Jet engine performance: Difference between revisions

The meaning of jet engine performance has been phrased as 'the end product that a jet engine company sells'<ref>Gas Turbine Performance, Second Edition, Walsh and Fletcher 2004, {{ISBN|0 632 06434-X}}, Preface </ref> and, as such, criteria include thrust and fuel consumption, life, weight, emissions, diameter and cost. Performance criteria reflect the level of technology used in the design of an engine and the technology has been advancing continuously since the jet engine entered service in the 1940s. Categories of performance include performance improvement, performance deterioration, performance retention, bare engine performance (uninstalled) and performance when part of an aircraft powerplant (installed).

Conversion of fuel into thrust may be shown on a sketch which illustrates, in principle, the ___location of the thrust force in a much simplified internal shape representing a ramjet. As a result of burning fuel thrust is a forward-acting force on internal surfaces whether in the diffuser of a ramjet or compressor of a jet engine. Although the momentum of the flow leaving the nozzle is used to calculate thrust the momentum is only the reaction to the static pressure forces inside the engine and these forces are what produce the thrust.<ref>The Aerothermodynamics of Aircraft Gas Turbine Engines, Oates, Editor, AFAPL-TR-78-=52, WP AFB, Ohio, ppp.1-41 1–41</ref>

File:Marquardt RJ43-MA-9 Ramjet Engine - sectioned.jpg|[[Marquardt RJ43]] supersonic ramjet. This cutaway museum exhibit shows the 3 components of a ramjet, diffuser, combustion chamber and nozzle. At supersonic airspeeds air compression starts at the tip of the diffuser cone and continues internally due to internal air passage contours between the black centerbody and duct inner wall as far as the red high-blockage grid<ref>{{Cite book |url=https://discovery.nationalarchives.gov.uk/details/r/530c316d-1e47-4593-afd4-cf603ac01b27 |title=AGARD (Advisory Group for Aerospace Research and Development), Lecture Series No.136: Ramjet and Ramrocket Propulsion Systems for Missiles |date= |language=English}}</ref> then combustion in the cylindrical section after the yellow fuel nozzles and as far as the nozzle entry, then expansion through the convergent/ divergent nozzle.<ref name=":0">{{Cite magazine |url=http://archive.org/details/sim_american-rocket-society-ars-journal_1957-04_27_4 |title=unknownSome Fundamental Aspects of Ramjet Propulsion |magazine=ARS Journal |date=April 1957 |volume=27 |number=4 |publisher=American Institute of Aeronautics |via=Internet Archive |language=English}}</ref>

File:Meccanismo della spinta dell'autoreattore.png|This purpose of this sketch is to show that there are forward acting pressure forces and rearward acting forces inside the engine and the forward are greater than the rearward so forward thrust is the result. A typical ramjet pressure distribution over all the internal surfaces is shown by Thomas.<ref name=":0" /> Combustion of the fuel in a ramjet, in area shown red, causes the air to expand. The ramjet is shown moving to the left and the ram pressure rise (P1) in the diffuser (diffusore) is maintained by the expanding gas which can only accelerate rearwards in the presence of the ram rise. Thrust (Sd) comes from the pressure acting on the rear-facing diffuser surfaces. If a nozzle (ugello) restriction is included, as shown but not necessary for the production of thrust,<ref>{{Cite magazine |url=http://archive.org/details/sim_cornell-engineer_1951-03_16_6 |title=unknownSupersonic Stovepipes |page=9 |magazine=The Cornell Engineer |date=March 1951 |volume=16 |number=6 |publisher=Cornell University |via=Internet Archive |language=English}}</ref> a drag force (Su) is also present which reduces the thrust.

[[File:F-GSTF Beluga Airbus 5 (8138504167).jpg|thumb|Visual evidence of jet engine waste is the distorted view through the high temperature jet wakes from the core of the engine. "The efficiency of a gas turbine can be increased by reducing the proportion of heat that goes to waste, that is, by reducing the temperature of the exhaust."<ref>"Gas Turbines And Their Problems", Hayne Constant, Todd Reference Library, Todd Publishing Group Ltd., 1948, p. 46</ref> Less waste is involved in producing most of the thrust (~ 90%) of a modern civil bypass engine since the bypass air is barely warm, only 60&nbsp;°F above ambient at take-off. Only ~10% comes from the visible much hotter core exhaust, 900 deg above ambient.<ref>{{cite report |author=Kiran Siddappaji |title=Benefits of GE 90 representative turbofan through cycle analysis |date=November 2008 |doi=10.13140/RG.2.2.25078.50243 |url=https://www.researchgate.net/publication/323790787_Benefits_of_GE_90_representative_turbofan_through_cycle_analysis,"Benefits_of_GE_90_representative_turbofan_through_cycle_analysis",Take-Off Point station 18}}</ref>]]

The waste leaving a jet engine is in the form of a wake which has 2 constituents, one mechanical, called the residual velocity loss (RVL) due to its kinetic energy, and the other thermodynamic, due to its high temperature. The waste heat in the exhaust of a jet engine can only be reduced at source by addressing the loss-making processes and entropy generated as the air flows through the engine. For example, a more efficient compressor has lower losses, generates less entropy and contributes less to the temperature of the exhaust leaving the engine. Another example is the transfer of energy from an engine to air bypassing the engine. In the case of a high bypass engine there is a large proportion (~90%) of barely-warm (~60 degF&nbsp;°F warmer than ambient) thrust-producing air with only a 10% contribution from the much hotter exhaust from the power-producing core engine. As such, Struchtrup et al.<ref>{{cite journal |author1=Henning Struchtrup |author2=Gwynn Elfring |title=External losses in high-bypass turbo fan air engines |date=June 2008 |journal=International Journal of Exergy |volume=5 |number=4 |doi=10.1504/IJEX.2008.019112 |url=https://www.researchgate.net/publication/252167474_External_losses_in_high-bypass_turbo_fan_air_engines, Introduction}}</ref> show the benefit of the high bypass turbofan engine from an entropy-reducing perspective instead of the usual propulsive efficiency advantage.

Entropy, identified as 's', is introduced here because, although its mathematical meaning is acknowledged as difficult,<ref>{{Cite journal |last=Smith |first=Trevor I. |last2=Christensen |first2=Warren M. |last3=Mountcastle |first3=Donald B. |last4=Thompson |first4=John R. |date=2015-09-23 |title=Identifying student difficulties with entropy, heat engines, and the Carnot cycle |url=https://link.aps.org/doi/10.1103/PhysRevSTPER.11.020116 |journal=Physical Review Special Topics - Physics Education Research |volume=11 |issue=2 |pages=020116 |doi=10.1103/PhysRevSTPER.11.020116}}</ref> its common representation on a Temperature~entropy (T~s) diagram for a jet engine cycle is graphical and intuitive since its influence is shown as areas of the diagram. The T~s diagram was invented to help engineers responsible for the operation of steam engines to understand the efficiency of their engines. It supplemented the already-existing p~v diagram which only gave half the heat engine efficiency story in only showing the cylinder work done with no reference to the heat supplied and wasted in doing so. The need for an additional diagram, as opposed to understanding difficult theories, recognized the value of graphically representing heat transfers to and from an engine.<ref>Transactions The Manchester Association of Engineers 1904, The Temperature-Entropy Diagram, Mr. G. James Wells,p237 p. 237</ref> It would show areas representative of heat converted to work compared to heat supplied (thermal efficiency).<ref>{{Cite book |last= |url=http://archive.org/details/reportcommittee05unkngoog |title=Report of the committee appointed on the 31st March, 1896, to consider and report to the Council upon the subject of the definition of a standard or standards of thermal efficiency for steam-engines .. |date=1898 |publisher=London, the Institution}}</ref>

Quoting [[Frank Whittle]]:<ref>"Gas Turbine Aero-thermodynamics", Sir Frank Whittle, {{ISBN|0-08-026718-1}}, p. 2</ref> "Entropy is a concept which many students have a difficulty in assimilating. It is a somewhat intangible quantity...". Entropy is generated when energy is converted in to an unusable form analogous to the loss of energy in a waterfall where the original potential energy is converted to unusable energy of turbulence.

