Jet engine
A jet engine is a reaction engine discharging a fast moving jet that generates thrust by jet propulsion in accordance with Newton's laws of motion. This broad definition of jet engines includes turbojets, turbofans, rockets, ramjets, and pulse jets. In general, jet engines are combustion engines but non-combusting forms also exist.
In common parlance, the term jet engine loosely refers to an internal combustion airbreathing jet engine (a duct engine). These typically consist of an engine with a rotary (rotating) air compressor powered by a turbine ("Brayton cycle"), with the leftover power providing thrust via a propelling nozzle. Jet aircraft use these types of engines for long-distance travel. Early jet aircraft used turbojet engines which were relatively inefficient for subsonic flight. Modern subsonic jet aircraft usually use high-bypass turbofan engines. These engines offer high speed and greater fuel efficiency than piston and propeller aeroengines over long distances.[1]
History
Jet engines date back to the invention of the aeolipile before the first century AD. This device directed steam power through two nozzles to cause a sphere to spin rapidly on its axis. So far as is known, it did not supply mechanical power and the potential practical applications of this invention did not receive recognition. Instead, it was seen as a curiosity.
Jet propulsion only gained practical applications with the invention of the gunpowder-powered rocket by the Chinese in the 13th century as a type of firework, and gradually progressed to propel formidable weaponry. However, although very powerful, at reasonable flight speeds rockets are very inefficient and so jet propulsion technology stalled for hundreds of years.
The earliest attempts at airbreathing jet engines were hybrid designs in which an external power source first compressed air, which was then mixed with fuel and burned for jet thrust. In one such system, called a thermojet by Secondo Campini but more commonly, motorjet, the air was compressed by a fan driven by a conventional piston engine. Examples of this type of design were the Caproni Campini N.1, and the Japanese Tsu-11 engine intended to power Ohka kamikaze planes towards the end of World War II. None were entirely successful and the N.1 ended up being slower than the same design with a traditional engine and propeller combination.
Even before the start of World War II, engineers were beginning to realize that engines driving propellers were self-limiting in terms of the maximum performance which could be attained; the limit was due to issues related to propeller efficiency,[2] which declined as blade tips approached the speed of sound. If aircraft performance were ever to increase beyond such a barrier, a way would have to be found to use a different propulsion mechanism. This was the motivation behind the development of the gas turbine engine, commonly called a "jet" engine.
The key to a practical jet engine was the gas turbine, used to extract energy from the engine itself to drive the compressor. The gas turbine was not an idea developed in the 1930s: the patent for a stationary turbine was granted to John Barber in England in 1791. The first gas turbine to successfully run self-sustaining was built in 1903 by Norwegian engineer Ægidius Elling.[3] Limitations in design and practical engineering and metallurgy prevented such engines reaching manufacture. The main problems were safety, reliability, weight and, especially, sustained operation.
The first patent for using a gas turbine to power an aircraft was filed in 1921 by Frenchman Maxime Guillaume.[4] His engine was an axial-flow turbojet. Alan Arnold Griffith published An Aerodynamic Theory of Turbine Design in 1926 leading to experimental work at the RAE.
In 1928, RAF College Cranwell cadet[5] Frank Whittle formally submitted his ideas for a turbojet to his superiors. In October 1929 he developed his ideas further.[6] On 16 January 1930 in England, Whittle submitted his first patent (granted in 1932).[7] The patent showed a two-stage axial compressor feeding a single-sided centrifugal compressor. Practical axial compressors were made possible by ideas from A.A.Griffith in a seminal paper in 1926 ("An Aerodynamic Theory of Turbine Design"). Whittle would later concentrate on the simpler centrifugal compressor only, for a variety of practical reasons. Whittle had his first engine running in April 1937. It was liquid-fuelled, and included a self-contained fuel pump. Whittle's team experienced near-panic when the engine would not stop, accelerating even after the fuel was switched off. It turned out that fuel had leaked into the engine and accumulated in pools, so the engine would not stop until all the leaked fuel had burned off. Whittle was unable to interest the government in his invention, and development continued at a slow pace.
In 1935 Hans von Ohain started work on a similar design in Germany, initially unaware of Whittle's work.[8]
Von Ohain's first device was strictly experimental and could run only under external power, but he was able to demonstrate the basic concept. Ohain was then introduced to Ernst Heinkel, one of the larger aircraft industrialists of the day, who immediately saw the promise of the design. Heinkel had recently purchased the Hirth engine company, and Ohain and his master machinist Max Hahn were set up there as a new division of the Hirth company. They had their first HeS 1 centrifugal engine running by September 1937. Unlike Whittle's design, Ohain used hydrogen as fuel, supplied under external pressure. Their subsequent designs culminated in the gasoline-fuelled HeS 3 of 1,100 lbf (5 kN), which was fitted to Heinkel's simple and compact He 178 airframe and flown by Erich Warsitz in the early morning of August 27, 1939, from Rostock-Marienehe aerodrome, an impressively short time for development. The He 178 was the world's first jet plane.[9]
Austrian Anselm Franz of Junkers' engine division (Junkers Motoren or "Jumo") introduced the axial-flow compressor in their jet engine. Jumo was assigned the next engine number in the RLM 109-0xx numbering sequence for gas turbine aircraft powerplants, "004", and the result was the Jumo 004 engine. After many lesser technical difficulties were solved, mass production of this engine started in 1944 as a powerplant for the world's first jet-fighter aircraft, the Messerschmitt Me 262 (and later the world's first jet-bomber aircraft, the Arado Ar 234). A variety of reasons conspired to delay the engine's availability, causing the fighter to arrive too late to improve Germany's position in World War II. Nonetheless, it will be remembered as the first use of jet engines in service.
Meanwhile, in Britain the Gloster E28/39 had its maiden flight on 15 May 1941 and the Gloster Meteor finally entered service with the RAF in July 1944.
Following the end of the war the German jet aircraft and jet engines were extensively studied by the victorious allies and contributed to work on early Soviet and US jet fighters. The legacy of the axial-flow engine is seen in the fact that practically all jet engines on fixed-wing aircraft have had some inspiration from this design.
By the 1950s the jet engine was almost universal in combat aircraft, with the exception of cargo, liaison and other specialty types. By this point some of the British designs were already cleared for civilian use, and had appeared on early models like the de Havilland Comet and Avro Canada Jetliner. By the 1960s all large civilian aircraft were also jet powered, leaving the piston engine in low-cost niche roles such as cargo flights.
The efficiency of turbojet engines was still rather worse than piston engines, but by the 1970s, with the advent of high-bypass turbofan jet engines (an innovation not foreseen by the early commentators such as Edgar Buckingham, at high speeds and high altitudes that seemed absurd to them), fuel efficiency was about the same as the best piston and propeller engines.[1]
Uses
Jet engines power aircraft, cruise missiles and unmanned aerial vehicles. In the form of rocket engines they power fireworks, model rocketry, spaceflight, and military missiles.
Jet engines have propelled high speed cars, particularly drag racers, with the all-time record held by a rocket car. A turbofan powered car, ThrustSSC, currently holds the land speed record.
Jet engine designs are frequently modified for non-aircraft applications, as industrial gas turbines or marine powerplants. These are used in electrical power generation, for powering water, natural gas, or oil pumps, and providing propulsion for ships and locomotives. Industrial gas turbines can create up to 50,000 shaft horsepower. Many of these engines are derived from older military turbojets such as the Pratt & Whitney J57 and J75 models. There is also a derivative of the P&W JT8D low-bypass turbofan that creates up to 35,000 HP.
Jet engines are also sometimes developed into, or share certain components such as engine cores, with turboshaft and turboprop engines, which are forms of gas turbine engines that are typically used to power helicopters and some propeller-driven aircraft..
