check out what i found about our engines
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check out what i found about our engines
http://www.answers.com/topic/mazda-wankel-engine
i found this page about our engines when i was looking for a cosmo eunos for me when i end up getting shipped to japan.
Mazda Wankel "rotary" engines
Mazda Wankel engine in the Deutsches Museum
Manufacturer Mazda
Production 1963 present
All Mazda Wankel "rotary" engines are essentially a single family they all derive from the first Wankel experiments in the early 1960s. Over the years, displacement has been increased (somewhat), and turbocharging has been added to great effect. This is the engine family that made Mazda famous.
In auto racing, the displacement of a Wankel engine is usually doubled for classing purposes. For Japanese tax purposes, the displacement of Wankel engines is defined as the equivalent of 1.5 times the nominal displacement. So the 1.3 L 13B engines count as just under 2.0 L for these purposes.
Wankel engines can be classified by their rotor size in terms of width (diameter) and depth (thickness). These metrics function similarly to the bore and stroke measurements of a piston engine. Nearly all Mazda production Wankel engines share a single rotor diameter: 105 mm (4.1 in) with a 15 mm (0.6 in) crankshaft offset. The only engine to diverge from this formula was the rare 13A, which used a 120 mm (4.7 in) diameter and 17.5 mm (0.7 in) offset.
40A
Mazda's first prototype Wankel was the 40A, a single-rotor engine very much like the NSU KKM400. Although never produced in volume, the 40A was a valuable testbed for Mazda engineers, and quickly demonstrated two serious challenges to the feasibility of the design: "chatter marks" in the housing, and heavy oil consumption. The chatter marks, nicknamed "devil's fingernails", were caused by improper sealing at the apex of the rotor. The oil consumption problem was addressed with heat-resistant rubber oil seals at the sides of the rotors. This early engine had a rotor diameter of 90 mm (3.5 in), an offset of 14 mm (0.6 in), and a depth of 59 mm (2.3 in).
L8A
The very first Mazda Cosmo prototype used a 798 cc L8A two-rotor Wankel. The engine and car were both shown at the 1963 Tokyo Motor Show. Hollow cast iron apex seals reduced vibration and thus chatter marks. It used dry-sump lubrication. Rotor diameter was up from the 40A to 98 mm (3.9 in), but depth dropped to 56 mm (2.2 in).
One-, three-, and four-rotor derivatives of the L8A were also created for experimentation.
10A
The 10A series was Mazda's first production Wankel, appearing in 1965. It was a two-rotor design, with each displacing 491 cc for a total of 982 cc. These engine featured the mainstream rotor dimensions with a 60 mm (2.4 in) depth.
The rotor housing was made of sand-cast aluminum plated with chrome, while the aluminum sides were sprayed with molten carbon steel for strength. Cast iron was used for the rotors themselves, and their eccentric shafts were of expensive chrome-molybdenum steel. The addition of aluminum/carbon apex seals addressed the chatter mark problem.
0810
The first 10A engine was the 0810, used in the Series I Cosmo from May, 1965 through July, 1968. These cars, and their revolutionary engine, were often called L10A models. Gross output was 110 hp (82 kW) at 7000 RPM and 130 Nm (96 ft.lbf) at 3500 RPM, but both numbers were probably optimistic.
The 10A featured twin side intake ports per rotor, each fed by a one of four carburetor barrels. Only one port per rotor was used under low loads for added fuel economy. A single peripheral exhaust port routed hot gas through the coolest parts of the housing, and engine coolant flowed axially rather than the radial flow used by NSU. A bit of oil was mixed with the intake charge for lubrication.
The 0810 was modified for the racing Cosmos used at Nόrburgring. These engines had both side- and peripheral-located intake ports switched with a butterfly valve for low- and high-RPM use (respectively)
Applications:
* 19651968 Mazda Cosmo Series I/L10A
0813
The improved 0813 engine appeared in July, 1968 in the Series II/L10B Cosmo. Its construction was very similar to the 0810, but the ports and carburetion were revised to produce 128 hp (96 kW) at 7000 RPM and 140 Nm (103 ft.lbf) at 5000 RPM. Again, these were Japanese net output figures.
