Applications
Automobile racing
In the racing world, Mazda has had substantial success with two-rotor, three-rotor, and four-rotor cars. Private racers have also had considerable success with stock and modified Mazda Wankel-engine cars.[49]
The Sigma MC74 powered by a Mazda 12A engine was the first engine and only team from outside Western Europe or the United States to finish the entire 24 hours of the 24 Hours of Le Mans race, in 1974. Mazda is the only team from outside Western Europe or the United States to have won Le Mans outright and the only non-piston engine ever to win Le Mans, which the company accomplished in 1991 with their four-rotor 787B (2,622 cc or 160 cu in—actual displacement, rated by FIA formula at 4,708 cc or 287 cu in). The following year, a planned rule change at Le Mans made the Mazda 787B ineligible to race due to weight advantages.[citation needed]
The Mazda RX-7 has won more IMSA races in its class than any other model of automobile, with its one hundredth victory on September 2, 1990. Following that, the RX-7 won its class in the IMSA 24 Hours of Daytona race ten years in a row, starting in 1982. The RX7 won the IMSA Grand Touring Under Two Liter (GTU) championship each year from 1980 through 1987, inclusive.
Formula Mazda Racing features open-wheel race cars with Mazda Wankel engines, adaptable to both oval tracks and road courses, on several levels of competition. Since 1991, the professionally organized Star Mazda Series has been the most popular format for sponsors, spectators, and upward bound drivers. The engines are all built by one engine builder, certified to produce the prescribed power, and sealed to discourage tampering. They are in a relatively mild state of racing tune, so that they are extremely reliable and can go years between motor rebuilds.[50]
The Malibu Grand Prix chain, similar in concept to commercial recreational kart racing tracks, operates several venues in the United States where a customer can purchase several laps around a track in a vehicle very similar to open wheel racing vehicles, but powered by a small Curtiss-Wright rotary engine.
In engines having more than two rotors, or two rotor race engines intended for high-rpm use, a multi-piece eccentric shaft may be used, allowing additional bearings between rotors. While this approach does increase the complexity of the eccentric shaft design, it has been used successfully in the Mazda's production three-rotor 20B-REW engine, as well as many low volume production race engines. The C-111-2 4 Rotor Mercedes-Benz eccentric shaft for the KE Serie 70, Typ DB M950 KE409 is made in one piece. Mercedes-Benz used split bearings.
Motorcycle engines
The world's first Wankel-engined motorcycle was the 1960 'IFA/MZ KKM 175W' built by German motorcycle manufacturer MZ on a licence from NSU.[51]
In 1972, Yamaha introduced the 'RZ201' at the Tokyo Motor Show, a prototype with Wankel engine, weighing 220 kg and producing 60 hp from a 660 cc engine (US patent N3964448). Kawasaki presented also in 1972 its Kawasaki X99 RCE prototype (US patent N 3848574, and also 3991722), both Yamaha and Kawasaki claimed having solved all problems previously found in Wankel RCEs, fuel economy, exhaust emissions and engine duration, but none entered the stage of production.
From 1974 to 1977 Hercules produced a limited number of motorcycles powered by Wankel engines, its production was discontinued because of failing to attain the necessary number of motorcycles sold by month to reach profitability by 27 units.[52]
The Suzuki RE5 single-rotor motorcycle was produced from 1975 to 1976. It proved to be a complex design, with liquid cooling and oil cooling, and multiple lubrication and carburetor systems, these gave problems that were solved after the first series units. It worked well and was smooth, but being rather heavy and having a modest 62 bhp power output, it did not sell well.[53]
Dutch motorcycle importer and manufacturer van Veen produced small quantities of their dual rotor Wankel-engined OCR-1000 between 1978 and 1980, using surplus Comotor engines.
In the early 1980s, David Garside's BSA twin-rotor engine reached production at Norton as the air-cooled twin-rotor Norton Classic. The Classic was succeeded by the later liquid-cooled Norton Commander and the Interpol2, a police version. (These machines used motor tooling and blank apex seals).[54] The Norton engine later formed the basis for the MidWest AE series aero-engine. Norton used a Wankel engine in several models including the Norton F1, F1 Sports, RC588, RCW588, NRS588, most notably Steve Hislop riding to various victories on Norton's F1 in the Isle of Man Tourist Trophy in 1992. Norton has proposed a new 588 cc twin-rotor model called the NRV588 and a 700 cc version called the NRV700.[55] A former mechanic at Norton, Brian Crighton, started developing his own rotary engined motorcycles line named Roton, whose products won several local Australia races.
No motorcycles with Wankel engines have been produced for sale to the general public for road use since 1992.