Types
There are a large number of different types of jet engines, all of which achieve forward thrust from the principle of jet propulsion.
Airbreathing
Commonly aircraft are propelled by airbreathing jet engines. Most airbreathing jet engines that are in use are turbofan jet engines, which give good efficiency at speeds just below the speed of sound.
Turbine powered
Gas turbines are rotary engines that extract energy from a flow of combustion gas. They have an upstream compressor coupled to a downstream turbine with a combustion chamber in-between. In aircraft engines, those three core components are often called the "gas generator."[10] There are many different variations of gas turbines, but they all use a gas generator system of some type.
Turbojet
A turbojet engine is a gas turbine engine that works by compressing air with an inlet and a compressor (axial, centrifugal, or both), mixing fuel with the compressed air, burning the mixture in the combustor, and then passing the hot, high pressure air through a turbine and a nozzle. The compressor is powered by the turbine, which extracts energy from the expanding gas passing through it. The engine converts internal energy in the fuel to kinetic energy in the exhaust, producing thrust. All the air ingested by the inlet is passed through the compressor, combustor, and turbine, unlike the turbofan engine described below.[11]
Turbofan
A turbofan engine is a gas turbine engine that is very similar to a turbojet. Like a turbojet, it uses the gas generator core (compressor, combustor, turbine) to convert internal energy in fuel to kinetic energy in the exhaust. Turbofans differ from turbojets in that they have an additional component, a fan. Like the compressor, the fan is powered by the turbine section of the engine. Unlike the turbojet, some of the flow accelerated by the fan bypasses the gas generator core of the engine and is exhausted through a nozzle. The bypassed flow is at lower velocities, but a higher mass, making thrust produced by the fan more efficient than thrust produced by the core. Turbofans are generally more efficient than turbojets at subsonic speeds, but they have a larger frontal area which generates more drag.[12]
There are two general types of turbofan engines, low-bypass and high-bypass. Low-bypass turbofans have a bypass ratio of around 2:1 or less, meaning that for each kilogram of air that passes through the core of the engine, two kilograms or less of air bypass the core.[citation needed] Low-bypass turbofans often use a mixed exhaust nozzle meaning that the bypassed flow and the core flow exit from the same nozzle.[13] High-bypass turbofans have larger bypass ratios, sometimes on the order of 5:1 or 6:1. These turbofans can produce much more thrust than low-bypass turbofans or turbojets because of the large mass of air that the fan can accelerate, and are often more fuel efficient than low-bypass turbofans or turbojets.[citation needed]
Turboprop and turboshaft
Turboprop engines are jet engine derivatives, still gas turbines, that extract work from the hot-exhaust jet to turn a rotating shaft, which is then used to produce thrust by some other means. While not strictly jet engines in that they rely on an auxiliary mechanism to produce thrust, turboprops are very similar to other turbine-based jet engines, and are often described as such.
In turboprop engines, a portion of the engine's thrust is produced by spinning a propeller, rather than relying solely on high-speed jet exhaust. As their jet thrust is augmented by a propeller, turboprops are occasionally referred to as a type of hybrid jet engine. They are quite similar to turbofans in many respects, except that they use a traditional propeller to provide the majority of thrust, rather than a ducted fan. Both fans and propellers are powered the same way, although most turboprops use gear-reduction between the turbine and the propeller (geared turbofans also feature gear reduction). While many turboprops generate the majority of their thrust with the propeller, the hot-jet exhaust is an important design point, and maximum thrust is obtained by matching thrust contributions of the propeller to the hot jet.[14] Turboprops generally have better performance than turbojets or turbofans at low speeds where propeller efficiency is high, but become increasingly noisy and inefficient at high speeds.[15]
Turboshaft engines are very similar to turboprops, differing in that nearly all energy in the exhaust is extracted to spin the rotating shaft, which is used to power machinery rather than a propeller, they therefore generate little to no jet thrust and are often used to power helicopters.[13]
Propfan
A propfan engine (also called "unducted fan", "open rotor", or "ultra-high bypass") is a jet engine that uses its gas generator to power an exposed fan, similar to turboprop engines. Like turboprop engines, propfans generate most of their thrust from the propeller and not the exhaust jet. The primary difference between turboprop and propfan design is that the propeller blades on a propfan are highly swept to allow them to operate at speeds around Mach 0.8, which is competitive with modern commercial turbofans. These engines have the fuel efficiency advantages of turboprops with the performance capability of commercial turbofans.[16] While significant research and testing (including flight testing) has been conducted on propfans, no propfan engines have entered production.
Ram powered
Ram powered jet engines are airbreathing engines similar to gas turbine engines and they both follow the Brayton cycle. Gas turbine and ram powered engines differ, however, in how they compress the incoming airflow. Whereas gas turbine engines use axial or centrifugal compressors to compress incoming air, ram engines rely only on air compressed through the inlet or diffuser.[17] Ram powered engines are considered the most simple type of air breathing jet engine because they can contain no moving parts.[18]
Ramjet
Ramjets are the most basic type of ram powered jet engines. They consist of three sections; an inlet to compress incoming air, a combustor to inject and combust fuel, and a nozzle to expel the hot gases and produce thrust. Ramjets require a relatively high speed to efficiently compress the incoming air, so ramjets cannot operate at a standstill and they are most efficient at supersonic speeds. A key trait of ramjet engines is that combustion is done at subsonic speeds. The supersonic incoming air is dramatically slowed through the inlet, where it is then combusted at the much slower, subsonic, speeds.[17] The faster the incoming air is, however, the less efficient it becomes to slow it to subsonic speeds. Therefore, ramjet engines are limited to approximately Mach 5.[19]
Scramjet
Scramjets are mechanically very similar to ramjets. Like a ramjet, they consist of an inlet, a combustor, and a nozzle. The primary difference between ramjets and scramjets is that scramjets do not slow the oncoming airflow to subsonic speeds for combustion, they use supersonic combustion instead. The name "scramjet" comes from "supersonic combusting ramjet." Since scramjets use supersonic combustion they can operate at speeds above Mach 6 where traditional ramjets are too inefficient. Another difference between ramjets and scramjets comes from how each type of engine compresses the oncoming airflow: while the inlet provides most of the compression for ramjets, the high speeds at which scramjets operate allow them to take advantage of the compression generated by shock waves, primarily oblique shocks.[20]
Very few scramjet engines have ever been built and flown. In May 2010 the Boeing X-51 set the endurance record for the longest scramjet burn at over 200 seconds.[21]
Non-continuous combustion
Type | Description | Advantages | Disadvantages |
---|---|---|---|
Motorjet | Obsolete type that worked like a turbojet but instead of a turbine driving the compressor a piston engine drives it. | Higher exhaust velocity than a propeller, offering better thrust at high speed | Heavy, inefficient and underpowered. Example: Caproni Campini N.1. |
Pulsejet | Air is compressed and combusted intermittently instead of continuously. Some designs use valves. | Very simple design, commonly used on model aircraft | Noisy, inefficient (low compression ratio), works poorly on a large scale, valves on valved designs wear out quickly |
Pulse detonation engine | Similar to a pulsejet, but combustion occurs as a detonation instead of a deflagration, may or may not need valves | Maximum theoretical engine efficiency | Extremely noisy, parts subject to extreme mechanical fatigue, hard to start detonation, not practical for current use |
Rocket
The rocket engine uses the same basic physical principles as the jet engine for propulsion via thrust, but is distinct in that it does not require atmospheric air to provide oxygen; the rocket carries all components of the reaction mass. This allows them to operate at arbitrary altitudes and in space.
This type of engine is used for launching satellites, space exploration and manned access, and permitted landing on the moon in 1969.