Applications:
* 19681972 Mazda Cosmo Series II/L10B
0820
The 10A was substantially revised for wide-scale production in the R100/Familia Rotary. Many changes were made in an effort to reduce production costs. These included the use of cast iron in the housing sides, less-expensive molded (instead of sand-cast) aluminum for the housings, and chrome-steel for the eccentric shafts. The port arrangement remained the same, but exhaust was no longer routed around the housing.
Japanese-spec gross output was 100 hp (75 kW) at 7000 RPM and 98 ft.lbf (133 Nm) at 3500 RPM. The use of less-expensive components raised the weight of the engine from 224 lb (102 kg) to 268 lb (122 kg).
Applications:
* 19681973 Mazda R100/Familia Rotary
0866
The final member of the 10A family was the 1971 0866. This variant featured a cast-iron thermal reactor to reduce exhaust emissions and re-tuned exhaust ports. The die-cast rotor housing was now coated with a new process: The new Transplant Coating Process (TCP) featured sprayed-on steel which is then coated with chrome. Gross output was 105 hp (78 kW) at 7000 RPM and 135 Nm (99.5 ft.lbf) at 3500 RPM.
Applications:
* 19721974 Mazda RX-3 (Japan-spec)
13A
The 13A was designed especially for front wheel drive applications. It had two 655 cc rotors for a total of 1310 cc. This was the only production Mazda Wankel with different rotor dimensions: Diameter was 120 mm (4.7 in) and offset was 17.5 mm (0.7 in), but depth remained the same as the 10A at 60 mm (2.4 in). Another major difference from the previous engines was the integrated water-cooled oil cooler.
The 13A was used only in the 19691972 R130 Luce, where it produced 126 hp (94 kW) and 126 ft.lbf (172 Nm). This was the end of the line for this engine design: The next Luce was rear wheel drive and Mazda never again made a front wheel drive rotary vehicle.
Applications:
* 19701972 Mazda R130
12A
The 12A was a "bored-out" version of the 10A the rotor diameter was the same, but the depth was increased by 10 mm (0.4 in) to 70 mm (2.8 in). Each of its two rotors displaced 573 cc for a total of 1146 cc. The 12A series was produced for 15 years, from May 1970 through 1985. In 1974, a 12A became the first engine built outside of western Europe or the U.S to finish the 24 hours of Le Mans.
In 1974, a new process was used to harden the rotor housing. The Sheet-metal Insert Process (SIP) used a sheet of steel much like a conventional piston engine cylinder liner with a chrome plated surface. The side housing coating was also changed to eliminate the troublesome sprayed metal. The new "REST" process created such a strong housing, the old carbon seals could be abandoned in favor of conventional cast iron.
Early 12A engines also feature a thermal reactor, similar to the 0866 10A, and some use an exhaust port insert to reduce exhaust noise. A lean-burn version was introduced in 1979 (in Japan) and 1980 (in America) which substituted a more-conventional catalytic converter for this "afterburner". A major modification of the 12A architecture was the 6PI which featured variable induction ports.
Applications:
* 19701972 Mazda R100
* 19701974 Mazda RX-2, 130 hp (97 kW) and 115 ft.lbf (156 Nm)
* 19721974 Mazda RX-3 (Japan), 110 hp (82 kW) and 100 ft.lbf (135 Nm)
* 19721974 Mazda RX-4
* 19721980 Mazda Luce
* 19781979 Mazda RX-7, 100 hp (75 kW)
* Lean-burn
o 19791985 Mazda RX-7 (Japan)
o 19801985 Mazda RX-7 (USA)
* 6PI
o 19811985 Mazda Luce
o 19811985 Mazda Cosmo
Turbo
The ultimate 12A engine was the turbocharged and fuel injected engine used in the Japan-spec HB series Cosmo, Luce, and SA series RX-7. In 1982 a 12A turbo powered Cosmo coupe was officially the fastest production car in Japan. It featured "semi-direct injection" into both rotors at once, a technique that was much more successful than it would appear. A passive knock sensor was used to eliminate detonation, and later models featured a specially-designed "impact turbo" which was tweaked for the unique exhaust signature of the Wankel engine. The engine continued until 1989 in the HB Cosmo series but by that stage it had grown a reputation as a thirsty engine.
Output was 165 hp (123 kW) at 6000 RPM and 186 Nm (137 ft.lbf) at 4000 RPM.
Applications:
* 19821989 Mazda Cosmo
* 19821985 Mazda Luce
* 19841985 Mazda RX-7
12B
The improved 12B was quietly introduced in 1974. In the US it was the start of the single distributors engines.
