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Combustor

January 26, 2023

A combustor is a component or area of a gas turbine, ramjet, or scramjet engine where combustion takes place. It is also known as a burner, combustion chamber or flame holder. In a gas turbine engine, the combustor or combustion chamber is fed high-pressure air by the compression system. The combustor then heats this air at constant pressure as the fuel/air mix burns. As it burns the fuel/air mix heats and rapidly expands. The burned mix is exhausted from the combustor through the nozzle guide vanes to the turbine. In the case of a ramjet or scramjet engines, the exhaust is directly fed out through the nozzle.

A combustor must contain and maintain stable combustion despite very high air flow rates. To do so combustors are carefully designed to first mix and ignite the air and fuel, and then mix in more air to complete the combustion process. Early gas turbine engines used a single chamber known as a can-type combustor. Today three main configurations exist: can, annular, and cannular (also referred to as can-annular tubo-annular). Afterburners are often considered another type of combustor.

Combustors play a crucial role in determining many of an engine's operating characteristics, such as fuel efficiency, levels of emissions, and transient response (the response to changing conditions such as fuel flow and air speed).

Fundamentals

 
Combustor on a Rolls-Royce Nene turbojet

The objective of the combustor in a gas turbine is to add energy to the system to power the turbines, and produce a high-velocity gas to exhaust through the nozzle in aircraft applications. As with any engineering challenge, accomplishing this requires balancing many design considerations, such as the following:

  • Completely combust the fuel. Otherwise, the engine wastes the unburned fuel and creates unwanted emissions of unburned hydrocarbons, carbon monoxide (CO), and soot.
  • Low pressure loss across the combustor. The turbine which the combustor feeds needs high-pressure flow to operate efficiently.
  • The flame (combustion) must be held (contained) inside of the combustor. If combustion happens further back in the engine, the turbine stages can easily be overheated and damaged. Additionally, as turbine blades continue to grow more advanced and are able to withstand higher temperatures, the combustors are being designed to burn at higher temperatures and the parts of the combustor need to be designed to withstand those higher temperatures.
  • It should be capable of relighting at high altitude in an event of engine flame-out.
  • Uniform exit temperature profile. If there are hot spots in the exit flow, the turbine may be subjected to thermal stress or other types of damage. Similarly, the temperature profile within the combustor should avoid hot spots, as those can damage or destroy a combustor from the inside.
  • Small physical size and weight. Space and weight are at a premium in aircraft applications, so a well designed combustor strives to be compact. Non-aircraft applications, like power-generating gas turbines, are not as constrained by this factor.
  • Wide range of operation. Most combustors must be able to operate with a variety of inlet pressures, temperatures, and mass flows. These factors change with both engine settings and environmental conditions (i.e., full throttle at low altitude can be very different from idle throttle at high altitude).
  • Environmental emissions. There are strict regulations on aircraft emissions of pollutants like carbon dioxide and nitrogen oxides, so combustors need to be designed to minimize those emissions. (See Emissions section below)

Sources:[1][2]

History

Advancements in combustor technology focused on several distinct areas; emissions, operating range, and durability. Early jet engines produced large amounts of smoke, so early combustor advances, in the 1950s, were aimed at reducing the smoke produced by the engine. Once smoke was essentially eliminated, efforts turned in the 1970s to reducing other emissions, like unburned hydrocarbons and carbon monoxide (for more details, see the Emissions section below). The 1970s also saw improvement in combustor durability, as new manufacturing methods improved liner (see Components below) lifetime by nearly 100 times that of early liners. In the 1980s combustors began to improve their efficiency across the whole operating range; combustors tended to be highly efficient (99%+) at full power, but that efficiency dropped off at lower settings. Development over that decade improved efficiencies at lower levels. The 1990s and 2000s saw a renewed focus on reducing emissions, particularly nitrogen oxides. Combustor technology is still being actively researched and advanced, and much modern research focuses on improving the same aspects.[3]

Components

 
Case

The case is the outer shell of the combustor, and is a fairly simple structure. The casing generally requires little maintenance.[4] The case is protected from thermal loads by the air flowing in it, so thermal performance is of limited concern. However, the casing serves as a pressure vessel that must withstand the difference between the high pressures inside the combustor and the lower pressure outside. That mechanical (rather than thermal) load is a driving design factor in the case.[5]

Diffuser

The purpose of the diffuser is to slow the high-speed, highly compressed, air from the compressor to a velocity optimal for the combustor. Reducing the velocity results in an unavoidable loss in total pressure, so one of the design challenges is to limit the loss of pressure as much as possible.[6] Furthermore, the diffuser must be designed to limit the flow distortion as much as possible by avoiding flow effects like boundary layer separation. Like most other gas turbine engine components, the diffuser is designed to be as short and light as possible.[7]

Liner

The liner contains the combustion process and introduces the various airflows (intermediate, dilution, and cooling, see Air flow paths below) into the combustion zone. The liner must be designed and built to withstand extended high-temperature cycles. For that reason liners tend to be made from superalloys like Hastelloy X. Furthermore, even though high-performance alloys are used, the liners must be cooled with air flow.[8] Some combustors also make use of thermal barrier coatings. However, air cooling is still required. In general, there are two main types of liner cooling; film cooling and transpiration cooling. Film cooling works by injecting (by one of several methods) cool air from outside of the liner to just inside of the liner. This creates a thin film of cool air that protects the liner, reducing the temperature at the liner from around 1800 kelvins (K) to around 830 K, for example. The other type of liner cooling, transpiration cooling, is a more modern approach that uses a porous material for the liner. The porous liner allows a small amount of cooling air to pass through it, providing cooling benefits similar to film cooling. The two primary differences are in the resulting temperature profile of the liner and the amount of cooling air required. Transpiration cooling results in a much more even temperature profile, as the cooling air is uniformly introduced through pores. Film cooling air is generally introduced through slats or louvers, resulting in an uneven profile where it is cooler at the slat and warmer between the slats. More importantly, transpiration cooling uses much less cooling air (on the order of 10% of total airflow, rather than 20-50% for film cooling). Using less air for cooling allows more to be used for combustion, which is more and more important for high-performance, high-thrust engines.[9][10]