Rocket engines are used for high altitude flights, or anywhere where very high accelerations are needed since rocket engines themselves have a very high thrust-to-weight ratio.
However, the high exhaust speed and the heavier, oxidizer-rich propellant results in far more propellant use than turbofans. Even so, at extremely high speeds they become energy-efficient.
An approximate equation for the net thrust of a rocket engine is:
Where is the net thrust, is the specific impulse, is a standard gravity, is the propellant flow in kg/s, is the cross-sectional area at the exit of the exhaust nozzle, and is the atmospheric pressure.
Type | Description | Advantages | Disadvantages |
---|---|---|---|
Rocket | Carries all propellants and oxidants on board, emits jet for propulsion[22] | Very few moving parts. Mach 0 to Mach 25+; efficient at very high speed (> Mach 5.0 or so). Thrust/weight ratio over 100. No complex air inlet. High compression ratio. Very high-speed (hypersonic) exhaust. Good cost/thrust ratio. Fairly easy to test. Works in a vacuum; indeed, works best outside the atmosphere, which is kinder on vehicle structure at high speed. Fairly small surface area to keep cool, and no turbine in hot exhaust stream. Very high-temperature combustion and high expansion-ratio nozzle gives very high efficiency, at very high speeds. | Needs lots of propellant. Very low specific impulse—typically 100–450 seconds. Extreme thermal stresses of combustion chamber can make reuse harder. Typically requires carrying oxidizer on-board which increases risks. Extraordinarily noisy. |
Hybrid
Combined cycle engines simultaneously use 2 or more different jet engine operating principles.
Type | Description | Advantages | Disadvantages |
---|---|---|---|
Turborocket | A turbojet where an additional oxidizer such as oxygen is added to the airstream to increase maximum altitude | Very close to existing designs, operates in very high altitude, wide range of altitude and airspeed | Airspeed limited to same range as turbojet engine, carrying oxidizer like LOX can be dangerous. Much heavier than simple rockets. |
Air-augmented rocket | Essentially a ramjet where intake air is compressed and burnt with the exhaust from a rocket | Mach 0 to Mach 4.5+ (can also run exoatmospheric), good efficiency at Mach 2 to 4 | Similar efficiency to rockets at low speed or exoatmospheric, inlet difficulties, a relatively undeveloped and unexplored type, cooling difficulties, very noisy, thrust/weight ratio is similar to ramjets. |
Precooled jets / LACE | Intake air is chilled to very low temperatures at inlet in a heat exchanger before passing through a ramjet and/or turbojet and/or rocket engine. | Easily tested on ground. Very high thrust/weight ratios are possible (~14) together with good fuel efficiency over a wide range of airspeeds, Mach 0-5.5+; this combination of efficiencies may permit launching to orbit, single stage, or very rapid, very long distance intercontinental travel. | Exists only at the lab prototyping stage. Examples include RB545, Reaction Engines SABRE, ATREX. Requires liquid hydrogen fuel which has very low density and requires heavily insulated tankage. |
Water jet
A water jet, or pump jet, is a marine propulsion system that utilizes a jet of water. The mechanical arrangement may be a ducted propeller with nozzle, or a centrifugal compressor and nozzle.
Type | Description | Advantages | Disadvantages |
---|---|---|---|
Water jet | For propelling water rockets and jetboats; squirts water out the back through a nozzle | In boats, can run in shallow water, high acceleration, no risk of engine overload (unlike propellers), less noise and vibration, highly maneuverable at all boat speeds, high speed efficiency, less vulnerable to damage from debris, very reliable, more load flexibility, less harmful to wildlife | Can be less efficient than a propeller at low speed, more expensive, higher weight in boat due to entrained water, will not perform well if boat is heavier than the jet is sized for |
General physical principles
All jet engines are reaction engines that generate thrust by emitting a jet of fluid rearwards at relatively high speed. The forces on the inside of the engine needed to create this jet give a strong thrust on the engine which pushes the craft forwards.
Jet engines make their jet from propellant from tankage that is attached to the engine (as in a 'rocket') as well as in duct engines (those commonly used on aircraft) by ingesting an external fluid (very typically air) and expelling it at higher speed.
Propelling nozzle
The propelling nozzle is the key component of all jet engines as it creates the exhaust jet. Propelling nozzles turn pressurized, slow moving, usually hot gas, into lower pressure, fast moving, colder gas by adiabatic expansion.[23] Propelling nozzles can be subsonic, sonic, or supersonic,[24] but in normal operation nozzles are usually sonic or supersonic. Nozzles operate to constrict the flow, and hence help raise the pressure in the engine, and physically the nozzles are very typically convergent, or convergent-divergent. Convergent-divergent nozzles can give supersonic jet velocity within the divergent section, whereas in a convergent nozzle the exhaust fluid cannot exceed the speed of sound of the gas within the nozzle.
Thrust
The net thrust (FN) of a turbojet is given by:[25]
where: | |
ṁ air | = the mass rate of air flow through the engine |
ṁ fuel | = the mass rate of fuel flow entering the engine |
ve | = the velocity of the jet (the exhaust plume) and is assumed to be less than sonic velocity |
v | = the velocity of the air intake = the true airspeed of the aircraft |
(ṁ air + ṁ fuel)ve | = the nozzle gross thrust (FG) |
ṁ air v | = the ram drag of the intake air |
The above equation applies only for air-breathing jet engines. It does not apply to rocket engines. Most types of jet engine have an air intake, which provides the bulk of the fluid exiting the exhaust. Conventional rocket engines, however, do not have an intake, the oxidizer and fuel both being carried within the vehicle. Therefore, rocket engines do not have ram drag and the gross thrust of the rocket engine nozzle is the net thrust of the engine. Consequently, the thrust characteristics of a rocket motor are different from that of an air breathing jet engine, and thrust is independent of velocity.
If the velocity of the jet from a jet engine is equal to sonic velocity, the jet engine's nozzle is said to be choked. If the nozzle is choked, the pressure at the nozzle exit plane is greater than atmospheric pressure, and extra terms must be added to the above equation to account for the pressure thrust.[25]
The rate of flow of fuel entering the engine is very small compared with the rate of flow of air.[25] If the contribution of fuel to the nozzle gross thrust is ignored, the net thrust is:
The velocity of the jet (ve) must exceed the true airspeed of the aircraft (v) if there is to be a net forward thrust on the aircraft. The velocity (ve) can be calculated thermodynamically based on adiabatic expansion.[26]
Thrust augmentation
Jet thrust can be increased by injecting additional fluids and it is then called wet thrust.[clarification needed] Early engines and some current non-afterburning engines use water injection to temporarily increase thrust. Water is injected at the air compressor inlet or the diffuser to cool the compressing air which permits an increase in pressure for higher burning. A 10 to 30% additional thrust can thus be gained. Methyl or ethyl alcohol (or a mixture of one or both of these with water) has been used in the past for injection. However, water has a higher heat of evaporation, and is therefore the only liquid generally used for thrust augmentation today.
Today's military combat engines use an afterburner for increased thrust.
Energy efficiency
The energy efficiency () of jet engines installed in vehicles has two main components:
- propulsive efficiency (): how much of the energy of the jet ends up in the vehicle body rather than being carried away as kinetic energy of the jet.