NOTE: the previous 12A & 10A engines used the twin distributors.
Applications:
* 19741978 Mazda RX-2
* 19741978 Mazda RX-3
13B
The 13B is the most widely produced engine. It was the basis for all future Mazda Wankel engines, and was produced for almost 30 years. The 13B is no relation to the 13A. Instead, it is a lengthened version of the 12A, having 80 mm (3.1 in) thick rotors. It had the largest displacement yet at 654 cc, for a total of 1308 cc.
In the United States, the 13B was available from 1974 through 1978 and was then retired until the 1984 RX-7 GSL-SE. It was retired again in 2002 with the cancellation of the RX-7. The engine was continually used in Japan from 1972's Mazda Luce/RX-4 through 2002's RX-7.
AP
The 13B was designed with both high performance and low emissions in mind. Early vehicles using this engine used the AP name, which signified these two characteristics.
Applications:
* 19721980 Mazda Cosmo AP
* 19741977 Mazda Rotary Pickup
* 19751977 Mazda Roadpacer
* 19741978 Mazda RX-4
* 19751980 RX-5
13B-RESI
A tuned intake manifold was used in a Wankel engine for the first time with the 13B-RESI ("Rotary Engine Super Injection"). The so-called Dynamic Effect Intake featured a two-level intake box which derived a supercharger-like effect from the Helmholtz resonance of the opening and closing intake ports. The RESI engine also featured Bosch L-Jetronic fuel injection. Output was much improved at 135 hp (101 kW) and 133 ft·lbf (180 N·m).
Applications:
* 19841985 Mazda HB Luce
* 19841985 Mazda HB Cosmo
* 19841985 Mazda FB RX-7 GSL-SE
13B-DEI
Like the 12A-SIP, the second-generation RX-7 bowed with a variable-intake system. Dubbed DEI, the engine features both the 6PI and DEI systems, as well as four-injector electronic fuel injection. Total output is up to 146 hp (109 kW) at 6500 rpm and 138 ft·lbf (187 N·m) at 3500 rpm.
Applications:
* 19861988 Mazda RX-7, 146 hp (108 kW)
* 19891991 Mazda RX-7, 160 hp (119 kW)
13B-Turbo
The 13B-DEI was turbocharged in 1987. It features the newer four-injector fuel injection of the 6PI engine, but lacks that engine's eponymous variable intake system. The twin-scroll turbocharger is fed with a two-stage valve to reduce turbo lag. Output is way up at 185 hp (138 kW) at 6500 rpm and 183 ft·lbf (248 N·m) at 3500 rpm.
Applications:
* 19861991 Mazda HC Luce Turbo-II, 185 hp (138 kW)
* 19871988 Mazda FC RX-7 Turbo-II, 185 hp (138 kW)
* 19891991 Mazda FC RX-7 Turbo-II, 200 hp (147 kW)
13B-REW
A twin-turbocharged version of the 13B, the 13B-REW, became famous for its high output and low weight. The twin Hitachi HT-12 turbos were operated sequentially, with the primary providing boost until 4,500 RPM, and the secondary coming online afterwards. Output eventually reached, and may have exceeded, Japan's "maximum" of 280 hp (208 kW) for the final revision used in the series 8 Mazda RX-7.
Applications:
* 19901995 Eunos Cosmo, 235 hp (176 kW)
* 19921995 Mazda RX-7, 255 hp (190 kW)
* 19961998 Mazda RX-7, 265 hp (197 kW)
* 19992002 Mazda RX-7, 280 hp (208 kW)
20B
Eunos Cosmo engine at the Mazda Museum
Enlarge
Eunos Cosmo engine at the Mazda Museum
Rotary Engine 20B
Enlarge
Rotary Engine 20B
In Le Mans racing, the first three-rotor engine used in the 757 was named the 13G.
The main difference between the 13G and 20B is that the 13G uses a factory peripheral intake port(used for racing) and the 20B uses side intake ports.
It was renamed 20B after Mazda's naming convention for the 767 in November of 1987.
The three-rotor 20B-REW was only used in the 1990-1995 Eunos Cosmo. It was the world's first volume production twin-turbo setup featured in both 13B-REW & 20B-REW form. It displaced 1962 cc (three 654 cc rotors) and used 0.7 bar (around 10psi)of turbo pressure to produce 300 hp (224 kW) and 300 ft.lbf (402 Nm). It was at the time the highest torque output engine of any Japanese vehicle manufacturer.
