB-80
- SNCAC NC.130
- SNCAC NC.150
- SNCAC NC.4-10
- SNCAO 200
- Wibault 360
- Wibault 366
Klimov powered
- Arkhangelsky Ar-2
- Bartini DAR
- Beriev MBR-7
- Bolkhovitinov S
- Lavochkin-Gorbunov-Goudkov LaGG-1
- Lavochkin-Gorbunov-Goudkov LaGG-3
- Mörkö-Morane
- Petlyakov Pe-2
- Petlyakov Pe-3
- Petlyakov Pe-8
- Polikarpov I-17
- Tupolev SB
- Yakovlev Yak-1
- Yakovlev Yak-2
- Yakovlev Yak-3
- Yakovlev Yak-4
- Yakovlev Yak-7
- Yakovlev Yak-9
- Yermolayev Yer-2
Specifications (12Ycrs)
Data from Le Dewoitine D.520[5][6]
General characteristics
- Type: Twelve-cylinder supercharged liquid-cooled 60° V12 engine
- Bore: 150 mm (5.906 in)
- Stroke: 170 mm (6.693 in)
- Displacement: 36.05 l (2,199.9 in³)
- Length: 1,722 mm (67.8 in)
- Width: 764 mm (30.08 in)
- Height: 935 mm (36.81 in)
- Dry weight: * 12Y-25:475 kg (1,047 lb)
- 12Y-45:515 kg (1,135 lb)
Components
- Valvetrain: One intake and one sodium-filled exhaust valve per cylinder actuated via a single overhead camshaft per bank.
- Supercharger: Gear-driven single-speed centrifugal type supercharger, 10.0:1 gear ratio
- Fuel system: Six Solex 56 S.V.C carburetors
- Fuel type: * Y-25/-29:85/100 octane rating gasoline
- Y-45/-49:92/100 octane rating gasoline
- Cooling system: Pressurised, Liquid-cooled: 600 litres/min.
- Reduction gear: Spur, 2:3
Performance
- Power output: * 12Y 25: 810 CV (600 kW) (800 hp) at 2,400 rpm for takeoff
- 920 CV (680 kW) (910 hp) at 2,520 rpm at 3,600 m (11,800 ft)
- 12Y 45: 850 CV (630 kW) (840 hp) at 2,400 rpm for takeoff
- 935 CV (688 kW) (922 hp) at 2,520 rpm at 4,200 m (13,800 ft)
- Specific power: 17.08 kW/l (0.38 hp/in³)
- Compression ratio: 12Y 25: 7.2-1 12Y 45: 7-1
- Specific fuel consumption: 328 g/(kW•h) (0.54 lb/(hp•h))
- Oil consumption: 11 g/(kW•h) (0.28 oz/(hp•h))
- Power-to-weight ratio: 1.32 kW/kg (0.8 hp/lb)
See also
Comparable engines
Related lists
References
Wikimedia Commons has media related to Hispano-Suiza 12Y. |
Notes
- Kotelnikov 2005, p. 136.
- Lage, 2004, pp.486–7
- Gunston 1989
- Lage, 2004, pp.258-260
- Danel and Cuny 1966, pp. 245-248.
- Hispano-Suiza 12Y-47 Retrieved: 1 October 2010.
Bibliography
- Danel, Raymond and Jean Cuny. Docavia n°4: le Dewoitine D.520 (in French). Paris: Editions Larivière, 1966.
- Kotelnikov, Vladimir. Russian Piston Aero Engines. Marlborough, Wiltshire. The Crowood Press Ltd. 2005. ISBN 1-86126-702-9.
- Hispano-Suiza 12Y-47 Retrieved: 1 October 2010.
- Wilkinson, Paul H. Aircraft Engines of the World 1945. Paul H. Wilkinson. New York. 1945 OCLC 766030348
- Gunston, Bill. World Encyclopedia of Aero engines fully revised second edition. Patrick Stephens Limited. Wellingborough. 1989. ISBN 1-85260-163-9
- Lage, Manual (2004). Hispano Suiza in Aeronautics. Warrendale, USA: SAE International. pp. 486–487. ISBN 0-7680-0997-9.