- cycle efficiency (): how efficiently the engine can accelerate the jet
Even though overall energy efficiency is simply:
for all jet engines the propulsive efficiency is highest when the engine emits an exhaust jet at a velocity that is the same as, or nearly the same as, the vehicle speed as this gives the smallest residual kinetic energy.[27] The formula for air-breathing engines moving at speed with an exhaust velocity , and neglecting fuel flow, is:[28]
And for a rocket:[29]
In addition to propulsive efficiency, another factor is cycle efficiency; essentially a jet engine is typically a form of heat engine. Heat engine efficiency is determined by the ratio of temperatures reached in the engine to that exhausted at the nozzle. This improves constantly over time as new materials are introduced into the design. For example, composite materials, combining metals with ceramics, are being used in fan blades in the first stage, which is the most critical stage.[30] The efficiency is also limited by the overall pressure ratio that can be achieved. Cycle efficiency is highest in rocket engines (~60+%), as they can achieve extremely high combustion temperatures. Cycle efficiency in turbojet and similar is nearer to 30%, due to much lower peak cycle temperatures.
The combustion efficiency of most aircraft gas turbine engines at sea level takeoff conditions is almost 100%. It decreases nonlinear to 98% at altitude cruise conditions. Air-fuel ratio ranges from 50:1 to 130:1. For any type of combustion chamber there is a rich and weak limit to the air-fuel ratio, beyond which the flame is extinguished. The range of air-fuel ratio between the rich and weak limits is reduced with an increase of air velocity. If the increasing air mass flow reduces the fuel ratio below certain value, flame extinction occurs.[31]
In aircraft turbines, the regular fuel ratio is less than the most efficient fuel ratio of 15%. Therefore, only a part of the air is being used in the combustion process. Part of the fuel isn't completely burned, leaving a mix of carbon monoxide, soot, and hydrocarbon behind. At idle these amount to 50-2000 ppm, and decreases during cruising to 1-50 ppm. That is why the air around airports is bad.[32]
Consumption of fuel or propellant
A closely related (but different) concept to energy efficiency is the rate of consumption of propellant mass. Propellant consumption in jet engines is measured by Specific Fuel Consumption, Specific impulse or Effective exhaust velocity. They all measure the same thing. Specific impulse and effective exhaust velocity are strictly proportional, whereas specific fuel consumption is inversely proportional to the others.
For airbreathing engines such as turbojets, energy efficiency and propellant (fuel) efficiency are much the same thing, since the propellant is a fuel and the source of energy. In rocketry, the propellant is also the exhaust, and this means that a high energy propellant gives better propellant efficiency but can in some cases actually give lower energy efficiency.
It can be seen in the table (just below) that the subsonic turbofans such as General Electric's CF6 turbofan use a lot less fuel to generate thrust for a second than did the Concorde's Rolls-Royce/Snecma Olympus 593 turbojet. However, since energy is force times distance and the distance per second was greater for Concorde, the actual power generated by the engine for the same amount of fuel was higher for Concorde at Mach 2 than the CF6. Thus, the Concorde's engines were more efficient in terms of thrust per mile.
Rocket engines in vacuum | |||||||
---|---|---|---|---|---|---|---|
Model | Type | First run |
Application | TSFC | Isp (by weight) | Isp (by mass) | |
lb/lbf·h | g/kN·s | s | m/s | ||||
Avio P80 | solid fuel | 2006 | Vega stage 1 | 13 | 360 | 280 | 2700 |
Avio Zefiro 23 | solid fuel | 2006 | Vega stage 2 | 12.52 | 354.7 | 287.5 | 2819 |
Avio Zefiro 9A | solid fuel | 2008 | Vega stage 3 | 12.20 | 345.4 | 295.2 | 2895 |
Merlin 1D | liquid fuel | 2013 | Falcon 9 | 12 | 330 | 310 | 3000 |
RD-843 | liquid fuel | Vega upper stage | 11.41 | 323.2 | 315.5 | 3094 | |
Kuznetsov NK-33 | liquid fuel | 1970s | N-1F, Soyuz-2-1v stage 1 | 10.9 | 308 | 331[33] | 3250 |
NPO Energomash RD-171M | liquid fuel | Zenit-2M, -3SL, -3SLB, -3F stage 1 | 10.7 | 303 | 337 | 3300 | |
LE-7A | cryogenic | H-IIA, H-IIB stage 1 | 8.22 | 233 | 438 | 4300 | |
Snecma HM-7B | cryogenic | Ariane 2, 3, 4, 5 ECA upper stage | 8.097 | 229.4 | 444.6 | 4360 | |
LE-5B-2 | cryogenic | H-IIA, H-IIB upper stage | 8.05 | 228 | 447 | 4380 | |
Aerojet Rocketdyne RS-25 | cryogenic | 1981 | Space Shuttle, SLS stage 1 | 7.95 | 225 | 453[34] | 4440 |
Aerojet Rocketdyne RL-10B-2 | cryogenic | Delta III, Delta IV, SLS upper stage | 7.734 | 219.1 | 465.5 | 4565 | |
NERVA NRX A6 | nuclear | 1967 | 869 |
Jet engines with Reheat, static, sea level | |||||||
---|---|---|---|---|---|---|---|
Model | Type | First run |
Application | TSFC | Isp (by weight) | Isp (by mass) | |
lb/lbf·h | g/kN·s | s | m/s | ||||
Turbo-Union RB.199 | turbofan | Tornado | 2.5[35] | 70.8 | 1440 | 14120 | |
GE F101-GE-102 | turbofan | 1970s | B-1B | 2.46 | 70 | 1460 | 14400 |
Tumansky R-25-300 | turbojet | MIG-21bis | 2.206[35] | 62.5 | 1632 | 16000 | |
GE J85-GE-21 | turbojet | F-5E/F | 2.13[35] | 60.3 | 1690 | 16570 | |
GE F110-GE-132 | turbofan | F-16E/F | 2.09[35] | 59.2 | 1722 | 16890 | |
Honeywell/ITEC F125 | turbofan | F-CK-1 | 2.06[35] | 58.4 | 1748 | 17140 | |
Snecma M53-P2 | turbofan | Mirage 2000C/D/N | 2.05[35] | 58.1 | 1756 | 17220 | |
Snecma Atar 09C | turbojet | Mirage III | 2.03[35] | 57.5 | 1770 | 17400 | |
Snecma Atar 09K-50 | turbojet | Mirage IV, 50, F1 | 1.991[35] | 56.4 | 1808 | 17730 | |