Denton compares it with aircraft drag, which is intuitive, "For an aircraft the ultimate measure of lost performance is the drag of its components....entropy creation reflects loss of efficiency in jet engines".<ref>Entropy Generation In Turbomachinery Flows"'Denton, SAE 902011, p. 2251</ref> He uses an analogy which imagines any inefficiency mechanism, such as the creation of whirls in the airflow, as producing smoke. Once created it cannot be destroyed and the concentration at the exit of the engine includes contributions from all loss-producing sources in the engine. The loss of efficiency is proportional to the concentration of the smoke at the exit.<ref>"Loss mechanisms in Turbomachines"' Denton, ASME 93-GT-435, p. 4</ref>

Acceleration of the flow through the engine causes simultaneous production of kinetic energy accompanying the thrust-producing backward momentum. The kinetic energy is left behind the engine without contributing to the thrust power<ref>'Jet Propulsion For Airplanes', Buckingham, NACA report 159, p. 85</ref> and is known as residual velocity loss. The thrust force from a stationary engine becomes thrust power when an aircraft is moving under its influence.

File:Klimov VK-1F (1948) used in MiG 17 at Flugausstellung Hermeskeil, pic2.jpg|[[Klimov VK-1]]F turbojet with afterburner. An afterburner is a propulsive duct in which high velocity exhaust from an engine turbine is converted into pressure in a diffuser. Afterburner fuel is burned with the oxygen in the dilution air which was not involved in the engine combustion process. The gas expands in a nozzle with an increase in velocity. The turbojet afterburner has the same three requirements as a ramjet, both being propulsive ducts. These are conversion of high velocity gas into pressure in a diffuser, combustion and expansion to a higher velocity in a nozzle. As such the turbojet/afterburner combination was sometimes considered in the late 1940's a turbo-ramjet.<ref>{{Cite web |last= |first= |date= |title=Performance and Ranges of Application of Various Types of Aircraft-Propulsion System |url=https://digital.library.unt.edu/ark:/67531/metadc55496/ |access-date=2023-11-16 |website=UNT Digital Library |language=English}}</ref><ref>"Design of Tail Pipes for Jet Engines-Including Reheat", Edwards, ''The Aeronautical Journal'', Volume 54, Issue 472, Fig. 1.</ref>

File:10+27 German Air Force Luftwaffe Airbus A310-304 MRTT General Electric CF6-80C2 engine ILA Berlin 2016 01.jpg|Turbofan (CF-6) inlet and fan. The core flow area, 1/6th, is visible through the fan. A comparison of how effective the subsonic inlet is at compressing air compared with the fan is given by inlet ram and fan temperature rises for a CFM56 of about 30 and 40 degF&nbsp;°F at 0.85 Mn cruise.<ref>{{Cite web |title=A Variable Cycle Engine for Subsonic Transport Applications - PDF Free Download |url=https://docplayer.net/140309337-A-variable-cycle-engine-for-subsonic-transport-applications.html |access-date=2023-11-16 |website=docplayer.net}}</ref> Temperature rise is connected to pressure rise by the losses incurred in the way the compression is achieved and all three are visually apparent on a T~s diagram.

File:Rolls-Royce Trent XWB on Airbus A350-941 F-WWCF MSN002 ILA Berlin 2016 09 square-crop.jpg|Turbofan (Trent) showing core nozzle and turbine blades, and bypass nozzle and fan bypass stators. The two nozzle wakes are made up of the waste which goes with thrust production. Both have residual velocity loss from their kinetic energy which is accounted for by pr eff. The core has heat rejected from the thermodynamic cycle and component losses. Also from the core part of the propulsion system, ie the nozzle and the LPT losses associated with the fan bypass flow. The fan nozzle passes the heat losses from the bypass propulsion system, ie the fan outer entropy generation, entropy production from the bypass duct pressure loss and the nozzle.<ref>https://arc.aiaa.org/doi/abs/10.2514/3.44525?journalCode=ja "Propulsive Efficiency from an Energy Utilization Standpoint", Lewis, Fig. 2</ref>

Thrust is easily controlled by regulating airflow and since all of the airflow is pumped by the fan N1 is used for setting thrust by [[General Electric Aviation]].<ref>Jet Engines And Propulsion Systems For Engineers, edited by Thaddeus Fowler, GE Aircraft Engines 1989, ppp.11-19 11–19</ref>

The EGT is a cockpit indicator for fuel flow since the fuel burned in the combustor determines the turbine entry temperature, which cannot be reliably measured, and EGT is a suitable alternative. Any deterioration from the engine as-new condition will require more fuel, resulting in higher temperature gas, to produce the thrust. At the take-off EPR, for example, the fuel flow and hence EGT rise with time in service as the engine deteriorates from its as-new condition. It progressively uses more fuel, until parts have to be replaced to restore the original lower operating temperature and reduce the cost of buying fuel.<ref>Performance of the Jet Transport Airplane, Young 2018, {{ISBN|9781118534779}}, Fig 8.19</ref>

Although EPR is directly related to thrust over the flight envelope American Airlines experience with their first jet engines, [[Pratt & Whitney JT3C]], was marred by instrumentation problems so the cockpit reading was questioned and other parameters, FF and N1, were used by flight personnel in desperation.<ref>"American Airlines Experience with Turbojet/Turbofan Engines", Whatley, ASME 62-GTP-16</ref>

EGT readings can also be misleading. The temperature of the gas leaving the turbine increases with engine use as parts become worn but the [[Strategic Air Command]] approved J57 and TF33 engines for flight without knowing they had bent and broken turbine parts. They were misled by low-reading EGT which indicated, when taken at face value, that the engines were in acceptable condition. It was found that the EGT probes were not positioned correctly to sample a representative gas temperature for the true condition of the engine.<ref>Who needs engine monitoring?, Aircraft Engine Diagnostics, NASA CP2190, 1981, p. 214</ref>

Performance improvement of the jet engine, first as a turbojet and then as a turbofan, has come from continuous increases in pressure ratio (PR) and component efficiencies, reduced pressure losses and from materials development which, together with cooling technologies, has allowed higher turbine inlet temperatures (TIT). It has also come from reduced leakage from the gas path because only the gas flow over the airfoil surfaces contributes to thrust. Increases in TIT mean a higher power output which for a turbojet leads to too high exhaust velocities for subsonic flight. For subsonic aircraft the high core power available from increased TIT is used to drive a large fan which adds less kinetic energy to a large amount of air.<ref>Jet Propulsion, Nicholas Cumpsty, {{ISBN|0 521 59674 2}}, p. 40</ref> Kinetic energy is the unwanted byproduct, known as residual velocity loss, of increasing momentum which produces thrust.

