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Summer Internship at Cranfield University-Report

S
Sathyanarayanan Nagasundaram

This document summarizes a student internship project on gas turbine performance simulation undertaken at Cranfield University. The project involved using Turbomatch software to simulate the off-design performance of 3 turbofan engines - CFM56-7B27, Rolls Royce Trent 1000, and Pratt & Whitney 4084. The student analyzed compressor maps, plotted performance parameters like thrust and SFC against turbine inlet temperature and ambient temperature, and compared results between 2 versions of Turbomatch software. The analysis provided insights into engine operation and limitations as well as improvements in the new Turbomatch version.

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TITLE GAS TURBINE PERFORMANCE SIMULATION STUDENT INTERNSHIP PROJECT UNDERTAKEN AT CRANFIELD UNIVERSITY BY N.SATHYANARAYANAN IV YEAR –MECHANICAL INDIAN INSTITUTE OF INFORMATION TECHNOLOGY DESIGN AND MANUFACURING – KANCHEEPURAM
REPORT SUBMITTED IN JULY 2013 CONTENTS 1. Acknowledgement 2. Introduction to Gas Turbines 3. A short note on Gas Turbine Performance Simulation and TURBOMATCH 4. Problem statement of the project 5. Engine Discussions 6. Analysis and Conclusions 7. Bibliography
ACKNOWLEDGEMENT At the outset I would like to acknowledge with thanks to the Department of Power and Propulsion, Cranfield University for permitting me to undergo a summer research internship in their department. I was offered an interesting problem to work on. Thanks are due to my supervisor Dr.Theoklis Nikolaidis, Lecturer, Department of Power and Propulsion, for explaining the technicalities and providing guidance at various stages in completing this internship study. I would also like to express my gratitude to Prof.Pericles Pilidis, Head of Department, for accepting my Visiting Student application, and to Ms. Faye Winstanlet and Ms.Clarie Bellis, for helping me with the application process. The internship has provided me with an insight into the component characteristics and performance characteristics of Gas Turbines. Thanks are also due to Dr.R.Gnanamoorthy, Director and Dr.K.Selvajyothi, Assistant Professor of our institute IIIT DM, Kancheepuram for encouraging us to undergo summer internship and also for providing with necessary letters of introduction in securing this internship N.SATHYANARAYANAN
INTRODUCTION TO GAS TURBINES A gas turbine is a type of an internal combustion engine, operating on Brayton cycle. With its high power-weight ratio the gas turbine engines have dominated the area of aerospace propulsion for quite some time now. It is becoming an increasingly popular prime mover in the power, process and oil industries. Some components of a gas turbine engine vary based on the application, even though there are three basic components that are common to a gas turbine engine. A compressor, combustor and a turbine. The compressor does the function of increasing the pressure of the incoming air thus facilitating combustion, and aiding power extraction in the turbine. From a compressor, the high pressure air enters the combustor, where fuel is injected to increase the energy and temperature of the gas. The hot, high pressure, high energy air then passes through the turbine where the enthalpy of the gas is converted into the rotational energy of the turbine. A typical ideal Brayton cycle is shown below. Image courtesy: Wikipedia
Since the project involved working on turbofan aero-engines, a bit more detailed discussion on aero engines will be done in the forthcoming section. An aero-engine has an intake, through which the air from the atmosphere passes into the engine, and is followed by compressor(s), combustor(s) and turbine(s) in the core. The aero-engine has a propelling nozzle in the core following the turbine(s), that converts the pressure energy of the gases to kinetic energy, thus accelerating the fluid. In case of turbofan engines there is bypass duct through which the air sucked by the frontal fan is bypassed. It is followed by a propelling nozzle. The thrust required by the aircraft if provided by the propelling nozzle(s), according to Newton’s third law. A descriptive picture and theory of thrust generation is given in the extract below.