GE J79-GE-15 | turbojet | F-4E/EJ/F/G, RF-4E | 1.965 | 55.7 | 1832 | 17970 | |
Saturn AL-31F | turbofan | Su-27/P/K | 1.96[36] | 55.5 | 1837 | 18010 | |
GE F110-GE-129 | turbofan | F-16C/D, F-15EX | 1.9[35] | 53.8 | 1895 | 18580 | |
Soloviev D-30F6 | turbofan | MiG-31, S-37/Su-47 | 1.863[35] | 52.8 | 1932 | 18950 | |
Lyulka AL-21F-3 | turbojet | Su-17, Su-22 | 1.86[35] | 52.7 | 1935 | 18980 | |
Klimov RD-33 | turbofan | 1974 | MiG-29 | 1.85 | 52.4 | 1946 | 19080 |
Saturn AL-41F-1S | turbofan | Su-35S/T-10BM | 1.819 | 51.5 | 1979 | 19410 | |
Volvo RM12 | turbofan | 1978 | Gripen A/B/C/D | 1.78[35] | 50.4 | 2022 | 19830 |
GE F404-GE-402 | turbofan | F/A-18C/D | 1.74[35] | 49 | 2070 | 20300 | |
Kuznetsov NK-32 | turbofan | 1980 | Tu-144LL, Tu-160 | 1.7 | 48 | 2100 | 21000 |
Snecma M88-2 | turbofan | 1989 | Rafale | 1.663 | 47.11 | 2165 | 21230 |
Eurojet EJ200 | turbofan | 1991 | Eurofighter | 1.66–1.73 | 47–49[37] | 2080–2170 | 20400–21300 |
Dry jet engines, static, sea level | |||||||
---|---|---|---|---|---|---|---|
Model | Type | First run |
Application | TSFC | Isp (by weight) | Isp (by mass) | |
lb/lbf·h | g/kN·s | s | m/s | ||||
GE J85-GE-21 | turbojet | F-5E/F | 1.24[35] | 35.1 | 2900 | 28500 | |
Snecma Atar 09C | turbojet | Mirage III | 1.01[35] | 28.6 | 3560 | 35000 | |
Snecma Atar 09K-50 | turbojet | Mirage IV, 50, F1 | 0.981[35] | 27.8 | 3670 | 36000 | |
Snecma Atar 08K-50 | turbojet | Super Étendard | 0.971[35] | 27.5 | 3710 | 36400 | |
Tumansky R-25-300 | turbojet | MIG-21bis | 0.961[35] | 27.2 | 3750 | 36700 | |
Lyulka AL-21F-3 | turbojet | Su-17, Su-22 | 0.86 | 24.4 | 4190 | 41100 | |
GE J79-GE-15 | turbojet | F-4E/EJ/F/G, RF-4E | 0.85 | 24.1 | 4240 | 41500 | |
Snecma M53-P2 | turbofan | Mirage 2000C/D/N | 0.85[35] | 24.1 | 4240 | 41500 | |
Volvo RM12 | turbofan | 1978 | Gripen A/B/C/D | 0.824[35] | 23.3 | 4370 | 42800 |
RR Turbomeca Adour | turbofan | 1999 | Jaguar retrofit | 0.81 | 23 | 4400 | 44000 |
Honeywell/ITEC F124 | turbofan | 1979 | L-159, X-45 | 0.81[35] | 22.9 | 4440 | 43600 |
Honeywell/ITEC F125 | turbofan | F-CK-1 | 0.8[35] | 22.7 | 4500 | 44100 | |
PW J52-P-408 | turbojet | A-4M/N, TA-4KU, EA-6B | 0.79 | 22.4 | 4560 | 44700 | |
Saturn AL-41F-1S | turbofan | Su-35S/T-10BM | 0.79 | 22.4 | 4560 | 44700 | |
Snecma M88-2 | turbofan | 1989 | Rafale | 0.782 | 22.14 | 4600 | 45100 |
Klimov RD-33 | turbofan | 1974 | MiG-29 | 0.77 | 21.8 | 4680 | 45800 |
RR Pegasus 11-61 | turbofan | AV-8B+ | 0.76 | 21.5 | 4740 | 46500 | |
Eurojet EJ200 | turbofan | 1991 | Eurofighter | 0.74–0.81 | 21–23[37] | 4400–4900 | 44000–48000 |
GE F414-GE-400 | turbofan | 1993 | F/A-18E/F | 0.724[38] | 20.5 | 4970 | 48800 |
Kuznetsov NK-32 | turbofan | 1980 | Tu-144LL, Tu-160 | 0.72-0.73 | 20–21 | 4900–5000 | 48000–49000 |
Soloviev D-30F6 | turbofan | MiG-31, S-37/Su-47 | 0.716[35] | 20.3 | 5030 | 49300 | |
Snecma Larzac | turbofan | 1972 | Alpha Jet | 0.716 | 20.3 | 5030 | 49300 |
IHI F3 | turbofan | 1981 | Kawasaki T-4 | 0.7 | 19.8 | 5140 | 50400 |
Saturn AL-31F | turbofan | Su-27 /P/K | 0.666-0.78[36][38] | 18.9–22.1 | 4620–5410 | 45300–53000 | |
RR Spey RB.168 | turbofan | AMX | 0.66[35] | 18.7 | 5450 | 53500 | |
GE F110-GE-129 | turbofan | F-16C/D, F-15 | 0.64[38] | 18 | 5600 | 55000 | |
GE F110-GE-132 | turbofan | F-16E/F | 0.64[38] | 18 | 5600 | 55000 | |
Turbo-Union RB.199 | turbofan | Tornado ECR | 0.637[35] | 18.0 | 5650 | 55400 | |
PW F119-PW-100 | turbofan | 1992 | F-22 | 0.61[38] | 17.3 | 5900 | 57900 |
Turbo-Union RB.199 | turbofan | Tornado | 0.598[35] | 16.9 | 6020 | 59000 | |
GE F101-GE-102 | turbofan | 1970s | B-1B | 0.562 | 15.9 | 6410 | 62800 |
PW TF33-P-3 | turbofan | B-52H, NB-52H | 0.52[35] | 14.7 | 6920 | 67900 | |
RR AE 3007H | turbofan | RQ-4, MQ-4C | 0.39[35] | 11.0 | 9200 | 91000 | |
GE F118-GE-100 | turbofan | 1980s | B-2 | 0.375[35] | 10.6 | 9600 | 94000 |
GE F118-GE-101 | turbofan | 1980s | U-2S | 0.375[35] | 10.6 | 9600 | 94000 |
General Electric CF6-50C2 | turbofan | A300, DC-10-30 | 0.371[35] | 10.5 | 9700 | 95000 | |
GE TF34-GE-100 | turbofan | A-10 | 0.37[35] | 10.5 | 9700 | 95000 | |
CFM CFM56-2B1 | turbofan | C-135, RC-135 | 0.36[39] | 10 | 10000 | 98000 | |
Progress D-18T | turbofan | 1980 | An-124, An-225 | 0.345 | 9.8 | 10400 | 102000 |
PW F117-PW-100 | turbofan | C-17 | 0.34[40] | 9.6 | 10600 | 104000 | |
PW PW2040 | turbofan | Boeing 757 | 0.33[40] | 9.3 | 10900 | 107000 | |
CFM CFM56-3C1 | turbofan | 737 Classic | 0.33 | 9.3 | 11000 | 110000 | |
GE CF6-80C2 | turbofan | 744, 767, MD-11, A300/310, C-5M | 0.307-0.344 | 8.7–9.7 | 10500–11700 | 103000–115000 | |
EA GP7270 | turbofan | A380-861 | 0.299[38] | 8.5 | 12000 | 118000 | |
GE GE90-85B | turbofan | 777-200/200ER/300 | 0.298[38] | 8.44 | 12080 | 118500 | |
GE GE90-94B | turbofan | 777-200/200ER/300 | 0.2974[38] | 8.42 | 12100 | 118700 | |
RR Trent 970-84 | turbofan | 2003 | A380-841 | 0.295[38] | 8.36 | 12200 | 119700 |
GE GEnx-1B70 | turbofan | 787-8 | 0.2845[38] | 8.06 | 12650 | 124100 | |
RR Trent 1000C | turbofan | 2006 | 787-9 | 0.273[38] | 7.7 | 13200 | 129000 |
Jet engines, cruise | |||||||
---|---|---|---|---|---|---|---|
Model | Type | First run |
Application | TSFC | Isp (by weight) | Isp (by mass) | |
lb/lbf·h | g/kN·s | s | m/s | ||||
Ramjet | Mach 1 | 4.5 | 130 | 800 | 7800 | ||
J-58 | turbojet | 1958 | SR-71 at Mach 3.2 (Reheat) | 1.9[35] | 53.8 | 1895 | 18580 |
RR/Snecma Olympus | turbojet | 1966 | Concorde at Mach 2 | 1.195[41] | 33.8 | 3010 | 29500 |
PW JT8D-9 | turbofan | 737 Original | 0.8[42] | 22.7 | 4500 | 44100 | |
Honeywell ALF502R-5 | GTF | BAe 146 | 0.72[40] | 20.4 | 5000 | 49000 | |
Soloviev D-30KP-2 | turbofan | Il-76, Il-78 | 0.715 | 20.3 | 5030 | 49400 | |
Soloviev D-30KU-154 | turbofan | Tu-154M | 0.705 | 20.0 | 5110 | 50100 | |