Snout

The snout is an extension of the dome (see below) that acts as an air splitter, separating the primary air from the secondary air flows (intermediate, dilution, and cooling air; see Air flow paths section below).[11]

Dome / swirler

The dome and swirler are the part of the combustor that the primary air (see Air flow paths below) flows through as it enters the combustion zone. Their role is to generate turbulence in the flow to rapidly mix the air with fuel.[8] Early combustors tended to use bluff body domes (rather than swirlers), which used a simple plate to create wake turbulence to mix the fuel and air. Most modern designs, however, are swirl stabilized (use swirlers). The swirler establishes a local low pressure zone that forces some of the combustion products to recirculate, creating the high turbulence.[11] However, the higher the turbulence, the higher the pressure loss will be for the combustor, so the dome and swirler must be carefully designed so as not to generate more turbulence than is needed to sufficiently mix the fuel and air.[12]

Fuel injector
 
Fuel injectors of a swirl-can combustor on a Pratt & Whitney JT9D turbofan

The fuel injector is responsible for introducing fuel to the combustion zone and, along with the swirler (above), is responsible for mixing the fuel and air. There are four primary types of fuel injectors; pressure-atomizing, air blast, vaporizing, and premix/prevaporizing injectors.[8] Pressure atomizing fuel injectors rely on high fuel pressures (as much as 3,400 kilopascals (500 psi)) to atomize[nb 1] the fuel. This type of fuel injector has the advantage of being very simple, but it has several disadvantages. The fuel system must be robust enough to withstand such high pressures, and the fuel tends to be heterogeneously atomized, resulting in incomplete or uneven combustion which has more pollutants and smoke.[13][14]

The second type of fuel injector is the air blast injector. This injector "blasts" a sheet of fuel with a stream of air, atomizing the fuel into homogeneous droplets. This type of fuel injector led to the first smokeless combustors. The air used is just same amount of the primary air (see Air flow paths below) that is diverted through the injector, rather than the swirler. This type of injector also requires lower fuel pressures than the pressure atomizing type.[14]

The vaporizing fuel injector, the third type, is similar to the air blast injector in that primary air is mixed with the fuel as it is injected into the combustion zone. However, the fuel-air mixture travels through a tube within the combustion zone. Heat from the combustion zone is transferred to the fuel-air mixture, vaporizing some of the fuel (mixing it better) before it is combusted. This method allows the fuel to be combusted with less thermal radiation, which helps protect the liner. However, the vaporizer tube may have serious durability problems with low fuel flow within it (the fuel inside of the tube protects the tube from the combustion heat).[15]

The premixing/prevaporizing injectors work by mixing or vaporizing the fuel before it reaches the combustion zone. This method allows the fuel to be very uniformly mixed with the air, reducing emissions from the engine. One disadvantage of this method is that fuel may auto-ignite or otherwise combust before the fuel-air mixture reaches the combustion zone. If this happens the combustor can be seriously damaged.[16]

Igniter

Most igniters in gas turbine applications are electrical spark igniters, similar to automotive spark plugs. The igniter needs to be in the combustion zone where the fuel and air are already mixed, but it needs to be far enough upstream so that it is not damaged by the combustion itself. Once the combustion is initially started by the igniter, it is self-sustaining, and the igniter is no longer used.[17] In can-annular and annular combustors (see Types of combustors below), the flame can propagate from one combustion zone to another, so igniters are not needed at each one. In some systems ignition-assist techniques are used. One such method is oxygen injection, where oxygen is fed to the ignition area, helping the fuel easily combust. This is particularly useful in some aircraft applications where the engine may have to restart at high altitude.[18]

Air flow paths

 
Primary air

This is the main combustion air. It is highly compressed air from the high-pressure compressor (often decelerated via the diffuser) that is fed through the main channels in the dome of the combustor and the first set of liner holes. This air is mixed with fuel, and then combusted.[19]

Intermediate air

Intermediate air is the air injected into the combustion zone through the second set of liner holes (primary air goes through the first set). This air completes the reaction processes, cooling the air down and diluting the high concentrations of carbon monoxide (CO) and hydrogen (H2).[20]

Dilution air

Dilution air is airflow injected through holes in the liner at the end of the combustion chamber to help cool the air to before it reaches the turbine stages. The air is carefully used to produce the uniform temperature profile desired in the combustor. However, as turbine blade technology improves, allowing them to withstand higher temperatures, dilution air is used less, allowing the use of more combustion air.[20]

Cooling air

Cooling air is airflow that is injected through small holes in the liner to generate a layer (film) of cool air to protect the liner from the combustion temperatures. The implementation of cooling air has to be carefully designed so it does not directly interact with the combustion air and process. In some cases, as much as 50% of the inlet air is used as cooling air. There are several different methods of injecting this cooling air, and the method can influence the temperature profile that the liner is exposed to (see Liner, above).[21]

Types

 
Arrangement of can-type combustors for a gas turbine engine, looking axis on, through the exhaust. The blue indicates cooling flow path, the orange indicates the combustion product flow path.

Can

Can combustors are self-contained cylindrical combustion chambers. Each "can" has its own fuel injector, igniter, liner, and casing.[22] The primary air from the compressor is guided into each individual can, where it is decelerated, mixed with fuel, and then ignited. The secondary air also comes from the compressor, where it is fed outside of the liner (inside of which is where the combustion is taking place). The secondary air is then fed, usually through slits in the liner, into the combustion zone to cool the liner via thin film cooling.[23]

In most applications, multiple cans are arranged around the central axis of the engine, and their shared exhaust is fed to the turbine(s). Can-type combustors were most widely used in early gas turbine engines, owing to their ease of design and testing (one can test a single can, rather than have to test the whole system). Can-type combustors are easy to maintain, as only a single can needs to be removed, rather than the whole combustion section. Most modern gas turbine engines (particularly for aircraft applications) do not use can combustors, as they often weigh more than alternatives. Additionally, the pressure drop across the can is generally higher than other combustors (on the order of 7%). Most modern engines that use can combustors are turboshafts featuring centrifugal compressors.[24][25]

Cannular

 
Cannular combustor for a gas turbine engine, viewing axis on, through the exhaust

