Rotary engine Guide, Meaning , Facts, Information and Description
- Alternative meaning: Wankel engine
In concept, a rotary engine is simple. It is a standard Otto cycle engine, but instead of having an orthodox fixed cylinder block with rotating crankshaft, the crankshaft remains stationary and the entire cylinder block rotates around it. In the most common form, the crankshaft was fixed solidly to an aircraft frame, and the propeller simply bolted onto the front of the cylinder block.
The effect of rotating such a large mass was the creation of a large gyroscopic flywheel. This design had a very favorable power-to-weight ratio and was the engine that powered many successful WWI fighter aircraft. The credit was initially given to the excellent power-to-weight ratio, however it was later discovered that the great success was in fact a result of the extremely high level of gyroscopic effect that enabled the aircraft to perform radical maneuvers. This was not normal for a conventionally-powered aircraft, and the handling ability was an unexpected setback to the enemy pursuer.
Most rotary engines were arranged with the cylinders pointed outwards from a single crankshaft, in the same general form as a radial, but there were also rotary boxer engines and even one cylinder rotaries.
| Table of contents |
|
2 History in Aircraft 3 Use in Cars and Motorcycles 4 See Also 5 External Links |
The major source of power wasteage in a reciprocating engine such as an inline or v-type is the internal inertia loss. A significant amount of power is required to accelerate a mass from a motionless position in any direction and then to stop and reverse direction 180 degrees and then to re-accelerate and stop, and so on. Any mass that merely moves back and forth, or up and down without going anywhere, requires a large amount of energy that is not being used to add to the rotation of the propeller. This also creates vibration that requires heavy counterbalancing on the rotating crankshaft, which is unnecessary in the rotary engine. Instead, the rotating cylinders' eccentric orbit about the crankshaft contributes to the rotation of the propeller with no parts coming to a complete stop, thus eliminating vibration and creating the total absence of inertia loss.
The high power-to-weight ratio gained by eliminating these internal inertial losses, combined with the gyroscopic induced flight characteristics of the aircraft, made it something to be reckoned with in a close-quarters dog fight.
The first effective rotaries were built by Stephen Balzer, who was interested in the design for two main reasons:
The next major advance in the design was Lauren Seguin's "Gnome" from 1908. Originally a 5-cylinder 50 hp (37 kW) engine, the production versions were scaled up to a 7-cylinder 50 hp (37 kW), which soon reached 80 hp (60 kW), and then 110 hp (80 kW). The engine was at this later standard when WWI started, and the Gnome quickly found itself being used in a large number of aircraft designs. It was so good that it was licensed by a number of companies, include the German Oberursel firm, later purchased by Fokker. It was not at all uncommon for French Gnomes to meet German versions in combat.
The Gnome (and its copies) had a number of features that made it unique, even among the rotaries. Notably, the fuel was mixed and sprayed into the center of the engine through a hollow crankshaft, and then into the cylinders through the piston itself, a single valve on the top of the piston let the mixture in when opened. The valves were counter balanced so than only a small force was needed to open them, and releasing the force closed them without any springs. The center of the engine is normally where the oil would be, and the fuel would wash it away. To fix this, the oil was mixed in liberal quantities with the fuel, and the engine spewed smoke due to the burning oil. Finally, the Gnome had no throttle or carburetor, with the fuel being sprayed into the spinning engine, the motion alone was enough to mix the fuel fairly well. Of course with no throttle, the engine was either on or off, so something as simple as reducing power for landing required the pilot to cut the ignition, "blipping" the engine on and off.
Throughout the early period of the war, the power-to-weight ratio of the rotaries remained ahead of that of their competition. They were used almost universally in fighter aircraft, while traditional water cooled designs were used on larger aircraft. The engines had a number of disadvantages, notably very poor fuel consumption because the engine was always "full throttle". In combat the huge "flywheel" the rotary had originally been designed to create turned out to result in tricky handling due to gyroscope effects as well. But they maintained their edge through a series of small upgrades, and many newer designs continued to use them.
1918 saw the introduction of the inline powered Fokker D.VII. Through superb design the D-VII was able to dogfight with the rotaries, and outclimb and outrun them with ease due to its 185 hp (140 kW) engine. Aircraft had evolved so that speed had become the most important aspect of ability, and speed can only be provided through increased power. Larger rotaries were attempted, but the gyroscopic effects were overwhelming and they proved to be largely unworkable. Inline engines were able to increase power through increased RPM, another trick the rotary couldn't match. By the end of the year only a single new rotary was designed, Fokker's own D-VIII, designed solely to provide some use for their Oberursel factory. When the war ended, the rotary disappeared almost instantly, with WWI engines being used for training for a short time until their poor fuel economy drove the users to newer engines.
The two original benefits were now no longer valid at the end of the war. Air cooling proved to be entirely "doable" as production techniques improved to the point where finning was no longer an issue. In addition as the size of the engines grew, the propellers themselves became large enough to act as the flywheel. Faster RPM also dramatically reduced the need for a flywheel at all. This left the rotary with high fuel and oil consumption compared to other designs, and not much else.
Perhaps more seriously, having such a large weight spinning in an aircraft produces significant gyroscopic effects. Maneuvering an aircraft with this kind of engine required a lot of skill since it did not always respond to controls as expected. It is said that the rotary powered Sopwith Camel could execute a turn to the right at double the rate to the left, by manuvering the plane around the massive gyroscopic momentum of the engine. With even larger rotaries, the planes proved almost unflyable.
Although the rotary engines were mostly used in aircraft, there were also a few cars and motorcycles with rotary engines. The most famous motorcycle (probably because of winning many races) is the Megola motorcycle with a radial rotary engine inside the front wheel. Another motorcycle with a radial rotary engine was the Redrup Radial, which had a rotating 3 cylinder engine in its frame.
In 1904, the Barry engine was built in Wales, a rotating 2 cylinder boxer engine inside a motorcycle frame, weighting 6.5kg. In the 1940s Cyril Pullin developed the Powerwheel, a wheel with rotating one cylinder engine, clutch and drum brake inside the hub but it never went into serial production.
Cars with rotary engines were built (among others) by American companies Adams-Farwell, Bailey, Balzer and Intrepid.
This is an Article on Rotary engine. Page Contains Information, Facts Details or Explanation Guide About Rotary engine Energy Characteristics
History in Aircraft
Another advantage, not realized at first, is that the pistons do not actually reciprocate, but orbit a common center. This leads to smoother running. Balzer's first designs were ready for use in 1899, at which time they were the most advanced in the world. Other aircraft engines would not catch up in performance for a decade. He then became involved in Langley's Aerodrome attempts, which bankrupted him while he tried to make much larger versions.Use in Cars and Motorcycles
See Also
External Links