Image courtesy: Gas turbine Theory, Cohens, Rogers, Saravanamuttoo A turbofan engine has a fan after the intake, which is a low pressure compressor and sucks in huge amounts of air so as to provide the required thrust. High mass flow rate facilitates reduction of exit velocity which also reduces the noise generated by the aero-engine. The net thrust generated by the turbofan engine equals the thrust generated by the bypass channel and that generated by the core. Turbofan engines can be classified into 2 spool or 3 spool engines. A spool can be said to consist of a turbine which runs either a single compressor or multiple compressors. Multi-spool engines facilitate running of the different turbines and their corresponding compressors to run at different rotating speeds, which is very important to avoid problems like stalling and surging in compressors. A cutaway diagram of a Rolls Royce Trent-900 is shown below: Trent-900 is a high bypass three spool turbofan aero-engine.
Image Courtesy: Google GAS TURBINE PERFORMANCE SIMULATION AND TURBOMATCH: With development in computational power and numerical tools in the recent past, a lot of emphasis has been laid on numerical simulations for getting the required Design and Performance results required, since it involves lesser time and money. For an aeroengine, the performance of an engine could be talked about in terms of Specific thrust, Thrust produced by the engine and the specific fuel consumption, given a particular running condition.
Performance prediction is something that could not be done by manual calculations and there arises a need for a computational tool to perform the simulation that is required. TURBOMATCH, an in-house code developed in the School of Mechanical Engineering, Cranfield University is one such code that predicts the performance of a gas turbine engine under a given condition. COMPRESSOR AND TURBINE MAPS: Compressor maps and turbine maps are a graphical representation of a behaviour of compressors and turbines under different rotational speeds, mass flow rates, entry total temperatures and entry total pressures. These maps are crucial in predicting the performance characteristics of a gas turbine engine. A typical compressor map has the pressure ratios and the efficiencies plotted for a range of values of non-dimensional speeds and non-dimensional mass flow rates. A typical turbine has non-dimensional mass flow rate plotted against the ratio of total pressure ratio at the entry to that at the exit for various non-dimensional speeds. In this project report, the compressor map has corrected mass flow in (Kg/s) on the X-axis and pressure ratio on the Y-axis. Corrected Flow is the mass flow that would pass through a device (e.g. compressor, bypass duct, etc.) if the inlet pressure and temperature corresponded to ambient conditions at Sea Level, on a Standard Day Typical representations of a compressor map and a turbine map are given below.
COMPRESSOR MAP Image courtesy: Gas turbine Theory, Cohens, Rogers, Saravanamuttoo
TURBINE MAP Image courtesy: Gas Turbine Theory, Cohens, Rogers, Saravanamuttoo
WORKING OF TURBOMATCH: Turbomatch is an iterative FORTRAN code that runs a series of calculations based on off-design matching process. Turbomatch has a set of inbuilt compressor and turbine maps which are scaled according to fit the given design conditions of a particular gas turbine engine. The scaled compressor map is then used as a tool to predict the off-design performance characteristics of the engine. The modelling of the engine is done using a .dat file consisting of various codewords called “BRICKS”, that represent the various components of an engine like Intake, Compressor, Gas Duct, Turbine, Nozzle, Heat exchanger etc. The data that is required by the code to do the performance calculations are fed in the form of brick data and Station Vectors. The numerical results are then extracted in excel and the comparison of value is done using spreadsheets and graphs. The compressor map is then plotted by using the scaled compressor map data values and the running lines for various compressors at different conditions are plotted and analysed. PROBLEM STATEMENT: 3 turbofan high bypass aero-engines namely, i.) CFM-56-7B27 ii.) Rolls Royce Trent 1000 iii.)Pratt and Whitney 4084, were chosen for the project.