26J
The first Mazda four-rotor engine was the 26J used in the 1988 767 Le Mans prototypes. This motor was poorly designed, and was replaced by the 26B.
R26B
The most prominent 4-rotor engine from Mazda was used exclusively for various Mazda-built GT cars (including the 767 and 787B) in replacement of the older 13J. In 1991 this engine in a 787B became the first from outside the U.S. or Western Europe and the first (and so far only) car with a rotary engine to win outright the 24 hours of Le Mans race. It displaced 2622 cc and built 700 hp (522 kW) at 9000RPM. The engine design originates as a single 13B with: an additional rotor and housing added at each end, continually variable geometry intakes, and an additional (third) spark plug. The R26B's engine block can be purchased at retail from Mazdaspeed, but no internal parts are available to the general public.
13B-MSP RENESIS
Mazda RENESIS prototype in the Mazda Museum
Enlarge
Mazda RENESIS prototype in the Mazda Museum
The RENESIS engine also 13B-MSP, for Multi Side Port , which first appeared in production in the 2003 Mazda RX-8, is an evolution of the previous 13B. It was designed to reduce exhaust emission and improve fuel economy, which were two of the most recurrent drawbacks of rotary engines. Unlike its predecessors from the 13B range, it is naturally aspirated, leading to lower power from its two versions (212 and 232hp) compared to the Mazda RX-7's twin-turbocharged 13B-REW (280hp).
The engine entailed two major changes. First, the exhausts ports are no longer peripheral but are located on the side of the housing, which allowed engineers to eliminate overlap and redesign the intake port area. This produced noticeably more power, thanks to a better compression ratio. Second, the rotors are shaped differently, especially their side seals and low-height apex seals, which offer optimized lubrication.
These and other innovative technologies allow the RENESIS to achieve 49% higher output and dramatically reduced fuel consumption and emissions (the RX-8 meets LEV-II). It won International Engine of the Year and Best New Engine awards 2003 and also holds the "2.5 to 3 liter" size award for 2003 and 2004, where it is considered a 2.60 L engine. Finally, it was on the Ward's 10 Best Engines list for 2004 and 2005.
The RENESIS has also been adapted for a dual-fuel use, allowing it to run either on gasoline or hydrogen.
Sales
Annual Mazda Wankel "rotary" engine sales (data source: Ward's AutoNews)
Enlarge
Annual Mazda Wankel "rotary" engine sales (data source: Ward's AutoNews)
Mazda was fully committed to the Wankel engine just as the energy crisis of the 1970s struck. The company had all but eliminated piston engines from its products in 1974, a decision that nearly led to the company's collapse. A switch to a three-prong approach (gasoline, Diesel, and Wankel) for the 1980s relegated the Wankel to sports car use (in the RX-7 and Cosmo), severely limiting production volume. But the company has continued production continually since the mid-1960s, and is the only maker of Wankel-powered cars (the RX-8) today.
Though not reflected in the graph at right, the RX-8 is a higher-volume car than its predecessors, and Mazda is considering adding more Wankel models. The company has also developed a hydrogen-powered version of the Renesis. Though sales leveled off in the 1990s, these factors could cause the Wankel to again be a substantial force in the automotive market.
See also
* Wankel engine
* Mazda engines
External links
* Informational Videos on rebuilding a rotary engine
References
* Yamaguchi, Jack K. (1985). The New Mazda RX-7 and Mazda Rotary Engine Sports Cars. St. Martin's Press, New York. ISBN 0-312-69456-3.
* Jan P. Norbye (1973). "Watch out for Mazda!". Automobile Quarterly XI.1: 50-61.
Mazda Wankel rotary timeline
Type 1960s 1970s 1980s 1990s 2000s
5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9
Compact Familia/R100 R100
Mid-size Capella/RX-2 RX-2
Luce/RX-4 R130 RX-4 Legato HB HC
Full-size Roadpacer RP
GT Cosmo/RX-5 L10A L10B CD HB JC
Sports Savanna/RX-3/RX-7/RX-8 RX-3 SA FB FC FD SE
Pickup Proceed/REPU REPU
i found this page about our engines when i was looking for a cosmo eunos for me when i end up getting shipped to japan.