The next type of combustor is the cannular combustor; the term is a portmanteau of "can annular". Like the can-type combustor, can annular combustors have discrete combustion zones contained in separate liners with their own fuel injectors. Unlike the can combustor, all the combustion zones share a common ring (annulus) casing. Each combustion zone no longer has to serve as a pressure vessel.[26] The combustion zones can also "communicate" with each other via liner holes or connecting tubes that allow some air to flow circumferentially. The exit flow from the cannular combustor generally has a more uniform temperature profile, which is better for the turbine section. It also eliminates the need for each chamber to have its own igniter. Once the fire is lit in one or two cans, it can easily spread to and ignite the others. This type of combustor is also lighter than the can type, and has a lower pressure drop (on the order of 6%). However, a cannular combustor can be more difficult to maintain than a can combustor.[27] Examples of gas turbine engines utilizing a cannular combustor include the General Electric J79 turbojet and the Pratt & Whitney JT8D and Rolls-Royce Tay turbofans.[28]

Annular

 
Annular combustor for a gas turbine engine, viewed axis on looking through the exhaust. The small yellow circles are the fuel injection nozzles, while the larger orange ring is the continuous liner for the combustion zone.

The final, and most-commonly used type of combustor is the fully annular combustor. Annular combustors do away with the separate combustion zones and simply have a continuous liner and casing in a ring (the annulus). There are many advantages to annular combustors, including more uniform combustion, shorter size (therefore lighter), and less surface area.[29][30] Additionally, annular combustors tend to have very uniform exit temperatures. They also have the lowest pressure drop of the three designs (on the order of 5%).[31] The annular design is also simpler, although testing generally requires a full size test rig. An engine that uses an annular combustor is the CFM International CFM56. Almost all of the modern gas turbine engines use annular combustors; likewise, most combustor research and development focuses on improving this type.

Double annular combustor

One variation on the standard annular combustor is the double annular combustor (DAC). Like an annular combustor, the DAC is a continuous ring without separate combustion zones around the radius. The difference is that the combustor has two combustion zones around the ring; a pilot zone and a main zone. The pilot zone acts like that of a single annular combustor, and is the only zone operating at low power levels. At high power levels, the main zone is used as well, increasing air and mass flow through the combustor. GE's implementation of this type of combustor focuses on reducing NOx and CO2 emissions.[32] A good diagram of a DAC is available from Purdue. Extending the same principles as the double annular combustor, triple annular and "multiple annular" combustors have been proposed and even patented.[33][34]

Emissions

One of the driving factors in modern gas turbine design is reducing emissions, and the combustor is the primary contributor to a gas turbine's emissions. Generally speaking, there are five major types of emissions from gas turbine engines: smoke, carbon dioxide (CO2), carbon monoxide (CO), unburned hydrocarbons (UHC), and nitrogen oxides (NOx).[35][36]

Smoke is primarily mitigated by more evenly mixing the fuel with air. As discussed in the fuel injector section above, modern fuel injectors (such as airblast fuel injectors) evenly atomize the fuel and eliminate local pockets of high fuel concentration. Most modern engines use these types of fuel injectors and are essentially smokeless.[35]

Carbon dioxide is a product of the combustion process, and it is primarily mitigated by reducing fuel usage. On average, 1 kg of jet fuel burned produces 3.2 kg of CO2. Carbon dioxide emissions will continue to drop as manufacturers make gas turbine engines more efficient.[36]

Unburned-hydrocarbon (UHC) and carbon-monoxide (CO) emissions are highly related. UHCs are essentially fuel that was not completely combusted, and UHCs are mostly produced at low power levels (where the engine is not burning all the fuel).[36] Much of the UHC content reacts and forms CO within the combustor, which is why the two types of emissions are heavily related. As a result of this close relation, a combustor that is well optimized for CO emissions is inherently well optimized for UHC emissions, so most design work focuses on CO emissions.[35]

Carbon monoxide is an intermediate product of combustion, and it is eliminated by oxidation. CO and OH react to form CO2 and H. This process, which consumes the CO, requires a relatively long time ("relatively" is used because the combustion process happens incredibly quickly), high temperatures, and high pressures. This fact means that a low-CO combustor has a long residence time (essentially the amount of time the gases are in the combustion chamber).[35]

Like CO, Nitrogen oxides (NOx) are produced in the combustion zone. However, unlike CO, it is most produced during the conditions that CO is most consumed (high temperature, high pressure, long residence time). This means that, in general, reducing CO emissions results in an increase in NOx, and vice versa. This fact means that most successful emission reductions require the combination of several methods.[35]

Afterburners

Main article: Afterburner

An afterburner (or reheat) is an additional component added to some jet engines, primarily those on military supersonic aircraft. Its purpose is to provide a temporary increase in thrust, both for supersonic flight and for takeoff (as the high wing loading typical of supersonic aircraft designs means that take-off speed is very high). On military aircraft the extra thrust is also useful for combat situations. This is achieved by injecting additional fuel into the jet pipe downstream of (i.e. after) the turbine and combusting it. The advantage of afterburning is significantly increased thrust; the disadvantage is its very high fuel consumption and inefficiency, though this is often regarded as acceptable for the short periods during which it is usually used.

Jet engines are referred to as operating wet when afterburning is being used and dry when the engine is used without afterburning. An engine producing maximum thrust wet is at maximum power or max reheat (this is the maximum power the engine can produce); an engine producing maximum thrust dry is at military power or max dry.