RR Tay RB.183 | turbofan | 1984 | Fokker 70, Fokker 100 | 0.69 | 19.5 | 5220 | 51200 |
GE CF34-3 | turbofan | 1982 | Challenger, CRJ100/200 | 0.69 | 19.5 | 5220 | 51200 |
GE CF34-8E | turbofan | E170/175 | 0.68 | 19.3 | 5290 | 51900 | |
Honeywell TFE731-60 | GTF | Falcon 900 | 0.679[43] | 19.2 | 5300 | 52000 | |
CFM CFM56-2C1 | turbofan | DC-8 Super 70 | 0.671[40] | 19.0 | 5370 | 52600 | |
GE CF34-8C | turbofan | CRJ700/900/1000 | 0.67-0.68 | 19–19 | 5300–5400 | 52000–53000 | |
CFM CFM56-3C1 | turbofan | 737 Classic | 0.667 | 18.9 | 5400 | 52900 | |
CFM CFM56-2A2 | turbofan | 1974 | E-3, E-6 | 0.66[39] | 18.7 | 5450 | 53500 |
RR BR725 | turbofan | 2008 | G650/ER | 0.657 | 18.6 | 5480 | 53700 |
CFM CFM56-2B1 | turbofan | C-135, RC-135 | 0.65[39] | 18.4 | 5540 | 54300 | |
GE CF34-10A | turbofan | ARJ21 | 0.65 | 18.4 | 5540 | 54300 | |
CFE CFE738-1-1B | turbofan | 1990 | Falcon 2000 | 0.645[40] | 18.3 | 5580 | 54700 |
RR BR710 | turbofan | 1995 | G. V/G550, Global Express | 0.64 | 18 | 5600 | 55000 |
GE CF34-10E | turbofan | E190/195 | 0.64 | 18 | 5600 | 55000 | |
General Electric CF6-50C2 | turbofan | A300B2/B4/C4/F4, DC-10-30 | 0.63[40] | 17.8 | 5710 | 56000 | |
PowerJet SaM146 | turbofan | Superjet LR | 0.629 | 17.8 | 5720 | 56100 | |
CFM CFM56-7B24 | turbofan | 737 NG | 0.627[40] | 17.8 | 5740 | 56300 | |
RR BR715 | turbofan | 1997 | 717 | 0.62 | 17.6 | 5810 | 56900 |
GE CF6-80C2-B1F | turbofan | 747-400 | 0.605[41] | 17.1 | 5950 | 58400 | |
CFM CFM56-5A1 | turbofan | A320 | 0.596 | 16.9 | 6040 | 59200 | |
Aviadvigatel PS-90A1 | turbofan | Il-96-400 | 0.595 | 16.9 | 6050 | 59300 | |
PW PW2040 | turbofan | 757-200 | 0.582[40] | 16.5 | 6190 | 60700 | |
PW PW4098 | turbofan | 777-300 | 0.581[40] | 16.5 | 6200 | 60800 | |
GE CF6-80C2-B2 | turbofan | 767 | 0.576[40] | 16.3 | 6250 | 61300 | |
IAE V2525-D5 | turbofan | MD-90 | 0.574[44] | 16.3 | 6270 | 61500 | |
IAE V2533-A5 | turbofan | A321-231 | 0.574[44] | 16.3 | 6270 | 61500 | |
RR Trent 700 | turbofan | 1992 | A330 | 0.562[45] | 15.9 | 6410 | 62800 |
RR Trent 800 | turbofan | 1993 | 777-200/200ER/300 | 0.560[45] | 15.9 | 6430 | 63000 |
Progress D-18T | turbofan | 1980 | An-124, An-225 | 0.546 | 15.5 | 6590 | 64700 |
CFM CFM56-5B4 | turbofan | A320-214 | 0.545 | 15.4 | 6610 | 64800 | |
CFM CFM56-5C2 | turbofan | A340-211 | 0.545 | 15.4 | 6610 | 64800 | |
RR Trent 500 | turbofan | 1999 | A340-500/600 | 0.542[45] | 15.4 | 6640 | 65100 |
CFM LEAP-1B | turbofan | 2014 | 737 MAX | 0.53-0.56 | 15–16 | 6400–6800 | 63000–67000 |
Aviadvigatel PD-14 | turbofan | 2014 | MC-21-310 | 0.526 | 14.9 | 6840 | 67100 |
RR Trent 900 | turbofan | 2003 | A380 | 0.522[45] | 14.8 | 6900 | 67600 |
GE GE90-85B | turbofan | 777-200/200ER | 0.52[40][46] | 14.7 | 6920 | 67900 | |
GE GEnx-1B76 | turbofan | 2006 | 787-10 | 0.512[42] | 14.5 | 7030 | 69000 |
PW PW1400G | GTF | MC-21 | 0.51[47] | 14.4 | 7100 | 69000 | |
CFM LEAP-1C | turbofan | 2013 | C919 | 0.51 | 14.4 | 7100 | 69000 |
CFM LEAP-1A | turbofan | 2013 | A320neo family | 0.51[47] | 14.4 | 7100 | 69000 |
RR Trent 7000 | turbofan | 2015 | A330neo | 0.506[a] | 14.3 | 7110 | 69800 |
RR Trent 1000 | turbofan | 2006 | 787 | 0.506[b] | 14.3 | 7110 | 69800 |
RR Trent XWB-97 | turbofan | 2014 | A350-1000 | 0.478[c] | 13.5 | 7530 | 73900 |
PW 1127G | GTF | 2012 | A320neo | 0.463[42] | 13.1 | 7780 | 76300 |
Thrust-to-weight ratio
The thrust-to-weight ratio of jet engines of similar principles varies somewhat with scale, but is mostly a function of engine construction technology. Clearly for a given engine, the lighter the engine, the better the thrust-to-weight is, the less fuel is used to compensate for drag due to the lift needed to carry the engine weight, or to accelerate the mass of the engine.
As can be seen in the following table, rocket engines generally achieve very much higher thrust-to-weight ratios than duct engines such as turbojet and turbofan engines. This is primarily because rockets almost universally use dense liquid or solid reaction mass which gives a much smaller volume and hence the pressurisation system that supplies the nozzle is much smaller and lighter for the same performance. Duct engines have to deal with air which is two to three orders of magnitude less dense and this gives pressures over much larger areas, which in turn results in more engineering materials being needed to hold the engine together and for the air compressor.
Jet or rocket engine | Mass | Thrust | Thrust-to- weight ratio | ||
---|---|---|---|---|---|
(kg) | (lb) | (kN) | (lbf) | ||
RD-0410 nuclear rocket engine[48][49] | 2,000 | 4,400 | 35.2 | 7,900 | 1.8 |
J58 jet engine (SR-71 Blackbird)[50][51] | 2,722 | 6,001 | 150 | 34,000 | 5.2 |
Rolls-Royce/Snecma Olympus 593 turbojet with reheat (Concorde)[52] |
3,175 | 7,000 | 169.2 | 38,000 | 5.4 |
Pratt & Whitney F119[53] | 1,800 | 3,900 | 91 | 20,500 | 7.95 |
RD-0750 rocket engine, three-propellant mode[54] | 4,621 | 10,188 | 1,413 | 318,000 | 31.2 |
RD-0146 rocket engine[55] | 260 | 570 | 98 | 22,000 | 38.4 |
Rocketdyne RS-25 rocket engine[56] | 3,177 | 7,004 | 2,278 | 512,000 | 73.1 |
RD-180 rocket engine[57] | 5,393 | 11,890 | 4,152 | 933,000 | 78.5 |
RD-170 rocket engine | 9,750 | 21,500 | 7,887 | 1,773,000 | 82.5 |
F-1 (Saturn V first stage)[58] | 8,391 | 18,499 | 7,740.5 | 1,740,100 | 94.1 |
NK-33 rocket engine[59] | 1,222 | 2,694 | 1,638 | 368,000 | 136.7 |
Merlin 1D rocket engine, full-thrust version | 467 | 1,030 | 825 | 185,000 | 180.1 |
Comparison of types
Propeller engines are useful for comparison. They accelerate a large mass of air but by a relatively small maximum change in speed. This low speed limits the maximum thrust of any propeller driven airplane. However, because they accelerate a large mass of air, propeller engines, such as turboprops, can be very efficient.