Aircraft engines
In principle, a Wankel engine should be ideal for light aircraft, as it is light, compact, almost vibrationless and has a high power-to-weight ratio. Further aviation benefits of a Wankel engine include: (i) rotors cannot seize, since rotor casings expand more than rotors; (ii) a Wankel is not susceptible to "shock-cooling" during descent; (iii) a Wankel does not require an enriched mixture for cooling at high power; (iv) having no reciprocating parts, it is less vulnerable to damage during "over-revving" (the main rev-limit being the strength of the main bearings). Unlike the case with cars (such as the NSU Ro 80) and motorcycles, a Wankel aero-engine will (because of the time taken for pre-flight checks) inevitably be sufficiently warm before full power is asked of it. A Wankel aero-engine spends most of its working time at high power outputs, with little idling, so peripheral ports are ideal; and this makes feasible modular engines with more than two rotors. If "carb-icing" is an issue, plenty of waste engine heat is available to prevent trouble.
The first Wankel rotary-engine aircraft was the experimental Lockheed Q-Star civilian version of the United States Army's reconnaissance QT-2, basically a powered Schweizer sailplane, in 1968 or 1969. It was powered by a 185 hp (138 kW) Curtiss-Wright RC2-60 Wankel rotary engine; the same engine model was also flown in a Cessna Cardinal and other airplanes and a helicopter.[56][57] In Germany around 1976, a pusher ducted fan airplane powered by a modified NSU multi-rotor Wankel engine was developed in both civilian and military versions, Fanliner and Fantrainer.
Aircraft Wankels have made something of a comeback in recent years. None of their advantages have been lost in comparison to other engines. They are increasingly being found in roles where their compact size and quiet operation is important, notably in drones, or UAVs. Many companies and hobbyists adapt Mazda rotary engines (taken from automobiles) to aircraft use; others, including Wankel GmbH itself, manufacture Wankel rotary engines dedicated for the purpose.[58][59] One such use are the "Rotapower" engines in the Moller Skycar M400. Another example of purpose built aircraft rotaries are Austro Engine's 55 hp (40.4 kW) AE50R (certified) and 75 hp (55 kW) AE75R (under development) both appr. 2 hp/kg.[60]
Wankel engines are also becoming increasingly popular in homebuilt experimental aircraft, such as the ARV Super2 which can be re-engined with the MidWest AE series aero-engine. Most are Mazda 12A and 13B automobile engines, converted to aviation use. This is a very cost-effective alternative to certified aircraft engines, providing engines ranging from 100 to 300 horsepower (220 kW) at a fraction of the cost of traditional engines. These conversions first took place in the early 1970s. With a number of these engines mounted on aircraft, as of 10 December 2006 the National Transportation Safety Board has only seven reports of incidents involving aircraft with Mazda engines, and none of these were a failure due to design or manufacturing flaws.[citation needed]
Peter Garrison, contributing editor for Flying magazine, has said that "In my opinion, however, the most promising engine for aviation use is the Mazda rotary."[61] Mazdas have indeed worked well when converted for use in homebuilt aircraft. However, the real challenge in aviation is producing FAA-certified alternatives to the standard reciprocating engines that power most small general aviation aircraft. Mistral Engines, based in Switzerland, developed purpose-built rotaries for factory and retrofit installations on certified production aircraft. The G-190 and G-230-TS rotary engines were already flying in the experimental market, and Mistral Engines hoped for FAA and JAA certification by 2011. As of June 2010, G-300 rotary engine development ceased, with the company citing a need for cash flow to complete development.[62]
Mistral claims to have overcome the challenges of fuel consumption inherent in the rotary, at least to the extent that the engines are demonstrating specific fuel consumption within a few points of reciprocating engines of similar displacement. While fuel burn is still marginally higher than traditional engines, it is outweighed by other beneficial factors.[63][64]
At the price of increased complication for a high pressure diesel type injection system, fuel consumption in the same range as small pre-chamber automotive and industrial diesels has been demonstrated with Curtiss-Wright's Stratified Charge multi-fuel engines, while preserving the aforementioned Wankel rotary advantages[65][66]
Since Wankel engines operate at a relatively high rotational speed with relatively low torque, propeller aircraft must use a Propeller Speed Reduction Unit (PSRU) to keep their propellers within the proper speed range. Experimental aircraft with Wankel engines use PSRUs: for instance, the MidWest twin-rotor engine has a 2.95:1 reduction gearbox. Although one may at first be apprehensive of the Wankel's relatively high rotational speed, in fact it is only the eccentric shaft that spins fast, while the rotors turn at exactly one-third of that speed. So, even when the shaft is spinning at, say, 7,500 rpm, the rotors are turning at a much more leisurely 2,500 rpm.