The project involved simulating the off-design conditions for the above- mentioned aero-engines on Turbomatch version 1 and the in-development Turbomatch Version 2. The project involved: 1.) Plotting the running lines and graphs for SFC, Specific thrust and Net thrust vs TET, for different flight mach numbers and altitudes. 2.) Studying the variation of takeoff thrust, SFC and specific thrust with variation in ambient temperature, for a constant TET. 3.) Finding the errors between numerical values and compare running lines predicted by the two versions of Turbomatch, for different off design conditions. ENGINE DISCUSSIONS: CFM56-7B-27: CFM56-7B-27 is a high bypass 2 spool turbo-fan aero-engine powering Boeing- 777. The engine has a single stage fan (low pressure compressor) and the intermediate 3-stage compressor(booster) on the same spool, which is driven by a 4-stage low pressure Turbine. It has a 9-stage high pressure compressor on the second spool which is driven by a 1-stage high pressure turbine. Technical specifications at takeoff(Rated to ISA conditions): Mass flow rate into the engine=354 Kg/s Overall pressure ratio=32.8 Turbine entry temperature=1600 K Bypass ratio=5.1 Net thrust=121 KN
PW 4084: PW 4084 is a high bypass 2 spool turbo-fan aero-engine powering Boeing-737. The engine has a single stage fan (low pressure compressor) and the intermediate 5-stage compressor(booster) on the same spool, which is driven by a 5-stage low pressure Turbine. It has a 15-stage(5 stages variable) high pressure compressor on the second spool which is driven by a 2-stage high pressure turbine. Technical specifications at takeoff(Flat-Rated to +15 K deviation ISA conditions): Mass flow rate into the engine=1157 Kg/s Overall pressure ratio=34.2 Turbine entry temperature=1705 K Bypass ratio=6.41 Net thrust=373.8 KN TRENT-1000: Trent-1000 is a high bypass 3 spool turbo-fan aero-engine powering Boeing- 787. The engine has a single stage fan (low pressure compressor) , which is driven by a 6-stage low pressure Turbine, an 8-stage intermediate pressure compressor on the second spool which is driven by a 1-stage intermediate pressure turbine, and a 6-stage high pressure turbine driven by a single-stage high pressure turbine. Technical specifications at takeoff (Rated to +15K deviation from ISA conditions): Mass flow rate into the engine=1199.30 Kg/s Overall pressure ratio=44.72 Turbine entry temperature=1820 K Bypass ratio=10.38
Net thrust=309 KN ANALYSIS AND CONCLUSIONS: CFM56-7B27: RUNNING LINES: The running lines of the compressors got for CFM56 are given below: (TM-2) Running lines for the fan
Running lines for the booster compressor
Running lines for the high pressure compressor
COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
Running line comparison for Intermediate compressor:
Running line comparision for high pressure compressor INFERENCES: 1.) It could be said that the operating region of the CFM-56 fan lies below the surge line for altitudes between 0 and 8000 metres and between speeds of M=0 and M=0.8.
2.) The surge margin of the fan is very low for non dimensional running speeds beyond 1.06. So care needs to be taken when the engine is operated in the region. 3.) The running lines for for different altitudes and a constant number are almost constant for the fan. 4.) The intermediate compressor severely limits the running speed of the spool, though. 5.) Since the square roots of total temperature at the entry of the fan and intermediate compressor are comparable, we could say the same about their non dimensional speeds at a particular running condition. 6.) The running lines of the intermediate compressor clearly imply that the spool is free to operate at any speed for Mach numbers between 0 and 0.4 . 7.) Beyond a Mach number of 0.4, care needs to be taken to ensure that the CN of the fan is lies between 0.85 and 1.15 to ensure smooth running of both the fan and intermediate compressor. 8.) High pressure compressor could be operated safely for any Mach number between 0 and 0.8 and at any altitude between 0 and 8000m, without surging problem, eventhough the thrust required at a particular condition might restrict the operating condition. Running lines lie in a very narrow region implying good running stability. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) The interpolation feature in Turbomatch-2 helps predict the running lines beyond the surge line. 2.) Turbomatch-2 predicted fairly smooth running lines while Turbomatch-1 showed wavy fluctuations in running lines whenever the running line approached the surge line. The differences are clearly visible in the results predicted for the intermediate compressor.
SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted. Thrust vs TET for Altitude=2000m 1.) As expected for a given TET, thrust decreases with increasing Mach number owing it to the increased mass flow into the engine, and thus a reduction in the overall pressure ratio of then engine, failure of ram pressure increase to compensate for the decrease in pressure ratio and also to higher momentum drag. 2.) As expected, increase in TET increases the net thrust produced, for a given mach number.
Specific thrust vs TET for Altitude=2000m 1.) As expected the specific thrust increased with an increase in turbine inlet temperature for a particular mach number. 2.) For a given turbine inlet temperature, increase in Mach number reduces the specific thurst owing it to increase in momentum drag.
SFC vs TET for Altitude=2000m 1.) With the increase in turbine inlet temperature there is an increase in the rotational speed of the spool, thus increasing the overall pressure ratio and the overall thrust. So a drop in SFC with increase in TET is clearly noticeable. 2.) Though SFC falls initially, the SFC starts increasing from a particular point on the curve. This could be attributed to the choking of the nozzle that occurs with an increase in mass flow rate due to increase in rotational speed.
3.) After the point of choking, there is no increase in thrust due to momentum thrust, eventhough there is an increase in pressure thrust. But the increase in overall thrust does not compensate proportionally for the increase in pressure thrust, thus increasing the SFC. Similar curves obtained for flight altitude=4000m, 6000m and 8000m show a similar trend. VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1600 K)
SFC vs Ambient Temperature(TET=1600 K) Specific thrust vs Ambient Temperature(TET=1600 K)
INFERENCES: 1.) For a given TET, thrust increases almost linearly, with decrease in ambient temperature. 2.) SFC and specific thrust increase with decrease in ambient temperature. There is an increase in fuel consumption, because lower ambient temperature thermodynamically causes lesser temperature at the entrance of combustor, thus requiring more fuel to be burnt to reach the required TET. 3.) The graphs clearly imply that achieving a certain amount of thrust consumes lesser fuel with reduction in ambient temperature and requires a lesser TET, since a lower rotational speed would balance out the reduction in temperature and give the required value of CN, to generate the required amount of thrust. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for Ambient temperature Off- design conditions TM1 value TM2 value %error Atttribute: Temperature deviation from ISA condtions(K) 168450 163260.0000 3.0810329 -50.0 164630 159470.0000 3.1343012 -45.0 160880 155510.0000 3.3378916 -40.0
157220 151560.0000 3.6000509 -35.0 153590 147490.0000 3.9716127 -30.0 149930 143190.0000 4.4954312 -25.0 146010 138900.0000 4.8695295 -20.0 142520 134700.0000 5.4869492 -15.0 138510 130630.0000 5.6891199 -10.0 134510 126660.0000 5.8359973 -5.0 130460 122480.0000 6.1168174 0.0 126470 118350.0000 6.420495 5.0 122760 114200.0000 6.9729554 10.0 119150 110260.0000 7.4611834 15.0 114470 105600.0000 7.7487551 20.0 110120 101180.0000 8.1184163 25.0 106180 97072.0000 8.5778866 30.0 102050 93284.0000 8.5899069 35.0 98008 89427.0000 8.7554077 40.0 94160 85562.0000 9.1312659 45.0 90149 81765.0000 9.3001586 50.0 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. The error varied between 3 to 9 percent, with Turbomatch-1 predicting higher values than those predicted by Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers. The maximum error between the thrust values predicted by the two versions was found to be around 5 KN and errors were found to lie within +/- 7 percentage, unless the value of net thrust was very low (< 5KN)
PW-4084: RUNNING LINES: The running lines of the compressors of the PW-4084 engine are shown below.(As predicted by Turbomatch-2) Running lines for the fan
Running lines for booster compressor
Running lines for high pressure compressor
COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
Running lines comparision for intermediate compressor
Running lines comparison for high pressure compressor INFERENCES: 1.) There were striking similarities between the running lines of the respective compressors of CFM-56 and PW-4084
2.) This could be owed to the fact that both engines are high bypass 2 spool engines with similar configuration of the spools. 3.) Like in CFM-56 engine, the intermediate compressor restricts the operating speed of the spool. 4.) The running lines for a given Mach number and various altitude almost lie on a same line. 5.) CN of the fan needs to be kept below 1.10 to ensure a safe surge margin, always. 6.) Even though for M<0.4, the spool can be operated at any CN<1.10, for mach numbers close to 0.4, CN must be kept above 0.5 to ensure smooth operation and giving the compressor sufficient surge margin. 7.) Above a speed of M=0.4, care must be taken to ensure that the non- dimensional speed of the intermediate compressor is above 0.80 and below 1.10 to ensure that there is fairly sufficient surge margin. 8.) The high pressure compressor is safe to operate at any non-dimensional speed less than 1.15 for any altitude between 0 to 8000m and for any mach number between 0 and 0.8, without any surging problem, even though thrust required might restrict the operating range. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) The interpolation feature in Turbomatch-2 helps predict the running lines beyond the surge line, while the running line predicted just coincided with the surge line. SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted.