As with the main combustor in a gas turbine, the afterburner has both a case and a liner, serving the same purpose as their main combustor counterparts. One major difference between a main combustor and an afterburner is that the temperature rise is not constrained by a turbine section, therefore afterburners tend to have a much higher temperature rise than main combustors.[37] Another difference is that afterburners are not designed to mix fuel as well as primary combustors, so not all the fuel is burned within the afterburner section.[38] Afterburners also often require the use of flameholders to keep the velocity of the air in the afterburner from blowing the flame out. These are often bluff bodies or "vee-gutters" directly behind the fuel injectors that create localized low-speed flow in the same manner the dome does in the main combustor.[39]

Ramjets

Main article: Ramjet

Ramjet engines differ in many ways from traditional gas turbine engines, but most of the same principles hold. One major difference is the lack of rotating machinery (a turbine) after the combustor. The combustor exhaust is directly fed to a nozzle. This allows ramjet combustors to burn at a higher temperature. Another difference is that many ramjet combustors do not use liners like gas turbine combustors do. Furthermore, some ramjet combustors are dump combustors rather than a more conventional type. Dump combustors inject fuel and rely on recirculation generated by a large change in area in the combustor (rather than swirlers in many gas turbine combustors).[40] That said, many ramjet combustors are also similar to traditional gas turbine combustors, such as the combustor in the ramjet used by the RIM-8 Talos missile, which used a can-type combustor.[41]

Scramjets

 
Diagram illustrating a scramjet engine. Notice the isolator section between the compression inlet and combustion chamber. (Illustration from The Hy-V Scramjet Flight Experiment.)
Main article: Scramjet

Scramjet (supersonic combustion ramjet) engines present a much different situation for the combustor than conventional gas turbine engines (scramjets are not gas turbines, as they generally have few or no moving parts). While scramjet combustors may be physically quite different from conventional combustors, they face many of the same design challenges, like fuel mixing and flame holding. However, as its name implies, a scramjet combustor must address these challenges in a supersonic flow environment. For example, for a scramjet flying at Mach 5, the air flow entering the combustor would nominally be Mach 2. One of the major challenges in a scramjet engine is preventing shock waves generated by combustor from traveling upstream into the inlet. If that were to happen, the engine may unstart, resulting in loss of thrust, among other problems. To prevent this, scramjet engines tend to have an isolator section (see image) immediately ahead of the combustion zone.[42]

Notes

  1. ^ While atomize has several definitions, in this context it means to form a fine spray. It is not meant to imply that the fuel is being broken down to its atomic components.

References

 
Wikimedia Commons has media related to Combustors.
Notes
  1. ^ Flack, p. 440.
  2. ^ Mattingly, Heiser, and Pratt, p. 325.
  3. ^ Koff, Bernard L. (July–August 2004). "Gas Turbine Technology Evolution: A Designer's Perspective". Journal of Propulsion and Power. 20 (4): 577–595. doi:10.2514/1.4361.
  4. ^ Henderson and Blazowski, pp. 119–20.
  5. ^ Mattingly, Heiser, and Pratt, p. 378.
  6. ^ Mattingly, Heiser, and Pratt, p. 375.
  7. ^ Henderson and Blazowski, p. 121.
  8. ^ a b c Mattingly, p. 760.
  9. ^ Mattingly, Heiser, and Pratt, pp. 372–4.
  10. ^ Henderson and Blazowski, pp. 124–7.
  11. ^ a b Henderson and Blazowski, p. 124.
  12. ^ Flack, p. 441.
  13. ^ Henderson and Blazowski, p. 127.
  14. ^ a b Mattingly, Heiser, and Pratt, p. 379.
  15. ^ Henderson and Blazowski, p. 128.
  16. ^ Henderson and Blazowski, p. 129.
  17. ^ Mattingly, Heiser, and Pratt, p. 368.
  18. ^ Henderson and Blazowski, pp. 129–30.
  19. ^ Henderson and Blazowski, p. 110.
  20. ^ a b Henderson and Blazowski, p. 111.
  21. ^ Henderson and Blazowski, pp. 111, 125–7.
  22. ^ Benson, Tom. Combustor-Burner. NASA Glenn Research Center. Last Updated 11 Jul 2008. Accessed 6 Jan 2010.
  23. ^ Flack, p. 442.
  24. ^ Flack, pp. 442–3.
  25. ^ Henderson and Blazowski, p. 106.
  26. ^ Mattingly, Heiser, and Pratt, pp. 377–8.
  27. ^ Flack, pp. 442–4.
  28. ^ Henderson and Blazowski, pp. 106–7.
  29. ^ Henderson and Blazowski, p. 108.
  30. ^ Mattingly, p. 757.
  31. ^ Flack, p. 444.
  32. ^ CFM'S Advanced Double Annular Combustor Technology Archived 2012-07-28 at archive.today. Press Release. 9 Jul 1998. Accessed 6 Jan 2010.
  33. ^ Ekstedt, Edward E., et al (1994). U.S. Patent 5,323,604 Triple annular combustor for gas turbine engine].
  34. ^ Schilling, Jan C., et al (1997). U.S. Patent 5,630,319 Dome assembly for a multiple annular combustor].
  35. ^ a b c d e Verkamp, F. J., Verdouw, A. J., Tomlinson, J. G. (1974). Impact of Emission Regulations on Future Gas Turbine Engine Combustors. Journal of Aircraft. June 1974. Vol. 11, No. 6. pp. 340–344.
  36. ^ a b c Sturgess, G.J.; Zelina, J.; Shouse D. T.; Roquemore, W.M. (March–April 2005). "Emissions Reduction Technologies for Military Gas Turbine Engines". Journal of Propulsion and Power. 21 (2): 193–217. doi:10.2514/1.6528.
  37. ^ Mattingly, pp. 770–1.
  38. ^ Flack, pp. 445–6.
  39. ^ Mattingly, p. 747.
  40. ^ Stull, F. D. and Craig, R. R. (1975). Investigation of Dump Combustors with Flameholders. 13th AIAA Aerospace Sciences Meeting. Pasadena, CA. 20–22 January 1975. AIAA 75-165
  41. ^ Waltrup, P.J.; White M.E.; Zarlingo F; Gravlin E. S. (January–February 2002). "History of U.S. Navy Ramjet, Scramjet, and Mixed-Cycle Propulsion Development". Journal of Propulsion and Power. 18 (1): 14–27. doi:10.2514/2.5928. (PDF) from the original on 2007-04-13.
  42. ^ Goyne, C. P; Hall, C. D.; O'Brian, W. F.; Schetz, J. A (November 2006). The Hy-V Scramjet Flight Experiment (AIAA 2006-7901). 14th AIAA/AHI Space Planes and Hypersonic Systems and Technologies Conference. doi:10.2514/6.2006-7901. (PDF) from the original on 2007-09-30.
Bibliography
  • Flack, Ronald D. (2005). "Chapter 9: Combustors and Afterburners". Fundamentals of Jet Propulsion with Applications. Cambridge Aerospace Series. New York, NY: Cambridge University Press. ISBN 978-0-521-81983-1.
  • Henderson, Robert E.; Blazowski, William S. (1989). "Chapter 2: Turbopropulsion Combustion Technology". In Oates, Gordon C. (ed.). Aircraft Propulsion Systems Technology and Design. AIAA Education Series. Washington, DC: American Institute of Aeronautics and Astronautics. ISBN 0-930403-24-X.
  • Mattingly, Jack D.; Heiser, William H.; Pratt, David T. (2002). "Chapter 9: Engine Component Design: Combustion Systems". Aircraft Engine Design. AIAA Education Series (2nd ed.). Reston, VA: American Institute of Aeronautics and Astronautics. ISBN 1-56347-538-3.
  • Mattingly, Jack D. (2006). "Chapter 10: Inlets, Nozzles, and Combustion Systems". Elements of Propulsion: Gas Turbines and Rockets. AIAA Education Series. Reston, VA: American Institute of Aeronautics and Astronautics. ISBN 1-56347-779-3.