The aim of the propulsion engineer is to minimize the conversion or degradation of energy into heat rather than thrust work. Piston engines used some of their waste heat with turbocharging and turbo-compounding. Some was used for thrust from rearwards facing exhaust stubs. The waste heat from a jet engine cannot be used so performance is improved by reducing the amount produced while the air is passing through the engine. This includes loss in total pressure from entropy production in ducts as explained by Sullivan:<ref>Novel Aerodynamic Loss Analysis Technique Based On CFD Predictions Of Entropy Production, Sullivan, SAE 951430, p. 343</ref>

A reason for increasing bypass when core power has been increased is given by Hartmann:<ref>https://arc.aiaa.org/doi/10.2514/3.43978 "Theory and Test of Flow Mixing of Turbofan Engines", Hartmann,''Journal of Aircraft'', Vol. 5, No. 6,' Introduction'</ref>

Increased pressure ratio is an improvement to the thermodynamic cycle because combustion at a higher pressure has a reduced entropy rise which is the basic reason for pursuing higher pressure ratios in the jet engine cycle which is known as the Brayton cycle.<ref>https://arc.aiaa.org/doi/abs/10.2514/6.1964-243, On The Thermodynamic Spectrum Of Airbreathing Propulsion, Builder, p.2</ref> Increased pressure ratio can be achieved by using more stages or increasing the stage pressure ratio. The significance of higher pressure ratio to fuel consumption was demonstrated in 1948 when the J57 (12:1) was selected for the B-52 in place of a turboprop.<ref>'The Road To The 707', {{ISBN| 0-9629605-0-0}}, p. 204</ref> Boeing previous experience with turbojet specific fuel consumptions up to that time was the J47 (5.4:1), used in the B47, which initially led to the turboprop decision.

The radial flow compressor was widely used for early turbojet engines but advantages in performance that came with the axial compressor in terms of pressure ratio, SFC, specific weight and thrust for each square foot of frontal area were presented in 1950 by Constant<ref>https://journals.sagepub.com/doi/10.1243/PIME_PROC_1950_163_022_02, 'The Gas Turbine in Perspective', Hayne Constant, Fig. 3, 8, 9, 10</ref> However, a radial flow compressor is still the best choice for small turbofans as the last high pressure stage because the alternative very small axial stages would be too easily damaged and inefficient with tip clearance being significant compared to the blade height.<ref>https://patents.google.com/patent/US3357176A/en, 'Twin Spool Gas Turbine Engine with Axial and Centrifugal Compressors, column 1, lines 46-5046–50</ref>

File:Gearbox and compressors of sectioned Rolls-Royce Dart turboprop.jpg|Two stages of centrifugal compressor as shown here in the [[Rolls-Royce Dart]] turboprop were used in a jet engine, the [[Garrett F109]] turbofan with a pressure ratio of 13:1.<ref>"Design And Development Of The Garrett F109 Turbofan Engine", Krieger et al., ''Canadian Aeronautics and Space Journal'', Vol. 34, No. 3, September 198891988 9.171</ref>

The axial compressor has a geometry applicable to its high speed design condition at which the airflow approaches all the blading with little or no incidence, a requirement to keep flow losses to a minimum. As soon as conditions change from the design point the blade incidence angle will change away from a low-loss value and ultimately the compressor will no longer operate in a stable manner. The deviations from design are acceptable if the compressor doesn't have to raise the air pressure too much, say to 5 atmospheres. For greater values variable features have to be incorporated which change the compressor geometry below the design speed. Engines that came after the J47 with its 5.4:1 PR had compressors with higher PRs that needed some form of variable feature which operated at low speeds to prevent front stage stall and flutter failure and rear stage choking. These were valves which opened to release air when all the stages could not pass the same flow and variable angle vanes to maintain acceptable velocity triangles made up from the velocity of the approaching air, blade velocity and the relative velocity of air to blade. Alternatively the compressor was split into two separately rotating compressors<ref>https://archive.org/details/Aviation_Week_1952-10-20 , p. 13 'Split Compressors Usher in New Jet Era'</ref> each with a low pressure ratio such as the J57 with 3.75 LP x 3.2 HP = 12:1 overall.<ref>'The Engines of Pratt & Whitney: A Technical History', {{ISBN|978-1-60086-711-8}}, p. 232</ref> Bleed valves, variable blade angles and split compressors are used together on modern engines to achieve high pressure ratios. The [[Rolls-Royce Trent]] 700 from the 1990's, with a pressure ratio of 36:1 and 3 separate compressor rotors, needs 3 rows of variable blades and 7 bleed valves.

In the beginning higher pressure ratios had to be obtained with many stages because stage pressure ratios were low, about 1.16 for the J79 compressor which needed 17 stages.<ref>Jet Propulsion For Aerospace Applications, Second Edition, Hesse and Mumford, Library of Congress Catalog Card Number: 64-18757, p. 185</ref> Modern compressors have a higher PR per stage and still require the same variable features. The [[CFM International LEAP]] engine HP compressor with a PR 22:1 from 10 stages needs variable inlet guide vanes and 4 stages of variable stator vanes. The overall pressure ratio for an engine is limited by the temperature that goes with it. A compressor outlet temperature of about 900 K is the limit which is determined by material suitability in terms of weight and cost.<ref>https://archive.org/details/aircraftpropulsion2ed_201907, "Aircraft Propulsion", Farokhi Second Edition 2014, p. 638</ref>

File:Jet engine, cutaway (27441073466).jpg|[[Rolls-Royce Avon]] early jet engine showing 1 of 2 sets of 3 valves at the top and 1 of 2 valves at the bottom which release some air from the compressor, pressure ratio 7.45:1, for starting and low speed running. Also visible at the front is the row of bearings for the variable inlet guide vanes.<ref>Flight International, 16 December 1955, p. 901</ref>

<ref>https://www.roadrunnersinternationale.com/pw_tales.htm, p. 3</ref>

Air compression in a gas turbine is achieved by converting a proportion of the kinetic energy (compressor rotor generated, either by a centrifugal impeller or an axial row) of the air into static pressure one stage at a time. Most early jet engines used a single-stage centrifugal compressor with pressure ratios such as 3.3:1 ([[de Havilland Goblin]]). Higher pressure ratios came with the axial compressor because although stage pressure ratios were very low in comparison (1.17:1 [[BMW 003]])<ref>https://www.jstor.org/stable/44548294,"BMW-003 Turbo-Jet Engine Compared With Jumo004", Lundquist and Cole, p. 506</ref> more stages could be used as required for a higher overall pressure ratio. More advanced centrifugal stages are used in small turbofans as the last high-pressure stage behind axial stages ([[Pratt & Whitney Canada PW300]] and others). The same technology level produces 8:1 when used as the only stage in [[Pratt & Whitney PW200]] helicopter engines.<ref>https://engineering.purdue.edu/~propulsi/propulsion/jets/tprops/pw200.html, PW206 8:1</ref> A centrifugal stage consists of an impeller and diffuser vanes,<ref>"theThe Jet Engine", Rolls-Royce Limited,, Publication Ref. T.S.D. 1302, July 1969, 3rd Edition, Figure 3-6 'Airflow at entry to diffuser'</ref> or alternatively diffuser pipes<ref>https://patents.google.com/patent/US3420435,"Diffuser Construction"</ref> which are considered to give less blockage as the static pressure rises with diffusion.<ref>https://asmedigitalcollection.asme.org/GT/proceedings/GT1972/79818/V001T01A053/231014,"A Comparison Of The Predicted And Measured Performance Of High Pressure Ratio Centrifugal Compressor Diffusers", Kenney, p. 19</ref>