Mazda Wankel "rotary" engines
Mazda Wankel engine in the Deutsches Museum
Manufacturer Mazda
Production 1963 present
All Mazda Wankel "rotary" engines are essentially a single family they all derive from the first Wankel experiments in the early 1960s. Over the years, displacement has been increased (somewhat), and turbocharging has been added to great effect. This is the engine family that made Mazda famous.
In auto racing, the displacement of a Wankel engine is usually doubled for classing purposes. For Japanese tax purposes, the displacement of Wankel engines is defined as the equivalent of 1.5 times the nominal displacement. So the 1.3 L 13B engines count as just under 2.0 L for these purposes.
Wankel engines can be classified by their rotor size in terms of width (diameter) and depth (thickness). These metrics function similarly to the bore and stroke measurements of a piston engine. Nearly all Mazda production Wankel engines share a single rotor diameter: 105 mm (4.1 in) with a 15 mm (0.6 in) crankshaft offset. The only engine to diverge from this formula was the rare 13A, which used a 120 mm (4.7 in) diameter and 17.5 mm (0.7 in) offset.
40A
Mazda's first prototype Wankel was the 40A, a single-rotor engine very much like the NSU KKM400. Although never produced in volume, the 40A was a valuable testbed for Mazda engineers, and quickly demonstrated two serious challenges to the feasibility of the design: "chatter marks" in the housing, and heavy oil consumption. The chatter marks, nicknamed "devil's fingernails", were caused by improper sealing at the apex of the rotor. The oil consumption problem was addressed with heat-resistant rubber oil seals at the sides of the rotors. This early engine had a rotor diameter of 90 mm (3.5 in), an offset of 14 mm (0.6 in), and a depth of 59 mm (2.3 in).
L8A
The very first Mazda Cosmo prototype used a 798 cc L8A two-rotor Wankel. The engine and car were both shown at the 1963 Tokyo Motor Show. Hollow cast iron apex seals reduced vibration and thus chatter marks. It used dry-sump lubrication. Rotor diameter was up from the 40A to 98 mm (3.9 in), but depth dropped to 56 mm (2.2 in).
One-, three-, and four-rotor derivatives of the L8A were also created for experimentation.
10A
The 10A series was Mazda's first production Wankel, appearing in 1965. It was a two-rotor design, with each displacing 491 cc for a total of 982 cc. These engine featured the mainstream rotor dimensions with a 60 mm (2.4 in) depth.
The rotor housing was made of sand-cast aluminum plated with chrome, while the aluminum sides were sprayed with molten carbon steel for strength. Cast iron was used for the rotors themselves, and their eccentric shafts were of expensive chrome-molybdenum steel. The addition of aluminum/carbon apex seals addressed the chatter mark problem.
0810
The first 10A engine was the 0810, used in the Series I Cosmo from May, 1965 through July, 1968. These cars, and their revolutionary engine, were often called L10A models. Gross output was 110 hp (82 kW) at 7000 RPM and 130 Nm (96 ft.lbf) at 3500 RPM, but both numbers were probably optimistic.
The 10A featured twin side intake ports per rotor, each fed by a one of four carburetor barrels. Only one port per rotor was used under low loads for added fuel economy. A single peripheral exhaust port routed hot gas through the coolest parts of the housing, and engine coolant flowed axially rather than the radial flow used by NSU. A bit of oil was mixed with the intake charge for lubrication.
The 0810 was modified for the racing Cosmos used at Nόrburgring. These engines had both side- and peripheral-located intake ports switched with a butterfly valve for low- and high-RPM use (respectively)
Applications:
* 19651968 Mazda Cosmo Series I/L10A
0813
The improved 0813 engine appeared in July, 1968 in the Series II/L10B Cosmo. Its construction was very similar to the 0810, but the ports and carburetion were revised to produce 128 hp (96 kW) at 7000 RPM and 140 Nm (103 ft.lbf) at 5000 RPM. Again, these were Japanese net output figures.
Applications:
* 19681972 Mazda Cosmo Series II/L10B
0820
The 10A was substantially revised for wide-scale production in the R100/Familia Rotary. Many changes were made in an effort to reduce production costs. These included the use of cast iron in the housing sides, less-expensive molded (instead of sand-cast) aluminum for the housings, and chrome-steel for the eccentric shafts. The port arrangement remained the same, but exhaust was no longer routed around the housing.