Thrust vs TET for Altitude=2000m Specific thrust vs TET for Altitude=2000m
SFC vs TET for Altitude=2000m The reasons for the trends observed in the graphs are the same as those mentioned in the inferences section of CFM-56 engine. VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1705 K)
Specific thrust vs Ambient temperature(TET=1705 K) SFC vs Ambient temperature(TET=1705 K)
INFERENCES: The reasons for the trend observed are the same as those mentioned in CFM- 56 case study. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for rotational speed(PCN) off- design conditions(Altitude=2000m,M=0.2) TM1 value TM2 value %error Attribute: Change in PCN(Alt=2000m,M=0.2) 350890 329190.0000 6.1842743 1.0500 288150 277470.0000 3.7064029 1.0000 236840 233840.0000 1.2666779 0.9500 202390 201140.0000 0.6176194 0.9000 172190 173280.0000 -0.633022 0.8500 145400 173280.0000 -19.17469 0.8000 121620 127760.0000 -5.048512 0.750 100360 104890.0000 -4.51375 0.700 80586 86080.0000 -6.817561 0.650 62412 68379.0000 -9.560661 0.600 48418 54361.0000 -12.27436 0.550 37715 41899.0000 -11.09373 0.500 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers.
The maximum error between the thrust values predicted by the two versions was found to be around 20 KN and errors were found to lie within +/- 8 percentage, unless the value of net thrust was lower than or 50KN where error was found to be higher more than 20 percent since there was around 15 KN error constantly between the 2 versions of Turbomatch. For ambient temperature off-design conditions, the error was found to be very low and less than (+/-) 1 percent.
TRENT 1000: RUNNING LINES: The running lines of the compressors of the Trent-1000 engine are shown below.(As predicted by Turbomatch-2) Running lines for the fan
Running lines for intermediate compressor
Running lines for the high pressure compressor
COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
Running line comparison for intermediate compressor
Running lines comparison for high pressure compressor
Inferences: 1.) All the compressors are safe to work at any rotational speed for altitudes between 0 to 8000 m and Mach numbers between 0 to 0.85, without surging problems, even though the required thrust at a particular operating condition might restrict the compressor working range. 2.) The intermediate compressor and the high pressure compressor have a narrow working region, which implies good functional stability. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) There were only subtle differences between running lines predicted by the 2 versions of turbomatch, as the surge margin of the running lines was quite sufficient for Turbomatch-1 to give smooth running lines without any problems. SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted. Thrust vs TET for Altitude=2000m
Specific thrust vs TET for Altitude=2000m SFC vs TET for Altitude=2000m The reasons for the trends observed in the graphs are the same as those mentioned in the inferences section of CFM-56 engine.
VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1820 K) Specific thrust vs Ambient temperature(TET=1820 K)
SFC vs Ambient temperature(TET=1820 K) INFERENCES: The reasons for the trend observed are the same as those mentioned in CFM- 56 case study. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for rotational speed(PCN) off- design conditions(Altitude=2000m,M=0.2) TM1 value TM2 value %error Attribute: Change in PCN at Alt=2000m,M=0.2 202580 205150.0000 -1.268635 1.000 177830 177860.0000 -0.01687 0.950 154070 155970.0000 -1.233206 0.900
132450 135490.0000 -2.295206 0.850 95510 95776.0000 -0.278505 0.750 77830 78814.0000 -1.264294 0.700 61078 63256.0000 -3.565932 0.650 48521 50381.0000 -3.833392 0.600 38414 39112.0000 -1.817046 0.550 29633 30581.0000 -3.199136 0.500 22013 23075.0000 -4.824422 0.450 15437 16335.0000 -5.817192 0.400 10113 10223.0000 -1.087709 0.350 6300.3 5188.5000 17.646779 0.300 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers. The maximum error between the thrust values predicted by the two versions was found to be around 3 KN and errors were found to lie within (+/-) seven percentage, unless the value of net thrust was lower than or around 3KN where error was found to be higher more than 20 percent since there was around 2 KN error constantly between the 2 versions of Turbomatch. For ambient temperature off-design conditions, the error was found to be less than (+/-) 5 percent. CONCLUSION: The following things were done successfully using TURBOMATCH versions 1 and 2 for the 3 engines, namely CFM56-7B27, PW-4084 and TRENT-1000 1.) Plotting the running lines and graphs for SFC, Specific thrust and Net thrust vs TET, for different flight mach numbers and altitudes. 2.) Studying the variation of takeoff thrust, SFC and specific thrust with variation in ambient temperature, for a constant TET.
3.) Finding the errors between numerical values and compare running lines predicted by the two versions of Turbomatch, for different off design conditions. BIBLIOGRAPHY: 1.)H Cohen, GFC Rogers, HIH Saravanamutto, Gas Turbine Theory 4th edition, Longman group limited 2.)Dr. Vasilios Pachidis, Gas Turbine Performance simulation 3.)www.wikipedia.org 4.)www.google.com 5.)www.cfmaeroengines.com 6.)www.pw.utc.com 7.)www.rolls-royce.com

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Summer Internship at Cranfield University-Report

  • 1. TITLE GAS TURBINE PERFORMANCE SIMULATION STUDENT INTERNSHIP PROJECT UNDERTAKEN AT CRANFIELD UNIVERSITY BY N.SATHYANARAYANAN IV YEAR –MECHANICAL INDIAN INSTITUTE OF INFORMATION TECHNOLOGY DESIGN AND MANUFACURING – KANCHEEPURAM
  • 2. REPORT SUBMITTED IN JULY 2013 CONTENTS 1. Acknowledgement 2. Introduction to Gas Turbines 3. A short note on Gas Turbine Performance Simulation and TURBOMATCH 4. Problem statement of the project 5. Engine Discussions 6. Analysis and Conclusions 7. Bibliography
  • 3. ACKNOWLEDGEMENT At the outset I would like to acknowledge with thanks to the Department of Power and Propulsion, Cranfield University for permitting me to undergo a summer research internship in their department. I was offered an interesting problem to work on. Thanks are due to my supervisor Dr.Theoklis Nikolaidis, Lecturer, Department of Power and Propulsion, for explaining the technicalities and providing guidance at various stages in completing this internship study. I would also like to express my gratitude to Prof.Pericles Pilidis, Head of Department, for accepting my Visiting Student application, and to Ms. Faye Winstanlet and Ms.Clarie Bellis, for helping me with the application process. The internship has provided me with an insight into the component characteristics and performance characteristics of Gas Turbines. Thanks are also due to Dr.R.Gnanamoorthy, Director and Dr.K.Selvajyothi, Assistant Professor of our institute IIIT DM, Kancheepuram for encouraging us to undergo summer internship and also for providing with necessary letters of introduction in securing this internship N.SATHYANARAYANAN