An axial compressor consists of alternating rows of rotating and stationary diffusers,<ref>https://archive.org/details/DTIC_ADA059784/page/n45/mode/2up,"All compression in engines requires a diffusion process", section 1.4.2.3</ref> each pair being a stage. These diffusers are diverging as necessary for subsonic flow.<ref>Supersonic flow is slowed in a converging duct as shown from the inlet lip to the shock trap bleed.[[File:J58 airflow at Mach 3.png|thumb|]]</ref> The channel formed by adjacent blades, amount of diffusion, is adjusted by varying their angle relative to tangential, known as stagger angle.<ref>https://ntrs.nasa.gov/citations/19650013744,"Aerodynamic Design of Axial-Flow Compressors", p. 126</ref> More diffusion gives a higher pressure ratio but flow in compressors is very susceptible to flow separation because it is going against a rising pressure (gas naturally flows from high to low pressure). Stage pressure ratio had increased by 2016 such that 11 stages could achieve 27:1 (GE9X high pressure compressor).<ref>https://drs.faa.gov/browse/excelExternalWindow/DRSDOCID114483736420230203181002.0001?modalOpened=true,"Type Certificate Data Sheet E00095EN"</ref>

Low aspect ratio compressor blades, with their better efficiency both aerodynamically and structurally, were introduced in the 1950's turbojet the [[Tumansky R-11]], and subsequently examples of wide chord fan blades introduced in 1983 in the [[Garrett TFE731]]-5<ref>https://www.sae.org/publications/technical-papers/content/861837/, "Low Aspect Ratio Axial Flow Compressors: Why and What It Means", Wennerstrom, p. 11</ref> and in 1984 in the [[RB211]]-535E4<ref>https://www.worldcat.org/title/history-of-the-rolls-royce-rb211-turbofan-engine/oclc/909128142</ref> and [[Pratt & Whitney Canada JT15D]]-5.<ref>https://asmedigitalcollection.asme.org/GT/proceedings/IGT1985/79429/V001T01A006/259190,"Development of a New Technology Small Fan Jet Engine", Boyd, ASME 85-IGT-139, p. 2</ref>

File:Compressor stage.JPG|Velocity triangles are used to show the velocity of the air relative to the stationary vanes and rotating blades. This figure shows the diffusing shape for the airflow between the blades, the exit area B is greater than the entry area A for the moving rotor blades (loopschoepen) and stationary vanes (leidschoepen). It also shows the construction of the velocity triangles which determine the angle the air strikes the leading edges. W₁ is the velocity relative to the blade moving at u and is aligned at a low-loss angle with the first rotor, C₂ is similarly aligned with the stationary vane, W₃ is aligned with the second rotor. Velocity triangles allow the mixing of moving and stationary viewpoints. For example the air is moving at velocity relative to rotor blade as it leaves the trailing edge and the triangle, with the blade velocity, converts to head-on velocity as it strikes a stationary vane.<ref>https://arc.aiaa.org/doi/abs/10.2514/1.9176?journalCode=jpp,"Ideas and Methods of Turbomachinery Aerodynamics: A Historical View", Cumpsty and Greitzer, Figure 1</ref>

File:COMBUSTOR SECTIONS - NARA - 17447547.jpg|This diagram shows some features in the complex flowfield in an axial compressor rotor. They are loss mechanisms which generate entropy. The flow is unsteady due to the relative motion between each row of moving and stationary blades. The flow patterns shown are known as secondary flow and are responsible for half the losses in a compressor.<ref>https://journals.sagepub.com/doi/10.1243/0954406991522680, "Axial Compressor Design", Gallimore, p. 439</ref>

File:Strahltriebwerk (41509006890).jpg|1950's [[Tumansky R-11]] low aspect ratio (wide) blading which preceded its introduction in other military engines by 20 years.<ref>https://asmedigitalcollection.asme.org/turbomachinery/article-abstract/111/4/357/419178/Low-Aspect-Ratio-Axial-Flow-Compressors-Why-and?redirectedFrom=fulltext, "Low Aspect Ratio Axial Flow Compressors: Why and What It Means", Wennerstrom, SAE 861837, p. 6</ref>

Fan blades on modern engines have a wide [[Chord (aircraft)|chord]] which replaced conventional narrow chord blades which needed snubbers, or shrouds, to prevent them vibrating to an unacceptable degree. Increasing the length of the chord by an amount which made the blade stiff enough to not require snubbers also made the blade more resistant to damage caused by bird, hail and ice ingestion,<ref>https://www.sciencedirect.com/science/article/abs/pii/S0376042112000838,"On The Design And Structural Analysis Of Jet Engine Fan Blade Structures", Amoo</ref> and brought several unrelated benefits of improved efficiency, surge margin and noise reductions.<ref>https://asmedigitalcollection.asme.org/GT/proceedings/GT1988/79191/V002T02A017/236878,"Developing The Rolls-Royce Tay", Wilson, 88-GT-302</ref> There is also a greater axial distance for centrifuging debris away from the compressor inlet to prevent erosion of the airfoil surfaces which lowers compressor efficiency.

File:JET ENGINES - NARA - 17421181.jpg|1970 [[Garrett TFE731]] with an early example of a transonic (supersonic relative velocities over the outer part of the blade) fan designed with the help of three-dimensional computational fluid dynamics (CFD).<ref>The Impact Of Three-Dimensional Analysis On Fan Design, Clemmons et al., ASME 83-GT-136</ref>

File:Rolls-Royce Trent 900 front.jpg|[[Rolls-Royce Trent]] 900 116 inch diameter fan. The fan has supersonic relative velocities in the outer half which result in shock waves in the passages. Visually evident are the blade leading edge sweep which changes from hub to tip from forward to backward to forward and the blade twist which varies from almost axial at the hub to almost circumferential at the tip. The shape of the blade positions the shock far enough behind the leading edge to prevent expulsion of the shockwave beyond the tip leading edge (prevents surge and flutter). Each radial section with its contribution to leading edge sweep and blade twist has its centrifugal force acting close to a radial line which minimizes stress due to rotation.<ref>https://patents.google.com/patent/US6071077A/en, "Swept Fan Blade"</ref><ref>"Modern Advances in Fan and Compressor Design using CFD", Balin, University of Colorado, Boulder, COColo. 80309</ref>

In addition to stagnation pressure loss the other measure of combustion performance is incomplete combustion. Combustion efficiency had always been close to 100 % at high thrust levels meaning only small amounts of HC and CO are present, but big improvements had to be made near idle operation. In the 1990's reduction of nitrogen oxides (NOx) became the focus due to its contribution to smog and acid rain for example. Combustor technology for reducing NOx is the Rich burn, Quick mix, Lean burn (RQL)<ref>https://www.researchgate.net/publication/271367881_The_Pratt_Whitney_TALON_X_Low_Emissions_Combustor_Revolutionary_Results_with_Evolutionary_Technology</ref> introduced by Pratt & Whitney with the TALON (Technology for Advanced Low NOx) PW4098 combustor.<ref>https://www.sciencedirect.com/science/article/abs/pii/S037604211630118X, p. 15</ref> RQL technology is also used in the Rolls-Royce Phase 5 Trent 1000 combustor and the General Electric LEC (Low Emissions Combustor).<ref>"Engine Technology Development to Address Local Air Quality Concerns", Moran, ICAO Colloquium on Aviation Emissions with Exhibition, 14-16 May 2007</ref>