January 26, 2023
combustor, combustor, component, area, turbine, ramjet, scramjet, engine, where, combustion, takes, place, also, known, burner, combustion, chamber, flame, holder, turbine, engine, combustor, combustion, chamber, high, pressure, compression, system, combustor,. A combustor is a component or area of a gas turbine ramjet or scramjet engine where combustion takes place It is also known as a burner combustion chamber or flame holder In a gas turbine engine the combustor or combustion chamber is fed high pressure air by the compression system The combustor then heats this air at constant pressure as the fuel air mix burns As it burns the fuel air mix heats and rapidly expands The burned mix is exhausted from the combustor through the nozzle guide vanes to the turbine In the case of a ramjet or scramjet engines the exhaust is directly fed out through the nozzle A combustor must contain and maintain stable combustion despite very high air flow rates To do so combustors are carefully designed to first mix and ignite the air and fuel and then mix in more air to complete the combustion process Early gas turbine engines used a single chamber known as a can type combustor Today three main configurations exist can annular and cannular also referred to as can annular tubo annular Afterburners are often considered another type of combustor Combustors play a crucial role in determining many of an engine s operating characteristics such as fuel efficiency levels of emissions and transient response the response to changing conditions such as fuel flow and air speed Contents 1 Fundamentals 1 1 History 1 2 Components 1 3 Air flow paths 2 Types 2 1 Can 2 2 Cannular 2 3 Annular 2 3 1 Double annular combustor 3 Emissions 4 Afterburners 5 Ramjets 6 Scramjets 7 Notes 8 ReferencesFundamentals Edit Combustor on a Rolls Royce Nene turbojet The objective of the combustor in a gas turbine is to add energy to the system to power the turbines and produce a high velocity gas to exhaust through the nozzle in aircraft applications As with any engineering challenge accomplishing this requires balancing many design considerations such as the following Completely combust the fuel Otherwise the engine wastes the unburned fuel and creates unwanted emissions of unburned hydrocarbons carbon monoxide CO and soot Low pressure loss across the combustor The turbine which the combustor feeds needs high pressure flow to operate efficiently The flame combustion must be held contained inside of the combustor If combustion happens further back in the engine the turbine stages can easily be overheated and damaged Additionally as turbine blades continue to grow more advanced and are able to withstand higher temperatures the combustors are being designed to burn at higher temperatures and the parts of the combustor need to be designed to withstand those higher temperatures It should be capable of relighting at high altitude in an event of engine flame out Uniform exit temperature profile If there are hot spots in the exit flow the turbine may be subjected to thermal stress or other types of damage Similarly the temperature profile within the combustor should avoid hot spots as those can damage or destroy a combustor from the inside Small physical size and weight Space and weight are at a premium in aircraft applications so a well designed combustor strives to be compact Non aircraft applications like power generating gas turbines are not as constrained by this factor Wide range of operation Most combustors must be able to operate with a variety of inlet pressures temperatures and mass flows These factors change with both engine settings and environmental conditions i e full throttle at low altitude can be very different from idle throttle at high altitude Environmental emissions There are strict regulations on aircraft emissions of pollutants like carbon dioxide and nitrogen oxides so combustors need to be designed to minimize those emissions See Emissions section below Sources 1 2 History Edit Advancements in combustor technology focused on several distinct areas emissions operating range and durability Early jet engines produced large amounts of smoke so early combustor advances in the 1950s were aimed at reducing the smoke produced by the engine Once smoke was essentially eliminated efforts turned in the 1970s to reducing other emissions like unburned hydrocarbons and carbon monoxide for more details see the Emissions section below The 1970s also saw improvement in combustor durability as new manufacturing methods improved liner see Components below lifetime by nearly 100 times that of early liners In the 1980s combustors began to improve their efficiency across the whole operating range combustors tended to be highly efficient 99 at full power but that efficiency dropped off at lower settings Development over that decade improved efficiencies at lower levels The 1990s and 2000s saw a renewed focus on reducing emissions particularly nitrogen oxides Combustor technology is still being actively researched and advanced and much modern research focuses on improving the same aspects 3 Components Edit CaseThe case is the outer shell of the combustor and is a fairly simple structure The casing generally requires little maintenance 4 The case is protected from thermal loads by the air flowing in it so thermal performance is of limited concern However the casing serves as a pressure vessel that must withstand the difference between the high pressures inside the combustor and the lower pressure outside That mechanical rather than thermal load is a driving design factor in the case 5 DiffuserThe purpose of the diffuser is to slow the high speed highly compressed air from the compressor to a velocity optimal for the combustor Reducing the velocity results in an unavoidable loss in total pressure so one of the design challenges is to limit the loss of pressure as much as possible 6 Furthermore the diffuser must be designed to limit the flow distortion as much as possible by avoiding flow effects like boundary layer separation Like most other gas turbine engine components the diffuser is designed to be as short and light as possible 7 LinerThe liner contains the combustion process and introduces the various airflows intermediate dilution and cooling see Air flow paths below into the combustion zone The liner must be designed and built to withstand extended high temperature cycles For that reason liners tend to be made from superalloys like Hastelloy X Furthermore even though high performance alloys are used the liners must be cooled with air flow 8 Some combustors also make use of thermal barrier coatings However air cooling is still required In general there are two main types of liner cooling film cooling and transpiration cooling Film cooling works by injecting by one of several methods cool air from outside of the liner to just inside of the liner This creates a thin film of cool air that protects the liner reducing the temperature at the liner from around 1800 kelvins K to around 830 K for example The other type of liner cooling transpiration cooling is a more modern approach