Japanese-spec gross output was 100 hp (75 kW) at 7000 RPM and 98 ft.lbf (133 Nm) at 3500 RPM. The use of less-expensive components raised the weight of the engine from 224 lb (102 kg) to 268 lb (122 kg).
Applications:
* 19681973 Mazda R100/Familia Rotary
0866
The final member of the 10A family was the 1971 0866. This variant featured a cast-iron thermal reactor to reduce exhaust emissions and re-tuned exhaust ports. The die-cast rotor housing was now coated with a new process: The new Transplant Coating Process (TCP) featured sprayed-on steel which is then coated with chrome. Gross output was 105 hp (78 kW) at 7000 RPM and 135 Nm (99.5 ft.lbf) at 3500 RPM.
Applications:
* 19721974 Mazda RX-3 (Japan-spec)
13A
The 13A was designed especially for front wheel drive applications. It had two 655 cc rotors for a total of 1310 cc. This was the only production Mazda Wankel with different rotor dimensions: Diameter was 120 mm (4.7 in) and offset was 17.5 mm (0.7 in), but depth remained the same as the 10A at 60 mm (2.4 in). Another major difference from the previous engines was the integrated water-cooled oil cooler.
The 13A was used only in the 19691972 R130 Luce, where it produced 126 hp (94 kW) and 126 ft.lbf (172 Nm). This was the end of the line for this engine design: The next Luce was rear wheel drive and Mazda never again made a front wheel drive rotary vehicle.
Applications:
* 19701972 Mazda R130
12A
The 12A was a "bored-out" version of the 10A the rotor diameter was the same, but the depth was increased by 10 mm (0.4 in) to 70 mm (2.8 in). Each of its two rotors displaced 573 cc for a total of 1146 cc. The 12A series was produced for 15 years, from May 1970 through 1985. In 1974, a 12A became the first engine built outside of western Europe or the U.S to finish the 24 hours of Le Mans.
In 1974, a new process was used to harden the rotor housing. The Sheet-metal Insert Process (SIP) used a sheet of steel much like a conventional piston engine cylinder liner with a chrome plated surface. The side housing coating was also changed to eliminate the troublesome sprayed metal. The new "REST" process created such a strong housing, the old carbon seals could be abandoned in favor of conventional cast iron.
Early 12A engines also feature a thermal reactor, similar to the 0866 10A, and some use an exhaust port insert to reduce exhaust noise. A lean-burn version was introduced in 1979 (in Japan) and 1980 (in America) which substituted a more-conventional catalytic converter for this "afterburner". A major modification of the 12A architecture was the 6PI which featured variable induction ports.
Applications:
* 19701972 Mazda R100
* 19701974 Mazda RX-2, 130 hp (97 kW) and 115 ft.lbf (156 Nm)
* 19721974 Mazda RX-3 (Japan), 110 hp (82 kW) and 100 ft.lbf (135 Nm)
* 19721974 Mazda RX-4
* 19721980 Mazda Luce
* 19781979 Mazda RX-7, 100 hp (75 kW)
* Lean-burn
o 19791985 Mazda RX-7 (Japan)
o 19801985 Mazda RX-7 (USA)
* 6PI
o 19811985 Mazda Luce
o 19811985 Mazda Cosmo
Turbo
The ultimate 12A engine was the turbocharged and fuel injected engine used in the Japan-spec HB series Cosmo, Luce, and SA series RX-7. In 1982 a 12A turbo powered Cosmo coupe was officially the fastest production car in Japan. It featured "semi-direct injection" into both rotors at once, a technique that was much more successful than it would appear. A passive knock sensor was used to eliminate detonation, and later models featured a specially-designed "impact turbo" which was tweaked for the unique exhaust signature of the Wankel engine. The engine continued until 1989 in the HB Cosmo series but by that stage it had grown a reputation as a thirsty engine.
Output was 165 hp (123 kW) at 6000 RPM and 186 Nm (137 ft.lbf) at 4000 RPM.
Applications:
* 19821989 Mazda Cosmo
* 19821985 Mazda Luce
* 19841985 Mazda RX-7
12B
The improved 12B was quietly introduced in 1974. In the US it was the start of the single distributors engines.
NOTE: the previous 12A & 10A engines used the twin distributors.