File:General Electric J31NMUSAF (070110-F-1234S-009).jpg|[[General Electric J31]] with ten reverse-flow combustors. Compressed air flows between the 18-8 [[stainless steel]] outer casing and inner [[Inconel]] flame tube, then through a series of holes to the inside of the tube where it mixes with fuel. Burning continues along the length and is complete before reversing direction to the turbine.<ref>"Jet Propulsion Progress", Neville ansand Silsbee, First Edition,McGra McGraw-Hill Book Company, Inc., 1948, p. 127</ref>

File:Royal Military Museum Brussels 2007 224.JPG|[[de Havilland Goblin]] with sixteen straight-through combustion chambers. Each consists of a flame tube enclosed in a pressure-tight outer casing. They are connected by tubes which balance the pressure and propagate the flame during start from the two tubes with igniters one of which is shown on a top tube.<ref>"Series II Goblin", Flight magazine,21st February,1946</ref>

File:Combustor on Rolls-Royce Nene turbojet (2).jpg|[[Rolls-Royce Nene]] with nine combustion chambers. The cutaway is one of 2 chambers fitted with a flame igniter which places the igniter in a cooler ___location than directly in the hot gas stream. During a start atomized fuel from the small self-contained unit (orange-coloured solenoid shown) is ignited by its ignition plug and the flaming jet of fuel is projected into the main fuel spray from the burner. Combustion is propagated to all the chambers through interconnecting tubes.<ref>https://archive.org/details/in.ernet.dli.2015.19428/page/n71/mode/2up,"Gas Turbines and Jet Propulsion" 4th edition, Smith, Fig. 73 and 77</ref>

File:Westinghouse J46-WE-8 axial flow jet engine - Hiller Aviation Museum - San Carlos, California - DSC03061.jpg|[[Westinghouse J46]] "walking stick" fuel vapouriser tubes in an annular combustor.<ref>"Westinghouse J46 Axial Turbojet Family. Development History And Technical Profiles", Paul J. Christiansen, {{ISBN|978-0692764886}}, Figure 3 and 8</ref> Fuel vaporization was also used in the Sapphire, Viper, Pegasus, Olympus 593, and RB211 engines. Otherwise engines use some form of atomizing nozzle<ref>https://asmedigitalcollection.asme.org/gasturbinespower/article/132/11/116501/464800/GAS-TURBINE-COMBUSTION-Alternative-Fuels-and, p. 237</ref> which converts fuel pressure in the fuel tube to kinetic energy in the combustor producing a well-atomized spray.

File:Pratt & Whitney JT3.jpg|[[Pratt & Whitney J57]] with eight can-annular combustors, meaning the flame cans are separate but contained within the annular space between outer and inner casings. Each can was an annular combustion chamber in miniature with a central tube for cooling air and six burners arranged around it.<ref>"Two-spool Turbo Wasp", ''Flight magazine'', 27 November, 1953.</ref>

File:Combustor diagram airflow.png|The engine combustor needs the high velocity air leaving the compressor to be slowed significantly, which is done with an increase in flow area (diffuser), to a low Mn before combustion takes place to ensure low combustion pressure loss. A recirculation zone (shown by the circular airflow paths) has to be maintained near the fuel nozzle for initial combustion of the entering fuel to take place. This zone (the primary zone) is maintained by the two primary air paths, the swirl flow entering through swirl vanes (depicted by grey squares) around the fuel injector and the first row of primary air radial inflow holes. Combustion is completed with the intermediate air and the gas temperature is reduced with the dilution air to the value required for long life of the turbine.<ref>"Gas Turbine Combustion" Third Edition, Lefebvre and Ballal, {{ISBN|978 1 4200 8605 8}}, ppp.15/16 15–16, Figure 1.16</ref>

File:Core section of a sectioned Rolls-Royce Turboméca Adour turbofan.jpg|[[Rolls-Royce Turbomeca Adour]] military turbofan. There is a requirement to maintain a certain minimum pressure-loss in combustors, rather than reducing it as much as possible to minimize entropy production. It has to be maintained to prevent backflow in the turbine cooling circuits since cooling air from the HP compressor needs a lower pressure at the turbines in order to flow.<ref>https://patents.google.com/patent/US20150059355A1/en,"Method And Sysstem For Controlling Gas Turbine Performance With A Variable Backflow Margin"</ref><ref>www.netl.doe.gov>gas.turbine.handbook,"4.2.1 Cooling Design Analysis, p. 304</ref> Cooling air from the compressor (blue) has to flow to the turbine area (nozzle guide vane painted orange). This is enabled by the drop in pressure which occurs in the combustor. Also evident is the increase in area from the compressor into the combustor which is necessary to slow the air.

A low enough Mn where the flame starts (0.2-0.25 EJ200<ref>https://archive.org/details/DTIC_ADA361702,"Design Principles And Methods For Aircraft Gas Turbine Engines", RTO-MP-8, p. 19-5</ref>) and a big enough duct diameter for the burning zone are necessary to keep the loss in total pressure in the afterburner to an acceptably low level. As with the engine combustor the air has to be slowed down from the previous component by starting with a diffuser. Stabilization of the flame is achieved in the engine combustor using airflow only, obtaining flow reversal, for example, by using swirl vanes around the fuel injector combined with air entering through holes in the liner. Afterburners use obstructions to the flow known as bluff-body flameholders ('Vee' gutters). Afterburner fuel nozzles are situated upstream of the burning zone to allow atomized fuel to mix sufficiently with the turbine exhaust for the flame to spread across the duct from the flameholders.

The fundamental pressure loss, that due to burning, increases with Mn at entry to burning zone and with the amount of fuel burned in terms of the increase in temperature in the afterburner.<ref>https://link.springer.com/book/10.1007/978-3-319-75979-1,"Propulsion and Power", Kurzke and Halliwell, ppp.544/545 544–545</ref>

Although there is no turbine to limit the temperature of an afterburner there is still a cooling air requirement for the duct liner and variable nozzle which is about 10% of the engine entry airflow. The oxygen in this air is not available for burning.<ref>https://link.springer.com/book/10.1007/978-3-319-75979-1,"Propulsion and Power", Kurzke and Halliwell, p. 545</ref>

File:Rear view of afterburner in sectioned Rolls-Royce Turboméca Adour turbofan.jpg|Adour afterburner rear view showing 4 concentric vapour gutters (flameholders) which supply fuel required for minimum boost, the majority of the fuel, known as fill fuel, for full boost comes from 4 concentric manifolds upstream of the gutters to produce flame across the whole afterburner except for cooling air along the duct surface. Also visible is the anti screech liner for preventing pressure fluctuations which can cause damage from overheating.<ref>"Fast Jets-the history of reheat development at Derby", Cyril Elliott, Rolls-Royce Heritage Trust, Technical Series No 5, {{ISBN|1 872922 20 1}}, p. 116</ref>

The first duct in the powerplant is the inlet and loss in total pressure in front of the engine is particularly important because it appears twice in the production of thrust. Thrust is proportional to mass flow which is proportional to total pressure. Jet nozzle pressure and therefore thrust is also proportional to the total pressure at engine entry.<ref>"A Review Of Supersonic Air Intake Problems, Wyatt", Agardograph No. 27, p. 22</ref> In subsonic inlets the only total pressure losses are those due to friction along the duct passage walls. For supersonic inlets shockwave losses are also present and shockwave systems are required to minimize pressure loss with increasing supersonic Mn. Additional losses in total pressure come with boundary layer growth as the flow slows down. Boundary layers have to be removed before the ___location of the terminal shock to prevent shock-induced separation and excessive loss.