On the other hand, turbojets accelerate a much smaller mass of intake air and burned fuel, but they emit it at the much higher speeds which are made possible by using a de Laval nozzle to accelerate the engine exhaust. This is why they are suitable for aircraft traveling at supersonic and higher speeds.
Turbofans have a mixed exhaust consisting of the bypass air and the hot combustion product gas from the core engine. The amount of air that bypasses the core engine compared to the amount flowing into the engine determines what is called a turbofan’s bypass ratio (BPR).
While a turbojet engine uses all of the engine's output to produce thrust in the form of a hot high-velocity exhaust gas jet, a turbofan's cool low-velocity bypass air yields between 30 percent and 70 percent of the total thrust produced by a turbofan system.[60]
The net thrust (FN) generated by a turbofan is:[61]
where:
ṁ e | = the mass rate of hot combustion exhaust flow from the core engine |
ṁo | = the mass rate of total air flow entering the turbofan = ṁc + ṁf |
ṁc | = the mass rate of intake air that flows to the core engine |
ṁf | = the mass rate of intake air that bypasses the core engine |
vf | = the velocity of the air flow bypassed around the core engine |
ve | = the velocity of the hot exhaust gas from the core engine |
vo | = the velocity of the total air intake = the true airspeed of the aircraft |
BPR | = Bypass Ratio |
Rocket engines have extremely high exhaust velocity and thus are best suited for high speeds (hypersonic) and great altitudes. At any given throttle, the thrust and efficiency of a rocket motor improves slightly with increasing altitude (because the back-pressure falls thus increasing net thrust at the nozzle exit plane), whereas with a turbojet (or turbofan) the falling density of the air entering the intake (and the hot gases leaving the nozzle) causes the net thrust to decrease with increasing altitude. Rocket engines are more efficient than even scramjets above roughly Mach 15.[62]
Altitude and speed
With the exception of scramjets, jet engines, deprived of their inlet systems can only accept air at around half the speed of sound. The inlet system's job for transonic and supersonic aircraft is to slow the air and perform some of the compression.
The limit on maximum altitude for engines is set by flammability- at very high altitudes the air becomes too thin to burn, or after compression, too hot. For turbojet engines altitudes of about 40 km appear to be possible, whereas for ramjet engines 55 km may be achievable. Scramjets may theoretically manage 75 km.[63] Rocket engines of course have no upper limit.
At more modest altitudes, flying faster compresses the air at the front of the engine, and this greatly heats the air. The upper limit is usually thought to be about Mach 5-8, as above about Mach 5.5, the atmospheric nitrogen tends to react due to the high temperatures at the inlet and this consumes significant energy. The exception to this is scramjets which may be able to achieve about Mach 15 or more[citation needed], as they avoid slowing the air, and rockets again have no particular speed limit.
Noise
The noise emitted by a jet engine has many sources. These include, in the case of gas turbine engines, the fan, compressor, combustor, turbine and propelling jet/s.[64]
The propelling jet produces jet noise which is caused by the violent mixing action of the high speed jet with the surrounding air. In the subsonic case the noise is produced by eddies and in the supersonic case by Mach waves.[65] The sound power radiated from a jet varies with the jet velocity raised to the eighth power for velocities up to 2,000 ft/sec and varies with the velocity cubed above 2,000 ft/sec.[66] Thus, the lower speed exhaust jets emitted from engines such as high bypass turbofans are the quietest, whereas the fastest jets, such as rockets, turbojets, and ramjets, are the loudest. For commercial jet aircraft the jet noise has reduced from the turbojet through bypass engines to turbofans as a result of a progressive reduction in propelling jet velocities. For example, the JT8D, a bypass engine, has a jet velocity of 1450 ft/sec whereas the JT9D, a turbofan, has jet velocities of 885 ft/sec (cold) and 1190 ft/sec (hot).[67]
The advent of the turbofan replaced the very distinctive jet noise with another sound known as "buzz saw" noise. The origin is the shockwaves originating at the supersonic fan blades at takeoff thrust.[68]
See also
- Air turboramjet
- Balancing machine
- Jet engine performance
- Reverse thrust
- Jetboat
- Variable Cycle Engine
- Pulse jet
- Turborocket
- Rocket turbine engine
- Rocket engine nozzles
- Spacecraft propulsion
- Water injection (engines)
- Turbojet development at the RAE
- Components of jet engines
- Turboprop
- Turboshaft
- Turbofan
- Turbojet
- Gas turbine
References
Notes
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- ^ Maxime Guillaume, "Propulseur par réaction sur l'air," French patent no. 534,801 (filed: 3 May 1921; issued: 13 January 1922). Available on-line (in French) at: http://v3.espacenet.com/origdoc?DB=EPODOC&IDX=FR534801&F=0&QPN=FR534801 .
- ^ "Chasing the Sun - Frank Whittle". PBS. Retrieved 2010-03-26.
- ^ "History - Frank Whittle (1907 - 1996)". BBC. Retrieved 2010-03-26.
- ^ Frank Whittle, "Improvements relating to the propulsion of aircraft and other vehicles," British patent no. 347,206 (filed: 16 January 1930). Available on-line at: http://v3.espacenet.com/origdoc?DB=EPODOC&IDX=GB347206&F=0&QPN=GB347206 .
- ^ The History of the Jet Engine - Sir Frank Whittle - Hans Von Ohain Ohain said that he had not read Whittle's patent and Whittle believed him. (Frank Whittle 1907-1996).
- ^ Warsitz, Lutz: THE FIRST JET PILOT - The Story of German Test Pilot Erich Warsitz (p. 125), Pen and Sword Books Ltd., England, 2009
- ^ Mattingly, Jack D. (2006). Elements of Propulsion: Gas Turbines and Rockets. AIAA Education Series. Reston, VA: American Institute of Aeronautics and Astronautics. p. 6. ISBN 1-56347-779-3.
- ^ Mattingly, pp. 6-8
- ^ Mattingly, pp. 9-11
- ^ a b Mattingly, p. 12
- ^ Hill & Peterson 1992, pp. 190.
- ^ Mattingly 2006, pp. 12–14.
- ^ Sweetman, Bill (2005). The Short, Happy Life of the Prop-fan. Air & Space Magazine. 1 September 2005.
- ^ a b Mattingly, p. 14
- ^ *Flack, Ronald D. (2005). Fundamentals of Jet Propulsion with Applications. Cambridge Aerospace Series. New York, NY: Cambridge University Press. p. 16. ISBN 978-0-521-81983-1.
- ^ Benson, Tom. Ramjet Propulsion. NASA Glenn Research Center. Updated: 11 July 2008. Retrieved: 23 July 2010.
- ^ Heiser, William H.; Pratt, David T. (1994). Hypersonic Airbreathing Propulsion. AIAA Education Series. Washington, D.C.: American Institute of Aeronautics and Astronautics. pp. 23–4. ISBN 1-56347-035-7.
