| • Science | • People | • Locations | • Timeline |
| Contents | ||
A propeller's efficiency is determined by (thrust × axial speed)/(resistance torque × rotational speed). Changes to a propeller's efficiency are produced by a number of factors, notably adjustments to the helix angle, the angle between the resultant relative velocity and the blade rotation direction, and to blade pitch. Very small pitch and helix angles give a good performance against resistance but provide little thrust, while larger angles have the opposite effect. The best helix angle is as if the blade was a wing producing much more lift than drag, roughly 45° in practice. However due to the shape of the propeller only part of the blade can actually be operating at peak efficiency, the outer part of the blade produces the most thrust and so the blade is positioned at a pitch that gives optimum angle to that portion. Since a large portion of the blade is therefore at an inefficient angle the inboard ends of the blade are subsumed into a streamlined spinner to reduce the resistance
torque that would otherwise be created.
Very high efficiency propellers are similar in aerofoil section to a low drag wing and as such are poor in operation when at other than their optimum angle of attack. It required advanced control systems and better section profiling to counter the need for accurate matching of pitch to flight speed and engine speed to power so as to make these type of propellers usable.
However with a propeller at a pitch angle of 45° at low flight speeds the angle of attack will be high, possibly high enough to stall the airfoil. Since this is an extremely inefficient regime in which to operate the propeller, it means that most propellers are fitted with mechanisms to allow variable pitch - Coarse pitch for high speed flight and fine pitch for climbing or accelerating at lower speeds. Early pitch control settings were pilot operated and so limited to only three or so settings, later systems were automatic. Variable pitch was replaced with the constant speed mechanism.
Constant-speed propellers automatically adjust the blade pitch angle to alter resistance torque in response to sensed changes in RPM. Initially in a rather crude fashion with the pilot altering the setting via control of the prop governor , but in more advanced aircraft the mechanism is linked into the entire engine management system for very fine control. The system is termed constant-speed because aeroengines produce maximum power at high revolutions and changing engine speed increases fuel consumption. It is, therefore, beneficial to run an engine at an optimum constant independent of flight speed, setting separate requirements for high power situations and cruising and controlling speed within these bands without changing RPM.
A further consideration is the number and the shape of the blades used. Increasing the aspect ratio of the blades reduces drag but the amount of thrust produced depends on blade area, so using high aspect blades can lead to the need for a propeller diameter which is unusable. A further balance is that a smaller number of blades reduces interference effects between the blades, but to have sufficient blade area to transmit the available power within a set diameter means a compromise is needed. Increasing the number of blades also decreases the amount of work each blade is required to perform, limiting the local Mach number - a significant performance limit on propellers.
Contra-rotating propellers involves placing a second propeller rotating in the opposite direction immediately 'downstream' of the main propeller so as to recover energy lost in the swirling motion of the air in the propeller slipstream. Contra-rotation also increases power without increasing propeller diameter and provides a counter to the torque of high-power piston engines and the gyroscopic precession effects of the slipstream swirl. However on small aircraft the added cost, complexity, weight and noise of the system rarely make it worthwhile.
The propeller is usually attached to the crankshaft of the engine, either directly or through a gearbox. Light aircraft sometimes forego the weight, complexity and cost of gearing but on larger aircraft and with turboprop engines it is essential.
As mentioned, a propeller's performance suffers as the blade speed exceeds the speed of sound. As the relative air speed at the blade is rotation speed plus axial speed, a propeller blade will reach sonic speed sometime before the rest of the aircraft (with a theoretical blade the maximum aircraft speed is about 845 km/h (Mach 0.7) at sea-level, in reality it is rather lower). When a blade tip becomes supersonicAny speed over the speed of sound, which is approximately 343 m/s or 761 mph or 1,225 km/h at sea level, is said to be supersonic . Many modern fighter aircraft are supersonic. The Concorde was a supersonic passenger aircraft, but, since its final retirem, drag and torque resistance increase suddenly and shock waveFor the vector animation platform, see Macromedia Shockwave. In fluid dynamics, a shock wave is a strong pressure wave. See Rankine-Hugoniot equation. In compressible fluids such as air, disturbances such as pressure changes caused by a solid object movins form creating a sharp increase in noise. Aircraft with conventional propellers therefore do not usually fly faster than Mach 0.6 although there are certain craft, usually military, which do operate at Mach 0.8 or higher although there is considerable fall off in efficiency.
Naturally there have been efforts to develop propellers for aircraft at high subsonic speeds. The 'fix' is similar to that of transonic wing design. The maximum relative velocity is kept as low as possible by careful control of pitch to allow the blades to have large helix angles; thin blade sections are used and the blades are swept back in a scimitarThe term scimitar refers to a sword with a curved blade from western Asia. While the name 'scimitar' is quite prevalent when speaking of Arabian swords, in reality there is no such 'historic sword' called a scimitar. The word scimitar is a derivative from shape; a large number of blades are used to reduce work per blade and so circulation strength; contra-rotation is used. The propellers designed are more efficient than turbo-fans and in terms of cruising speed (Mach 0.7-0.85) suitable for airliners except that the noise is tremendous.