that uses a porous material for the liner The porous liner allows a small amount of cooling air to pass through it providing cooling benefits similar to film cooling The two primary differences are in the resulting temperature profile of the liner and the amount of cooling air required Transpiration cooling results in a much more even temperature profile as the cooling air is uniformly introduced through pores Film cooling air is generally introduced through slats or louvers resulting in an uneven profile where it is cooler at the slat and warmer between the slats More importantly transpiration cooling uses much less cooling air on the order of 10 of total airflow rather than 20 50 for film cooling Using less air for cooling allows more to be used for combustion which is more and more important for high performance high thrust engines 9 10 SnoutThe snout is an extension of the dome see below that acts as an air splitter separating the primary air from the secondary air flows intermediate dilution and cooling air see Air flow paths section below 11 Dome swirlerThe dome and swirler are the part of the combustor that the primary air see Air flow paths below flows through as it enters the combustion zone Their role is to generate turbulence in the flow to rapidly mix the air with fuel 8 Early combustors tended to use bluff body domes rather than swirlers which used a simple plate to create wake turbulence to mix the fuel and air Most modern designs however are swirl stabilized use swirlers The swirler establishes a local low pressure zone that forces some of the combustion products to recirculate creating the high turbulence 11 However the higher the turbulence the higher the pressure loss will be for the combustor so the dome and swirler must be carefully designed so as not to generate more turbulence than is needed to sufficiently mix the fuel and air 12 Fuel injector Fuel injectors of a swirl can combustor on a Pratt amp Whitney JT9D turbofan The fuel injector is responsible for introducing fuel to the combustion zone and along with the swirler above is responsible for mixing the fuel and air There are four primary types of fuel injectors pressure atomizing air blast vaporizing and premix prevaporizing injectors 8 Pressure atomizing fuel injectors rely on high fuel pressures as much as 3 400 kilopascals 500 psi to atomize nb 1 the fuel This type of fuel injector has the advantage of being very simple but it has several disadvantages The fuel system must be robust enough to withstand such high pressures and the fuel tends to be heterogeneously atomized resulting in incomplete or uneven combustion which has more pollutants and smoke 13 14 The second type of fuel injector is the air blast injector This injector blasts a sheet of fuel with a stream of air atomizing the fuel into homogeneous droplets This type of fuel injector led to the first smokeless combustors The air used is just same amount of the primary air see Air flow paths below that is diverted through the injector rather than the swirler This type of injector also requires lower fuel pressures than the pressure atomizing type 14 The vaporizing fuel injector the third type is similar to the air blast injector in that primary air is mixed with the fuel as it is injected into the combustion zone However the fuel air mixture travels through a tube within the combustion zone Heat from the combustion zone is transferred to the fuel air mixture vaporizing some of the fuel mixing it better before it is combusted This method allows the fuel to be combusted with less thermal radiation which helps protect the liner However the vaporizer tube may have serious durability problems with low fuel flow within it the fuel inside of the tube protects the tube from the combustion heat 15 The premixing prevaporizing injectors work by mixing or vaporizing the fuel before it reaches the combustion zone This method allows the fuel to be very uniformly mixed with the air reducing emissions from the engine One disadvantage of this method is that fuel may auto ignite or otherwise combust before the fuel air mixture reaches the combustion zone If this happens the combustor can be seriously damaged 16 IgniterMost igniters in gas turbine applications are electrical spark igniters similar to automotive spark plugs The igniter needs to be in the combustion zone where the fuel and air are already mixed but it needs to be far enough upstream so that it is not damaged by the combustion itself Once the combustion is initially started by the igniter it is self sustaining and the igniter is no longer used 17 In can annular and annular combustors see Types of combustors below the flame can propagate from one combustion zone to another so igniters are not needed at each one In some systems ignition assist techniques are used One such method is oxygen injection where oxygen is fed to the ignition area helping the fuel easily combust This is particularly useful in some aircraft applications where the engine may have to restart at high altitude 18 Air flow paths Edit Primary airThis is the main combustion air It is highly compressed air from the high pressure compressor often decelerated via the diffuser that is fed through the main channels in the dome of the combustor and the first set of liner holes This air is mixed with fuel and then combusted 19 Intermediate airIntermediate air is the air injected into the combustion zone through the second set of liner holes primary air goes through the first set This air completes the reaction processes cooling the air down and diluting the high concentrations of carbon monoxide CO and hydrogen H2 20 Dilution airDilution air is airflow injected through holes in the liner at the end of the combustion chamber to help cool the air to before it reaches the turbine stages The air is carefully used to produce the uniform temperature profile desired in the combustor However as turbine blade technology improves allowing them to withstand higher temperatures dilution air is used less allowing the use of more combustion air 20 Cooling airCooling air is airflow that is injected through small holes in the liner to generate a layer film of cool air to protect the liner from the combustion temperatures The implementation of cooling air has to be carefully designed so it does not directly interact with the combustion air and process In some cases as much as 50 of the inlet air is used as cooling air There are several different methods of injecting this cooling air and the method can influence the temperature profile that the liner is exposed to see Liner above 21 Types Edit Arrangement of can type combustors for a gas turbine engine looking axis on through the exhaust The blue indicates cooling flow path the orange indicates the combustion product flow path Can Edit Can combustors are self contained cylindrical combustion chambers Each can has its own fuel injector igniter liner and casing 22 The primary air from the compressor is guided into each individual can where it is decelerated mixed with fuel and then ignited The secondary air also comes from the compressor where it is fed outside