Applications:
* 19741978 Mazda RX-2
* 19741978 Mazda RX-3
13B
The 13B is the most widely produced engine. It was the basis for all future Mazda Wankel engines, and was produced for almost 30 years. The 13B is no relation to the 13A. Instead, it is a lengthened version of the 12A, having 80 mm (3.1 in) thick rotors. It had the largest displacement yet at 654 cc, for a total of 1308 cc.
In the United States, the 13B was available from 1974 through 1978 and was then retired until the 1984 RX-7 GSL-SE. It was retired again in 2002 with the cancellation of the RX-7. The engine was continually used in Japan from 1972's Mazda Luce/RX-4 through 2002's RX-7.
AP
The 13B was designed with both high performance and low emissions in mind. Early vehicles using this engine used the AP name, which signified these two characteristics.
Applications:
* 19721980 Mazda Cosmo AP
* 19741977 Mazda Rotary Pickup
* 19751977 Mazda Roadpacer
* 19741978 Mazda RX-4
* 19751980 RX-5
13B-RESI
A tuned intake manifold was used in a Wankel engine for the first time with the 13B-RESI ("Rotary Engine Super Injection"). The so-called Dynamic Effect Intake featured a two-level intake box which derived a supercharger-like effect from the Helmholtz resonance of the opening and closing intake ports. The RESI engine also featured Bosch L-Jetronic fuel injection. Output was much improved at 135 hp (101 kW) and 133 ft·lbf (180 N·m).
Applications:
* 19841985 Mazda HB Luce
* 19841985 Mazda HB Cosmo
* 19841985 Mazda FB RX-7 GSL-SE
13B-DEI
Like the 12A-SIP, the second-generation RX-7 bowed with a variable-intake system. Dubbed DEI, the engine features both the 6PI and DEI systems, as well as four-injector electronic fuel injection. Total output is up to 146 hp (109 kW) at 6500 rpm and 138 ft·lbf (187 N·m) at 3500 rpm.
Applications:
* 19861988 Mazda RX-7, 146 hp (108 kW)
* 19891991 Mazda RX-7, 160 hp (119 kW)
13B-Turbo
The 13B-DEI was turbocharged in 1987. It features the newer four-injector fuel injection of the 6PI engine, but lacks that engine's eponymous variable intake system. The twin-scroll turbocharger is fed with a two-stage valve to reduce turbo lag. Output is way up at 185 hp (138 kW) at 6500 rpm and 183 ft·lbf (248 N·m) at 3500 rpm.
Applications:
* 19861991 Mazda HC Luce Turbo-II, 185 hp (138 kW)
* 19871988 Mazda FC RX-7 Turbo-II, 185 hp (138 kW)
* 19891991 Mazda FC RX-7 Turbo-II, 200 hp (147 kW)
13B-REW
A twin-turbocharged version of the 13B, the 13B-REW, became famous for its high output and low weight. The twin Hitachi HT-12 turbos were operated sequentially, with the primary providing boost until 4,500 RPM, and the secondary coming online afterwards. Output eventually reached, and may have exceeded, Japan's "maximum" of 280 hp (208 kW) for the final revision used in the series 8 Mazda RX-7.
Applications:
* 19901995 Eunos Cosmo, 235 hp (176 kW)
* 19921995 Mazda RX-7, 255 hp (190 kW)
* 19961998 Mazda RX-7, 265 hp (197 kW)
* 19992002 Mazda RX-7, 280 hp (208 kW)
20B
Eunos Cosmo engine at the Mazda Museum
Enlarge
Eunos Cosmo engine at the Mazda Museum
Rotary Engine 20B
Enlarge
Rotary Engine 20B
In Le Mans racing, the first three-rotor engine used in the 757 was named the 13G.
The main difference between the 13G and 20B is that the 13G uses a factory peripheral intake port(used for racing) and the 20B uses side intake ports.
It was renamed 20B after Mazda's naming convention for the 767 in November of 1987.
The three-rotor 20B-REW was only used in the 1990-1995 Eunos Cosmo. It was the world's first volume production twin-turbo setup featured in both 13B-REW & 20B-REW form. It displaced 1962 cc (three 654 cc rotors) and used 0.7 bar (around 10psi)of turbo pressure to produce 300 hp (224 kW) and 300 ft.lbf (402 Nm). It was at the time the highest torque output engine of any Japanese vehicle manufacturer.