- ^ X-51 Waverider makes historic hypersonic flight. United States Air Force. 26 May 2010. Retrieved: 23 July 2010.
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- ^ GFC Rogers, and Cohen, H. Gas Turbine Theory, p.108 (5th Edition), HIH Saravanamuttoo
- ^ Rocket propulsion elements, Sutton, Biblarz- table 3-1
- ^ a b c Nicholas Cumpsty (2003). Jet Propulsion (2nd ed.). Cambridge University Press. ISBN 0-521-54144-1.
- ^ 16.Unified: Thermodynamics and Propulsion, Prof. Z. S. Spakovszky. Scroll down to "Performance of Turbojet Engines, Section 11.6.4. (Obtained from the website of the Massachusetts Institute of Technology)
- ^ Note: In Newtonian mechanics kinetic energy is frame dependent. The kinetic energy is easiest to calculate when the speed is measured in the center of mass frame of the vehicle and (less obviously) its reaction mass / air (i.e., the stationary frame before takeoff begins.
- ^ "Jet Propulsion" Nicholas Cumpsty ISBN 0 521 59674 2 p24
- ^ George P. Sutton and Oscar Biblarz (2001). Rocket Propulsion Elements (7th ed.). John Wiley & Sons. pp. 37–38. ISBN 0-471-32642-9.
- ^ S. Walston, A. Cetel, R. MacKay, K. O’Hara, D. Duhl, and R. Dreshfield (2004). Joint Development of a Fourth Generation Single Crystal Superalloy. NASA TM—2004-213062. December 2004. Retrieved: 16 June 2010.
- ^ Claire Soares, "Gas Turbines: A Handbook of Air, Land and Sea Applications", pp. 140.
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- ^ "NK33". Encyclopedia Astronautica.
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- ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag Nathan Meier (21 Mar 2005). "Military Turbojet/Turbofan Specifications". Archived from the original on 11 February 2021.
- ^ a b "Flanker". AIR International Magazine. 23 March 2017.
- ^ a b "EJ200 turbofan engine" (PDF). MTU Aero Engines. April 2016.
- ^ a b c d e f g h i j k Kottas, Angelos T.; Bozoudis, Michail N.; Madas, Michael A. "Turbofan Aero-Engine Efficiency Evaluation: An Integrated Approach Using VSBM Two-Stage Network DEA" (PDF). doi:10.1016/j.omega.2019.102167.
- ^ a b c Élodie Roux (2007). "Turbofan and Turbojet Engines: Database Handbook" (PDF). p. 126. ISBN 9782952938013.
- ^ a b c d e f g h i j k Nathan Meier (3 Apr 2005). "Civil Turbojet/Turbofan Specifications". Archived from the original on 17 August 2021.
- ^ a b Ilan Kroo. "Data on Large Turbofan Engines". Aircraft Design: Synthesis and Analysis. Stanford University. Archived from the original on 11 January 2017.
- ^ a b c David Kalwar (2015). "Integration of turbofan engines into the preliminary design of a high-capacity short-and medium-haul passenger aircraft and fuel efficiency analysis with a further developed parametric aircraft design software" (PDF).
- ^ "Purdue School of Aeronautics and Astronautics Propulsion Web Page - TFE731".
- ^ a b Lloyd R. Jenkinson & al. (30 Jul 1999). "Civil Jet Aircraft Design: Engine Data File". Elsevier/Butterworth-Heinemann.
- ^ a b c d "Gas Turbine Engines" (PDF). Aviation Week. 28 January 2008. pp. 137–138.
- ^ Élodie Roux (2007). "Turbofan and Turbojet Engines: Database Handbook". ISBN 9782952938013.
- ^ a b Vladimir Karnozov (August 19, 2019). "Aviadvigatel Mulls Higher-thrust PD-14s To Replace PS-90A". AIN Online.
- ^ Wade, Mark. "RD-0410". Encyclopedia Astronautica. Retrieved 2009-09-25.
- ^ РД0410. Ядерный ракетный двигатель. Перспективные космические аппараты [RD0410. Nuclear Rocket Engine. Advanced launch vehicles]. KBKhA - Chemical Automatics Design Bureau. Archived from the original on 30 November 2010.
- ^ "Aircraft: Lockheed SR-71A Blackbird". Archived from the original on 2012-07-29. Retrieved 2010-04-16.
- ^ "Factsheets : Pratt & Whitney J58 Turbojet". National Museum of the United States Air Force. Archived from the original on 2015-04-04. Retrieved 2010-04-15.
- ^ "Rolls-Royce SNECMA Olympus - Jane's Transport News". Archived from the original on 2010-08-06. Retrieved 2009-09-25.
With afterburner, reverser and nozzle ... 3,175 kg ... Afterburner ... 169.2 kN
- ^ Military Jet Engine Acquisition, RAND, 2002.
- ^ "Конструкторское бюро химавтоматики" - Научно-исследовательский комплекс / РД0750. [«Konstruktorskoe Buro Khimavtomatiky» - Scientific-Research Complex / RD0750.]. KBKhA - Chemical Automatics Design Bureau. Archived from the original on 26 July 2011.
- ^ Wade, Mark. "RD-0146". Encyclopedia Astronautica. Retrieved 2009-09-25.
- ^ SSME
- ^ "RD-180". Retrieved 2009-09-25.
- ^ Encyclopedia Astronautica: F-1
- ^ Astronautix NK-33 entry
- ^ Federal Aviation Administration (FAA) (2004). FAA-H-8083-3B Airplane Flying Handbook Handbook (PDF). Federal Aviation Administration.
- ^ Turbofan Thrust, Glenn Research Center, National Aeronautics and Space Administration (NASA)
- ^ "Microsoft PowerPoint - KTHhigspeed08.ppt" (PDF). Retrieved 2010-03-26.
- ^ "Scramjet". Orbitalvector.com. 2002-07-30. Retrieved 2010-03-26.
- ^ "Softly, softly towards the quiet jet" Michael J. T. Smith New Scientist 19 February 1970 p350
- ^ "Silencing the sources of jet noise" Dr David Crighton New Scientist 27 July 1972 p185
- ^ "Noise" I.C. Cheeseman Flight International 16 April 1970 p639
- ^ "The Aircraft Gas Turbine Engine and its operation" United Technologies Pratt & Whitney Part No. P&W 182408 December 1982 Sea level static internal pressures and temperatures p219/220
- ^ 'Quietening a Quiet Engine- The RB211 Demonstrator Programme" M. J. T. Smith SAE paper 760897 "Intake Noise Suppression" p5
Bibliography
- Brooks, David S. (1997). Vikings at Waterloo: Wartime Work on the Whittle Jet Engine by the Rover Company. Rolls-Royce Heritage Trust. ISBN 1-872922-08-2.
- Golley, John (1997). Genesis of the Jet: Frank Whittle and the Invention of the Jet Engine. Crowood Press. ISBN 1-85310-860-X.
- Hill, Philip; Peterson, Carl (1992), Mechanics and Thermodynamics of Propulsion (2nd ed.), New York: Addison-Wesley, ISBN 0-201-14659-2
- Kerrebrock, Jack L. (1992). Aircraft Engines and Gas Turbines (2nd ed.). Cambridge, MA: The MIT Press. ISBN 978-0-262-11162-1.
External links
- Media about jet engines from Rolls-Royce
- How Stuff Works article on how a Gas Turbine Engine works
- Influence of the Jet Engine on the Aerospace Industry
- An Overview of Military Jet Engine History, Appendix B, pp. 97–120, in Military Jet Engine Acquisition (Rand Corp., 24 pgs, PDF)
- Basic jet engine tutorial (QuickTime Video)
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