File:Strahltriebwerk WK-1A.jpg|[[Klimov VK-1]] early subsonic inlet showing the curved turning vanes which guide the inlet air into the eye of the impeller front and rear. This performance improvement was introduced by [[Frank Whittle]] in 1939 for the [[Power Jets W.1]]A "to help the air round the corner".<ref>The First James Clayton Lecture,"The Early History Of The Whittle Jet Propulsion Gas Turbine", Air Commodore F. Whittle, p. 430/ Fig. 20</ref> The equivalent vanes on the [[Rolls-Royce Nene]] reduced the inlet losses to the extent that thrust was increased from 4,000 to 5,000 lb at the same turbine temperature.<ref>Not Much Of An Engineer, Sir Stanley Hooker An Autobiography, {{ISBN|1 85310 285 7}}, p. 90</ref>

File:Vasters 1602 (6586637283).jpg|A view of the entry to an SR71 Mach 3.2 mixed external-internal inlet looking in direction of airflow to the engine. The centre translating cone has 26 inches of travel between extended, up to M1.6 (shown), and fully retracted at M3.2. An oblique shock from the cone tip, an internal oblique shock from the cowl lip and a normal shock<ref>https://patents.google.com/patent/US3477455A/en,"Supersonic inlet for jet engines"</ref> give the required pressure recovery at M3.2. The boundary layers on the cone and cowl inner surface have to be removed before the final shock-wave where the flow becomes subsonic. Otherwise shock-induced separation occurs. The two removal features are just visible. The cone boundary layer is removed through the band of holes (porous bleed). The boundary layer on the cowl inner surface is removed through a shock-trap<ref>https://ntrs.nasa.gov/citations/19930090035,"Use of Shock-trap Bleed to Improve Pressure Recovery...",</ref> bleed. This ram bleed is just visible on the lower surface in front of a row of streamlined lumps called "mice" which reduce the rate of diffusion.<ref>https://www.semanticscholar.org/paper/Ramjet-Intakes-Cain/96dc23a101c094f19d185f7497755c0cb0d19ec8, "Ramjet Intakes", Cain, Figure 19</ref>

Flow through bypass ducts is subject to frictional losses and obstructions causing flow separation. Care has to be taken to avoid steps and gaps which increase flow losses as does their presence on aircraft surfaces where they cause drag.<ref>"Fluid-dynamic Drag", Hoerner 1965, Library of Congress Catalog Card Number: 64-19666, Chapter 5 Drag of surface imperfections, p. 5-1</ref> Ducts need internal streamlining in the same way as external surfaces. Tubes have to cross the duct bringing compressed air from the gas generator to the aircraft pylon for its ECS. The tubes creates turbulent wakes in the bypass air which shows up as a pressure loss, an increase in entropy. A streamlined fairing round the tube is a performance improvement, it reduces the rise in entropy. The higher the flow Mn the greater the pressure loss.<ref>https://www.hindawi.com/journals/ijae/2022/3637181/, Analysis of Entropy Generation and Potential Inhibition in an Aeroengine System Environment, Liu et al., Introduction</ref>

File:Power jets W.2.jpg|[[Power Jets W.2]] for its initial installation in the [[Gloster E28/39]] was tested with no diffusion from the turbine exit Mn of 0.8. The turbine blade annulus area was used for the length of pipe necessary to reach the tail of the aircraft. The exhaust reached the speed of sound at a low thrust but at the turbine temperature limit due to the excessive pressure loss and frictional heating. Diffusion was added behind the turbine with the cone shown to reduce the pipe entry Mach number.<ref>https://www.cambridge.org/core/journals/aeronautical-journal/article/abs/aircraft-propulsion-from-the-back-room/771675086CDE0E766BE700CD6B3198E7 "Aircraft propulsion from the back room", Hawthorne, p. 101</ref>

The jet engine has many sealing locations, more than 50 in a large engine.The cumulative effect of leakage on fuel consumption can be significant. Gas path sealing affects engine efficiency and became increasingly more important as higher pressure compressors were introduced.<ref>"Seal Technology In Gas Turbine Engines", AGARD CP 237,p pp.1-2 1–2</ref>

Sealing of the stators was initially accomplished using knife-edge fins on the rotating part and a smooth surface for the stator shroud. Examples are the Avon and Tumansky R-11. With the invention of the honeycomb seal the labyrinth seal has an abrazive honeycomb shroud which is easily cut by the rotating seal teeth without overheating and damaging them.<ref>Selecting a Material For Brazing Honeycomb in Turbine Engines, Sporer and Fortuna, Brazing and Soldering Today February 20014, p. 44</ref> Labyrinth seals are also used in the secondary air system between rotating and stationary parts. Example locations for these are shown by Bobo.<ref>https://patents.google.com/patent/US2963307, "Honeycomb seal" Fig.1</ref>

Much of the loss in compressors is associated with tip clearance flow.<ref>Current Aerodynamic Issues For Aircraft Engines, Cumpsty, 11th Australian Fluid Mechanics Conference, University of Tasmania,14-18 14–18 December 1992, p. 804</ref> For a CFM56 engine an increase in high pressure turbine tip clearance of 0.25 mm causes the engine to run 10&nbsp;°C hotter (reduced efficiency) to attain take off thrust.<ref>CFM Flight Ops Support, Performance Deterioration p. 48</ref>

File:Strahltriebwerk (41509006890).jpg|Tumansky R-11 shrouded vane interstage labyrinth, (knife/teeth) on rotor, seal visible between LP stage 2 and 3<ref>AGARD CP 237 'Gas Path Sealing in Turbine Engines', Ludwig, Figure 6(a)</ref>

File:TF30 Side Cut Compressor HP.jpeg|[[Pratt & Whitney TF30]]. Early military bypass engine showing compressor discharge six-fin labyrinth seal <ref>https://ntrs.nasa.gov/citations/19780013166 "Gaspath Sealing in Turbine Engines", Ludwig Fig. 6(d)</ref>

An engine is designed to run steady state at design points such as take-off, climb, and cruise with running clearances which minimize fuel use. Steady state means being at a constant rpm for long enough (several minutes) for all parts to have stopped moving relative to each other from transient thermal growths. During this time clearances between parts may close up to rubbing contact and wear to give larger clearances, and fuel consumption, at the important stabilized condition. This scenario inside the engine is prevented by internal compressor bore cooling<ref>"Jet Engines And Propulsion Systems For Engineers, GE Aircraft Engines 1989, ppp.8-10 8–10</ref> and external turbine casing cooling on big fan engines (active clearance control).