of the liner inside of which is where the combustion is taking place The secondary air is then fed usually through slits in the liner into the combustion zone to cool the liner via thin film cooling 23 In most applications multiple cans are arranged around the central axis of the engine and their shared exhaust is fed to the turbine s Can type combustors were most widely used in early gas turbine engines owing to their ease of design and testing one can test a single can rather than have to test the whole system Can type combustors are easy to maintain as only a single can needs to be removed rather than the whole combustion section Most modern gas turbine engines particularly for aircraft applications do not use can combustors as they often weigh more than alternatives Additionally the pressure drop across the can is generally higher than other combustors on the order of 7 Most modern engines that use can combustors are turboshafts featuring centrifugal compressors 24 25 Cannular Edit Cannular combustor for a gas turbine engine viewing axis on through the exhaust The next type of combustor is the cannular combustor the term is a portmanteau of can annular Like the can type combustor can annular combustors have discrete combustion zones contained in separate liners with their own fuel injectors Unlike the can combustor all the combustion zones share a common ring annulus casing Each combustion zone no longer has to serve as a pressure vessel 26 The combustion zones can also communicate with each other via liner holes or connecting tubes that allow some air to flow circumferentially The exit flow from the cannular combustor generally has a more uniform temperature profile which is better for the turbine section It also eliminates the need for each chamber to have its own igniter Once the fire is lit in one or two cans it can easily spread to and ignite the others This type of combustor is also lighter than the can type and has a lower pressure drop on the order of 6 However a cannular combustor can be more difficult to maintain than a can combustor 27 Examples of gas turbine engines utilizing a cannular combustor include the General Electric J79 turbojet and the Pratt amp Whitney JT8D and Rolls Royce Tay turbofans 28 Annular Edit Annular combustor for a gas turbine engine viewed axis on looking through the exhaust The small yellow circles are the fuel injection nozzles while the larger orange ring is the continuous liner for the combustion zone The final and most commonly used type of combustor is the fully annular combustor Annular combustors do away with the separate combustion zones and simply have a continuous liner and casing in a ring the annulus There are many advantages to annular combustors including more uniform combustion shorter size therefore lighter and less surface area 29 30 Additionally annular combustors tend to have very uniform exit temperatures They also have the lowest pressure drop of the three designs on the order of 5 31 The annular design is also simpler although testing generally requires a full size test rig An engine that uses an annular combustor is the CFM International CFM56 Almost all of the modern gas turbine engines use annular combustors likewise most combustor research and development focuses on improving this type Double annular combustor Edit One variation on the standard annular combustor is the double annular combustor DAC Like an annular combustor the DAC is a continuous ring without separate combustion zones around the radius The difference is that the combustor has two combustion zones around the ring a pilot zone and a main zone The pilot zone acts like that of a single annular combustor and is the only zone operating at low power levels At high power levels the main zone is used as well increasing air and mass flow through the combustor GE s implementation of this type of combustor focuses on reducing NOx and CO2 emissions 32 A good diagram of a DAC is available from Purdue Extending the same principles as the double annular combustor triple annular and multiple annular combustors have been proposed and even patented 33 34 Emissions EditOne of the driving factors in modern gas turbine design is reducing emissions and the combustor is the primary contributor to a gas turbine s emissions Generally speaking there are five major types of emissions from gas turbine engines smoke carbon dioxide CO2 carbon monoxide CO unburned hydrocarbons UHC and nitrogen oxides NOx 35 36 Smoke is primarily mitigated by more evenly mixing the fuel with air As discussed in the fuel injector section above modern fuel injectors such as airblast fuel injectors evenly atomize the fuel and eliminate local pockets of high fuel concentration Most modern engines use these types of fuel injectors and are essentially smokeless 35 Carbon dioxide is a product of the combustion process and it is primarily mitigated by reducing fuel usage On average 1 kg of jet fuel burned produces 3 2 kg of CO2 Carbon dioxide emissions will continue to drop as manufacturers make gas turbine engines more efficient 36 Unburned hydrocarbon UHC and carbon monoxide CO emissions are highly related UHCs are essentially fuel that was not completely combusted and UHCs are mostly produced at low power levels where the engine is not burning all the fuel 36 Much of the UHC content reacts and forms CO within the combustor which is why the two types of emissions are heavily related As a result of this close relation a combustor that is well optimized for CO emissions is inherently well optimized for UHC emissions so most design work focuses on CO emissions 35 Carbon monoxide is an intermediate product of combustion and it is eliminated by oxidation CO and OH react to form CO2 and H This process which consumes the CO requires a relatively long time relatively is used because the combustion process happens incredibly quickly high temperatures and high pressures This fact means that a low CO combustor has a long residence time essentially the amount of time the gases are in the combustion chamber 35 Like CO Nitrogen oxides NOx are produced in the combustion zone However unlike CO it is most produced during the conditions that CO is most consumed high temperature high pressure long residence time This means that in general reducing CO emissions results in an increase in NOx and vice versa This fact means that most successful emission reductions require the combination of several methods 35 Afterburners EditMain article Afterburner An afterburner or reheat is an additional component added to some jet engines primarily those on military supersonic aircraft Its purpose is to provide a temporary increase in thrust both for supersonic flight and for takeoff as the high wing loading typical of supersonic aircraft designs means that take off speed is very high On military aircraft the extra thrust is also useful for combat situations This is achieved by injecting additional fuel into the jet pipe downstream of i e after the turbine and combusting it The advantage of afterburning is significantly increased thrust the disadvantage is its very high fuel consumption and