26J
The first Mazda four-rotor engine was the 26J used in the 1988 767 Le Mans prototypes. This motor was poorly designed, and was replaced by the 26B.
R26B
The most prominent 4-rotor engine from Mazda was used exclusively for various Mazda-built GT cars (including the 767 and 787B) in replacement of the older 13J. In 1991 this engine in a 787B became the first from outside the U.S. or Western Europe and the first (and so far only) car with a rotary engine to win outright the 24 hours of Le Mans race. It displaced 2622 cc and built 700 hp (522 kW) at 9000RPM. The engine design originates as a single 13B with: an additional rotor and housing added at each end, continually variable geometry intakes, and an additional (third) spark plug. The R26B's engine block can be purchased at retail from Mazdaspeed, but no internal parts are available to the general public.
13B-MSP RENESIS
Mazda RENESIS prototype in the Mazda Museum
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Mazda RENESIS prototype in the Mazda Museum
The RENESIS engine also 13B-MSP, for Multi Side Port , which first appeared in production in the 2003 Mazda RX-8, is an evolution of the previous 13B. It was designed to reduce exhaust emission and improve fuel economy, which were two of the most recurrent drawbacks of rotary engines. Unlike its predecessors from the 13B range, it is naturally aspirated, leading to lower power from its two versions (212 and 232hp) compared to the Mazda RX-7's twin-turbocharged 13B-REW (280hp).
The engine entailed two major changes. First, the exhausts ports are no longer peripheral but are located on the side of the housing, which allowed engineers to eliminate overlap and redesign the intake port area. This produced noticeably more power, thanks to a better compression ratio. Second, the rotors are shaped differently, especially their side seals and low-height apex seals, which offer optimized lubrication.
These and other innovative technologies allow the RENESIS to achieve 49% higher output and dramatically reduced fuel consumption and emissions (the RX-8 meets LEV-II). It won International Engine of the Year and Best New Engine awards 2003 and also holds the "2.5 to 3 liter" size award for 2003 and 2004, where it is considered a 2.60 L engine. Finally, it was on the Ward's 10 Best Engines list for 2004 and 2005.
The RENESIS has also been adapted for a dual-fuel use, allowing it to run either on gasoline or hydrogen.
Sales
Annual Mazda Wankel "rotary" engine sales (data source: Ward's AutoNews)
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Annual Mazda Wankel "rotary" engine sales (data source: Ward's AutoNews)
Mazda was fully committed to the Wankel engine just as the energy crisis of the 1970s struck. The company had all but eliminated piston engines from its products in 1974, a decision that nearly led to the company's collapse. A switch to a three-prong approach (gasoline, Diesel, and Wankel) for the 1980s relegated the Wankel to sports car use (in the RX-7 and Cosmo), severely limiting production volume. But the company has continued production continually since the mid-1960s, and is the only maker of Wankel-powered cars (the RX-8) today.
Though not reflected in the graph at right, the RX-8 is a higher-volume car than its predecessors, and Mazda is considering adding more Wankel models. The company has also developed a hydrogen-powered version of the Renesis. Though sales leveled off in the 1990s, these factors could cause the Wankel to again be a substantial force in the automotive market.
See also
* Wankel engine
* Mazda engines
External links
* Informational Videos on rebuilding a rotary engine
References
* Yamaguchi, Jack K. (1985). The New Mazda RX-7 and Mazda Rotary Engine Sports Cars. St. Martin's Press, New York. ISBN 0-312-69456-3.
* Jan P. Norbye (1973). "Watch out for Mazda!". Automobile Quarterly XI.1: 50-61.
Mazda Wankel rotary timeline
Type 1960s 1970s 1980s 1990s 2000s
5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9
Compact Familia/R100 R100
Mid-size Capella/RX-2 RX-2
Luce/RX-4 R130 RX-4 Legato HB HC
Full-size Roadpacer RP
GT Cosmo/RX-5 L10A L10B CD HB JC
Sports Savanna/RX-3/RX-7/RX-8 RX-3 SA FB FC FD SE
Pickup Proceed/REPU REPU
11-12-07, 11:02 PM
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it is kind of cool how they actually offered all those engines and were are only really deal with four of them on a regular basis. it would be really nice if someone could get a hold of the internals and specs for some of those race engines
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