In the late 1940's it was considered by most US engine manufacturers that the optimum pr was 6:1 in light of the amount of leakage flow expected with the then-current sealing knowledge. P&W considered 12:1 could be achieved<ref>https://arc.aiaa.org/doi/book/10.2514/4.867293 "The Engines of Pratt & Whitney:A Technical History", Connors, p. 219</ref> but during pre-J57 development testing a compressor with 8:1 was tested and the leakage was so high that no useful work would have been produced.<ref>https://www.enginehistory.org,"Wright's T35 Turboprop Engine, et al. by Doug Cuty,Published 1 Sept 2020 "... a constant outer diameter and a pressure ratio of 8:1 ... seal leakage was so bad that the constant outer diameter approach was terminated.."</ref> One benefit of the subsequent wasp waist was reduced leakage from the reduced sealing diameter.

In 1954 a GE engineer invented a very effective sealing scheme, the honeycomb seal<ref>'Honeycomb Seal", US patent 2,963,307</ref> which reduces substantially the rubbing contact area and temperatures generated. The rotating part cuts into the cellular structure without being permanently damaged. It is widely used today.

The advent of the high bypass civil engines, JT9D and CF6, showed the importance of thrust take off locations on the engine cases. Also, large engines have relatively flexible cases inherent in large diameter flight-weight structures giving relatively large relative displacements between heavy stiff rotors and the flexible cases. <ref>https://archive.org/stream/DTIC_ADA060293/DTIC_ADA060293_djvu.txt, "AGARD CP 237", ppp.1-9 1–9</ref>

Case distortion with subsequent blade tip rubbing and performance loss appeared on the JT9D installation in the Boeing 747 as a result of thrust being taken from a single point on top of the engine exhaust case. Thrust from the rear mount plane was a Boeing requirement.<ref>"Jet Engine Force Frame", US patent 3,675,418</ref> Compared to the 15,000 lb thrust JT3D with its four structural cases the 40,000 lb thrust JT9D made economical use of supporting structure with only three structural cases making a compact lightweight design.<ref>https://nyaspubs.onlinelibrary.wiley.com/doi/abs/10.1111/j.1749-6632.1968.tb15216.x, "Development Of The High Bypass Turbofan", p. 588 'Advanced Structural Concepts'</ref> During flight testing the engines suffered violent surges and loss in performance<ref>"747 Creating The World's First Jumbo Jet And Other Adventures From A Life In Aviation", Sutter, {{ISBN|978 0 06 088241 9}}, p. 187</ref> which were traced to bending of the engine backbone by 0.043 in. at the combustor case and the turbine case going out-of-round which in turn caused blade tip rubs and increased tip clearance.<ref>Flight International,13 November 1969, p. 749</ref>

The three big fan engines introduced in the 1960's for wide-body airliners, Boeing 747, Lockheed Tristar, DC-10, had much higher thrust and size compared to the engines powering the previous generation of airliners. The JT9D and CF6 showed that rotor tip clearances were sensitive to the way the engines were mounted and performance was lost through rotor tip rubs due to backbone bending and local distortion of casings at the point of thrust transfer to the aircraft pylon.<ref>https://arc.aiaa.org/doi/10.2514/6.1991-2987, "Spanning The Globe With Jet Propulsion", Koff, p. 8</ref> At the same time the RB211 performance didn't deteriorate so fast due to its shorter, more rigid, three-shaft configuration. For the Boeing 777<ref>https://patents.google.com/patent/US5320307A/en, "Aircraft Engine Thrust Mount", Abstract</ref><ref>https://www.freepatentsonline.com/5873547.html, "Aircraft Engine Thrust Mount", Sheet 2</ref> the Trent 800<ref>https://archive.org/details/boeing-777-ian-allan-abc, "Boeing 777, Campion-Smith, p. 52</ref> and GE90 would incorporate two-point mounting for ovalization reduction.<ref>https://asmedigitalcollection.asme.org/memagazineselect/article-abstract/133/03/46/380174/Mounting-TroublesThe-First-Jumbo-Jet-was-an?redirectedFrom=fulltext, "Mounting Troubles", Langston, p. 7</ref>

File:JT9D on 747.JPG|A [[Pratt & Whitney JT9D]] museum exhibit with none of the accessories, tubes, wiring and cowls which cover a functional engine. Revealed are the casings bolted together which make up the structural backbone of the engine.<ref>https://doi.org/10.1115/1.2011-MAR-6, 'Mounting Troubles' Langston</ref> The engine thrust is transferred to the aircraft pylon at the top of the turbine case. As this is above the engine centerline where the thrust acts it causes backbone bending in the core engine<ref>https://ntrs.nasa.gov/citations/19790022018, "Energy Efficient Engine Flight Propulsion System",'Mounting System' 4.11.2.3</ref> which in turn causes causes blade tip rubs and performance loss.

File:2016.10.13.111932 Detail GE90 jet engine Future of Flight Center & Boeing Tour Everett Washington.jpg|[[General Electric GE90]] shows one of two locations (45 degrees either side of top centre) on fan frame where engine thrust is transferred by links to the rear thrust mount for transfer to the aircraft pylon.<ref>https://www.freepatentsonline.com/5873547.html, "Aircraft Engine Thrust Mount", Sheet 2</ref>

File:DH-112-Mk4-Venom turboreactor MG 1323.jpg|[[de Havilland Ghost]] shows labyrinth teeth on the impeller backface to reduce air loss from the impeller and control the pressure on the back face. The radial position of the seal is chosen to set the area on which the pressure acts so the forward thrust on the impeller substantially balances the rearward thrust from the turbine which reduces the axial force on the rotor thrust bearing.<ref>"Flight", February 6th6, 1947, "The de Havilland Ghost (DGT/50)", p. 143</ref>

File:Turbine of a sectioned Rolls-Royce Turboméca Adour turbofan.jpg|Adour labyrinth seal with 3 fins on the blade platforms and a honeycomb shroud is a type of rim seal to prevent hot gas ingestion at the turbine disc rim.<ref>"Gas path sealing in turbine engines", Ludwig, NASA TM-73890, p. 1-2, 2. Sealing locations and seal types</ref>

File:CFM International CFM56-7B26 fitted to Qantas (VH-VZY) Boeing 737-838 (WL) at the Canberra Airport open day.jpg|CFM56 showing internal air system overboard vent for the oil system (vent tube in the exhaust). Secondary air enters the bearing compartments through labyrinth seals to prevent oil escaping in the opposite direction. The air continually escapes from the system through the vent with some oil mist after passing through a centrifugal air/oil separator.<ref>Training Manual CFM56-5C Engine Systems, January 2003, Published by CFMI Customer Training Center, Chapter 79-00-00 page 7</ref>

[[File:Pratt & Whitney JT8D-17A 1.JPG|The [[Pratt & Whitney JT8D]] has a full length fan duct which is a rigid case construction which resists inlet air loads during aircraft rotation. Compared to the later JT9D it has relatively loose clearances between rotating and stationary parts so blade tip rubs as a source of performance deterioration were not an issue.<ref>https://ntrs.nasa.gov/citations/19810022654,"Aircraft Engine Diagnostics", JT-8D Engine Performance Retention, p. 66</ref>]]

[[File:P&W JT9D cutaway.jpg|right|The Pratt & Whitney JT9D with a big increase in thrust over the JT8D raised awareness how to transfer engine thrust to the aircraft without bending the engine too much and causing rubs and performance deterioration.<ref>Flight International, 13 November 1969, p. 749</ref>.]]