inefficiency though this is often regarded as acceptable for the short periods during which it is usually used Jet engines are referred to as operating wet when afterburning is being used and dry when the engine is used without afterburning An engine producing maximum thrust wet is at maximum power or max reheat this is the maximum power the engine can produce an engine producing maximum thrust dry is at military power or max dry As with the main combustor in a gas turbine the afterburner has both a case and a liner serving the same purpose as their main combustor counterparts One major difference between a main combustor and an afterburner is that the temperature rise is not constrained by a turbine section therefore afterburners tend to have a much higher temperature rise than main combustors 37 Another difference is that afterburners are not designed to mix fuel as well as primary combustors so not all the fuel is burned within the afterburner section 38 Afterburners also often require the use of flameholders to keep the velocity of the air in the afterburner from blowing the flame out These are often bluff bodies or vee gutters directly behind the fuel injectors that create localized low speed flow in the same manner the dome does in the main combustor 39 Ramjets EditMain article Ramjet Ramjet engines differ in many ways from traditional gas turbine engines but most of the same principles hold One major difference is the lack of rotating machinery a turbine after the combustor The combustor exhaust is directly fed to a nozzle This allows ramjet combustors to burn at a higher temperature Another difference is that many ramjet combustors do not use liners like gas turbine combustors do Furthermore some ramjet combustors are dump combustors rather than a more conventional type Dump combustors inject fuel and rely on recirculation generated by a large change in area in the combustor rather than swirlers in many gas turbine combustors 40 That said many ramjet combustors are also similar to traditional gas turbine combustors such as the combustor in the ramjet used by the RIM 8 Talos missile which used a can type combustor 41 Scramjets Edit Diagram illustrating a scramjet engine Notice the isolator section between the compression inlet and combustion chamber Illustration from The Hy V Scramjet Flight Experiment Main article Scramjet Scramjet supersonic combustion ramjet engines present a much different situation for the combustor than conventional gas turbine engines scramjets are not gas turbines as they generally have few or no moving parts While scramjet combustors may be physically quite different from conventional combustors they face many of the same design challenges like fuel mixing and flame holding However as its name implies a scramjet combustor must address these challenges in a supersonic flow environment For example for a scramjet flying at Mach 5 the air flow entering the combustor would nominally be Mach 2 One of the major challenges in a scramjet engine is preventing shock waves generated by combustor from traveling upstream into the inlet If that were to happen the engine may unstart resulting in loss of thrust among other problems To prevent this scramjet engines tend to have an isolator section see image immediately ahead of the combustion zone 42 Notes Edit While atomize has several definitions in this context it means to form a fine spray It is not meant to imply that the fuel is being broken down to its atomic components References Edit Wikimedia Commons has media related to Combustors Notes Flack p 440 Mattingly Heiser and Pratt p 325 Koff Bernard L July August 2004 Gas Turbine Technology Evolution A Designer s Perspective Journal of Propulsion and Power 20 4 577 595 doi 10 2514 1 4361 Henderson and Blazowski pp 119 20 Mattingly Heiser and Pratt p 378 Mattingly Heiser and Pratt p 375 Henderson and Blazowski p 121 a b c Mattingly p 760 Mattingly Heiser and Pratt pp 372 4 Henderson and Blazowski pp 124 7 a b Henderson and Blazowski p 124 Flack p 441 Henderson and Blazowski p 127 a b Mattingly Heiser and Pratt p 379 Henderson and Blazowski p 128 Henderson and Blazowski p 129 Mattingly Heiser and Pratt p 368 Henderson and Blazowski pp 129 30 Henderson and Blazowski p 110 a b Henderson and Blazowski p 111 Henderson and Blazowski pp 111 125 7 Benson Tom Combustor Burner NASA Glenn Research Center Last Updated 11 Jul 2008 Accessed 6 Jan 2010 Flack p 442 Flack pp 442 3 Henderson and Blazowski p 106 Mattingly Heiser and Pratt pp 377 8 Flack pp 442 4 Henderson and Blazowski pp 106 7 Henderson and Blazowski p 108 Mattingly p 757 Flack p 444 CFM S Advanced Double Annular Combustor Technology Archived 2012 07 28 at archive today Press Release 9 Jul 1998 Accessed 6 Jan 2010 Ekstedt Edward E et al 1994 U S Patent 5 323 604 Triple annular combustor for gas turbine engine Schilling Jan C et al 1997 U S Patent 5 630 319 Dome assembly for a multiple annular combustor a b c d e Verkamp F J Verdouw A J Tomlinson J G 1974 Impact of Emission Regulations on Future Gas Turbine Engine Combustors Journal of Aircraft June 1974 Vol 11 No 6 pp 340 344 a b c Sturgess G J Zelina J Shouse D T Roquemore W M March April 2005 Emissions Reduction Technologies for Military Gas Turbine Engines Journal of Propulsion and Power 21 2 193 217 doi 10 2514 1 6528 Mattingly pp 770 1 Flack pp 445 6 Mattingly p 747 Stull F D and Craig R R 1975 Investigation of Dump Combustors with Flameholders 13th AIAA Aerospace Sciences Meeting Pasadena CA 20 22 January 1975 AIAA 75 165 Waltrup P J White M E Zarlingo F Gravlin E S January February 2002 History of U S Navy Ramjet Scramjet and Mixed Cycle Propulsion Development Journal of Propulsion and Power 18 1 14 27 doi 10 2514 2 5928 Archived PDF from the original on 2007 04 13 Goyne C P Hall C D O Brian W F Schetz J A November 2006 The Hy V Scramjet Flight Experiment AIAA 2006 7901 14th AIAA AHI Space Planes and Hypersonic Systems and Technologies Conference doi 10 2514 6 2006 7901 Archived PDF from the original on 2007 09 30 BibliographyFlack Ronald D 2005 Chapter 9 Combustors and Afterburners Fundamentals of Jet Propulsion with Applications Cambridge Aerospace Series New York NY Cambridge University Press ISBN 978 0 521 81983 1 Henderson Robert E Blazowski William S 1989 Chapter 2 Turbopropulsion Combustion Technology In Oates Gordon C ed Aircraft Propulsion Systems Technology and Design AIAA Education Series Washington DC American Institute of Aeronautics and Astronautics ISBN 0 930403 24 X Mattingly Jack D Heiser William H Pratt David T 2002 Chapter 9 Engine Component Design Combustion Systems Aircraft Engine Design AIAA Education Series 2nd ed Reston VA American Institute of Aeronautics and Astronautics ISBN 1 56347 538 3 Mattingly Jack D 2006 Chapter 10 Inlets Nozzles and Combustion Systems Elements of Propulsion Gas Turbines and Rockets AIAA Education Series Reston VA American Institute of Aeronautics and Astronautics ISBN 1 56347 779 3 Retrieved from https en wikipedia org w index php title Combustor amp oldid 1082825325, wikipedia, wiki, book, books, library,

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