Pratt & Whitney Rocketdyne have been commissioned by DARPA to develop a diesel Wankel engine for use in a prototype VTOL flying car called the "Transformer".[67] The engine, based on an earlier UAV diesel Wankel concept called 'EnduroCORE',[68] will utilize Wankel rotors of varying sizes on a shared eccentric shaft to increase efficiency.[69] The engine is claimed to be a 'full-compression, full-expansion, diesel-cycle engine'. An October 28, 2010 patent from Pratt & Whitney Rocketdyne, describes a Wankel engine superficially similar to Rolls-Royce's earlier prototype that required an external air compressor to achieve high enough compression for diesel-cycle combustion.[70][71] The design differs from Rolls-Royce's diesel Wankel mainly by proposing an injector both in the exhaust passage between the combustor rotor and expansion rotor stages, and an injector in the expansion rotor's expansion chamber, for 'afterburning'.
Range extender
Due to the compact size and low weight of a Wankel engine, it has found its way into electric vehicles as range extenders. In 2010 Audi revealed that in their electric car, the A1 e-tron, they would have a small 250 cc Wankel engine running at 5,000 rpm that would recharge the car's batteries as needed.[73]
In 2010 FEV Inc revealed that in their electric version of the Fiat 500 a Wankel engine would be used as range extender as well.[74]
The DA36 E-Star, an aircraft designed by Siemens, Diamond Aircraft and EADS, employs a series hybrid powertrain, with a Wankel engine as internal combustion engine.[75]
Other uses
Small Wankel engines are being found increasingly in other roles, such as go-karts,[76][77] personal water craft and auxiliary power units for aircraft.[78][79] Kawasaki patented also a mixture cooled RCE engine (US patent 3991722) The Graupner/O.S. 49-PI is a 1.27 hp (947 W) 5 cc Wankel engine for model airplane use which has been in production essentially unchanged since 1970; even with a large muffler, the entire package weighs only 380 grams (13.4 ounces).[80][81]
The simplicity of the Wankel makes it well-suited for mini, micro, and micro-mini engine designs. The Microelectromechanical systems (MEMS) Rotary Engine Lab at the University of California, Berkeley has been developing Wankel engines of down to 1 mm in diameter with displacements less than 0.1 cc. Materials include silicon and motive power includes compressed air. The goal is to eventually develop an internal combustion engine that will deliver 100 milliwatts of electrical power; the engine itself will serve as the rotor of the generator, with magnets built into the engine rotor itself.[82][83] Development of the miniature Wankel engine stopped at UC Berkeley at the end of the DARPA contract. The several generations of miniature Wankel engines developed at UC Berkeley struggled to maintain compression. In addition, miniature engines suffer from an adverse surface to volume ratio; the relatively large surface area transfers away what little heat is generated in the small combustion volume resulting in quenching and low efficiency.
The largest Wankel engine was built by Ingersoll-Rand; available in 550 hp (410 kW) one rotor and 1,100 hp (820 kW) two rotor versions, displacing 41 liters per rotor with a rotor approximately one meter in diameter. It was available between 1975 and 1985. It was derived from a previous, unsuccessful Curtiss-Wright design, which failed because of a well-known problem with all internal combustion engines: the fixed speed at which the flame front travels limits the distance combustion can travel from the point of ignition in a given time, and thereby limiting the maximum size of the cylinder or rotor chamber which can be used. This problem was solved by limiting the engine speed to only 1200 rpm and the use of natural gas as fuel; this was particularly well chosen, since one of the major uses of the engine was to drive compressors on natural gas pipelines.[84] Yanmar Diesel of Japan produced some small, charge-cooled rotor rotary engines for uses such as chainsaws and outboard engines,[85] some of their contributions are that the LDR (rotor recess in the leading edge of combustion chamber) engines had better exhaust emissions profiles, and that reed-valve controlled intake ports improve part-load and low RPM performance.[86]
Non-internal combustion[edit]
In addition for use as an internal combustion engine, the basic Wankel design has also been used for gas compressors, and superchargers for internal combustion engines, but in these cases, although the design still offers advantages in reliability, the basic advantages of the Wankel in size and weight over the four-stroke internal combustion engine are irrelevant. In a design using a Wankel supercharger on a Wankel engine, the supercharger is twice the size of the engine.
The Wankel design is used in the seat belt pre-tensioner system[87] of some Mercedes-Benz[88] and Volkswagen[89] cars. When the deceleration sensors sense a potential crash, small explosive cartridges are triggered electrically and the resulting pressurized gas feeds into tiny Wankel engines which rotate to take up the slack in the seat belt systems, anchoring the driver and passengers firmly in the seat before a collision.[90]