Gas path deterioration and increasing EGT coexist. As the gas path deteriorates the EGT limit ultimately prevents the take-off thrust from being achieved and the engine has to be repaired.<ref>Aircraft Engine Diagnostics, NASA CP 2190, 1981, JT8D Engine Performance Retention, p. 64</ref>

The engine performance deteriorates with use as parts wear, meaning the engine has to use more fuel to get the required thrust. A new engine starts with a reserve of performance which is gradually eroded. The reserve is known as its temperature margin and is seen by a pilot as the EGT margin. For a new [[CFM International CFM56]]-3 the margin is 53&nbsp;°C.<ref>https:smart cockpit.com, CFM Flight Operations Support, page 37</ref><ref>Performance of the Jet Transport Airplane, Young 2018, {{ISBN|9781118534779}}, Fig 8.19</ref> Kraus<ref>https://reposit.haw-hamburg.de/handle/20.500.12738/5576,"Further investigation of engine performance loss, in particular exhaust gas temperature margin, in the CF6-80C2 jet engine and recommendations for test cell modifications to record additional criteria, Tables 2.1-21–2.4</ref> gives the effect on increased fuel consumption of typical component degredation during service.

File:TURBINE BLADES - DPLA - df5b1b1c388e127aca37fc549964a38c.jpg|The rough turbine blade airfoil surfaces have a higher friction coefficient than smooth surfaces and cause friction drag which is a source of loss in the turbine.<ref>Jet Engines And Propulsion Systems For Engineers, GE Aircraft Engines 1989,p pp.5-17 5–17</ref>

American Airlines experience with the JT3C turbojet included cracking and bowing of the turbine nozzle guide vanes which adversely affected the gas flow to the rotating turbine blades causing increased fuel consumption. More significant was erosion of turbine parts by hard carbon lumps which formed around the fuel nozzles and periodically breaking away and striking and eroding turbine blades and nozzle guide vanes causing loss of EGT margin.<ref>https://asmedigitalcollection.asme.org/GT/proceedings/GT1962/79931/V001T01A016/227591,"American Airlines Experience with Turbojet/Turbofan Engines", p. 4</ref>

Prior to the doubling and tripling price of fuel in the early 1970's the regain of performance after deterioration was largely a by-product of maintaining engine reliability. The rising cost of fuel and a new awareness on conservation of energy led to a need to understand which type and amount of component degradation caused how much of an increase in fuel consumption.<ref>https://ntrs.nasa.gov/citations/19750018937, p. 2</ref> Higher bypass ratio engines were shown to be more susceptible to structural deformations which caused blade tip and seal clearances to be opened up by rubs.

[[American Airlines]] conducted tests on early bypass engines to understand to what degree component wear and accumulation of atmospheric dirt affected fuel consumption. Gas path surfaces in the fan and compressor were found to be coated with deposits of dirt, salt and oil which increased surface roughness and caused performance loss.<ref>https://ntrs.nasa.gov/citations/19750018937,"Analysis of turbofan engine performance deterioration and proposed follow-on tests", p. 22</ref> A compressor wash on a particular [[Pratt & Whitney JT8D]] bypass engine reduced the fuel consumption by 110 pounds of fuel for every hour run.<ref>https://ntrs.nasa.gov/citations/19750018937 p.20</ref>

The advent of the high bypass engines introduced new structural requirements necessary to prevent blade rubs and performance deterioration. Prior to this the JT8D, for example, had thrust bending deflections minimized with a long stiff one-piece fan duct which isolated the internal engine cases from aerodynamic loads. The JT8D had good performance retention with its moderate turbine temperature and stiff structure. Rigid case construction installed engine not adversely affected by axial bending loads from inlet on TO rotation. The engine had relatively large clearances between rotating and stationary components so compressor and turbine blade tip rubs were not significant and performance degradation came from distress to the hot section and compressor blade increasing roughness and erosion.<ref> https://ntrs.nasa.gov/citations/19810022654,"Aircraft Engine Diagnostics", JT-8D Engine Performance Retention, p. 69</ref>

The connection between emissions and fuel consumption is the combustion inefficiency which wastes fuel. Fuel should be completely burned so all chemical energy is liberated as heat.<ref>https://archive.org/details/gasturbinecombus0000lefe, Gas Turbine Combustion, Lefebvre 1983, {{ISBN|0 07 037029X}} p. 4</ref> The formation of pollutants signifies that fuel has been wasted and more fuel is required to produce a particular thrust than would otherwise be.

Starting time is the time taken from initiating the starting sequence to reaching idle speed. A [[CFM-56]] typical start time is 45-60 seconds.<ref>CFM Flight Ops Support 13 December 2005, p. 85</ref> Starting time is a flight safety issue for airstarts because starting has to be completed before too much altitude has been lost.<ref>"Performance Prediction and Simulation of Gas Turbine Engine Operation for Aircraft, Marine, Vehicular, and Power Generation", RTO Technical Report TR-AVT-036, ppp.2-50 2–50</ref>

The weight of an engine is reflected in the weight of the aircraft and introduces some drag penalty. Extra engine weight means a heavier structure and reduces aircraft payload.<ref>"Aircraft Propulsion", P. J. McMahon, {{ISBN|0 273 42324 X}}, p. 58</ref>

The thrust governs the flow area hence size of the engine. A criterion of pounds of thrust per square foot of compressor inlet is a figure of merit. The first operational turbojets in Germany had axial compressors to meet a 1939 request from the German Air Ministry to develop engines producing 410 lb/sq ft.<ref>https://link.springer.com/book/10.1007/978-3-642-18484-0 "Aeronautical Research in Germany", Hirschel et al., p. 226</ref>

A lower fuel consumption engine reduces airline expenditure on buying fuel for a given fuel cost. Deterioration of performance(increased fuel consumption) in service has a cumulative effect on fuel costs as the deterioration and rise in consumption is progressive. The cost of parts replacement has to be considered relative to the saving in fuel.<ref>"Evolution Of The Airliner", Whitford, {{ISBN|978 1 86126 870 9}}, p. 119</ref>

A basic explanation for the way burning fuel results in engine thrust uses terminology like momentum, work, energy, power and rate. Correct use of the terminology may be confirmed by using the idea of fundamental units which are mass '''M''', length '''L''' and time '''T''', together with the idea of a dimension, ie power, of the fundamental unit, say '''L'''¹ for distance, and in a derived unit, say speed which is distance over time, with dimensions '''L'''¹ '''T''' ⁻¹ <ref>Engineering Thermodynamics Work and Heat Transfer, Rogers and Mayhew 1967, {{ISBN| 9780582447271}}, p. 15</ref> The object of the jet engine is to produce thrust which it does by increasing the momentum of the air passing through it. But thrust isn't caused by the change in momentum. It's caused by the rate of change in momentum. So thrust, which is a force, has to have the same dimensions as rate of change of momentum, not momentum. Efficiences may be expressed as ratios of energy rate or power which has the same dimensions.

Force dimensions are '''M'''¹ '''L'''¹ '''T'''⁻² , momentum has dimensions '''M'''¹'''L'''¹ '''T'''⁻¹ and rate of change of momentum has dimensions '''M'''¹ '''L'''¹'''T'''⁻², ie the same as force. Work and energy are similar quantities with dimensions '''M'''¹ '''L'''²'''T'''⁻². Power has dimensions '''M'''¹ '''L'''²'''T'''⁻³.<ref>https://archive.org/details/masslengthtime0000norm_v5r2/page/150/mode/2up, Mass, Length and Time, Norman Feather 1959, p. 150</ref>