  • 4. INTRODUCTION TO GAS TURBINES A gas turbine is a type of an internal combustion engine, operating on Brayton cycle. With its high power-weight ratio the gas turbine engines have dominated the area of aerospace propulsion for quite some time now. It is becoming an increasingly popular prime mover in the power, process and oil industries. Some components of a gas turbine engine vary based on the application, even though there are three basic components that are common to a gas turbine engine. A compressor, combustor and a turbine. The compressor does the function of increasing the pressure of the incoming air thus facilitating combustion, and aiding power extraction in the turbine. From a compressor, the high pressure air enters the combustor, where fuel is injected to increase the energy and temperature of the gas. The hot, high pressure, high energy air then passes through the turbine where the enthalpy of the gas is converted into the rotational energy of the turbine. A typical ideal Brayton cycle is shown below. Image courtesy: Wikipedia
  • 5. Since the project involved working on turbofan aero-engines, a bit more detailed discussion on aero engines will be done in the forthcoming section. An aero-engine has an intake, through which the air from the atmosphere passes into the engine, and is followed by compressor(s), combustor(s) and turbine(s) in the core. The aero-engine has a propelling nozzle in the core following the turbine(s), that converts the pressure energy of the gases to kinetic energy, thus accelerating the fluid. In case of turbofan engines there is bypass duct through which the air sucked by the frontal fan is bypassed. It is followed by a propelling nozzle. The thrust required by the aircraft if provided by the propelling nozzle(s), according to Newton’s third law. A descriptive picture and theory of thrust generation is given in the extract below.
  • 6. Image courtesy: Gas turbine Theory, Cohens, Rogers, Saravanamuttoo A turbofan engine has a fan after the intake, which is a low pressure compressor and sucks in huge amounts of air so as to provide the required thrust. High mass flow rate facilitates reduction of exit velocity which also reduces the noise generated by the aero-engine. The net thrust generated by the turbofan engine equals the thrust generated by the bypass channel and that generated by the core. Turbofan engines can be classified into 2 spool or 3 spool engines. A spool can be said to consist of a turbine which runs either a single compressor or multiple compressors. Multi-spool engines facilitate running of the different turbines and their corresponding compressors to run at different rotating speeds, which is very important to avoid problems like stalling and surging in compressors. A cutaway diagram of a Rolls Royce Trent-900 is shown below: Trent-900 is a high bypass three spool turbofan aero-engine.
  • 7. Image Courtesy: Google GAS TURBINE PERFORMANCE SIMULATION AND TURBOMATCH: With development in computational power and numerical tools in the recent past, a lot of emphasis has been laid on numerical simulations for getting the required Design and Performance results required, since it involves lesser time and money. For an aeroengine, the performance of an engine could be talked about in terms of Specific thrust, Thrust produced by the engine and the specific fuel consumption, given a particular running condition.
  • 8. Performance prediction is something that could not be done by manual calculations and there arises a need for a computational tool to perform the simulation that is required. TURBOMATCH, an in-house code developed in the School of Mechanical Engineering, Cranfield University is one such code that predicts the performance of a gas turbine engine under a given condition. COMPRESSOR AND TURBINE MAPS: Compressor maps and turbine maps are a graphical representation of a behaviour of compressors and turbines under different rotational speeds, mass flow rates, entry total temperatures and entry total pressures. These maps are crucial in predicting the performance characteristics of a gas turbine engine. A typical compressor map has the pressure ratios and the efficiencies plotted for a range of values of non-dimensional speeds and non-dimensional mass flow rates. A typical turbine has non-dimensional mass flow rate plotted against the ratio of total pressure ratio at the entry to that at the exit for various non-dimensional speeds. In this project report, the compressor map has corrected mass flow in (Kg/s) on the X-axis and pressure ratio on the Y-axis. Corrected Flow is the mass flow that would pass through a device (e.g. compressor, bypass duct, etc.) if the inlet pressure and temperature corresponded to ambient conditions at Sea Level, on a Standard Day Typical representations of a compressor map and a turbine map are given below.
  • 9. COMPRESSOR MAP Image courtesy: Gas turbine Theory, Cohens, Rogers, Saravanamuttoo
  • 10. TURBINE MAP Image courtesy: Gas Turbine Theory, Cohens, Rogers, Saravanamuttoo
  • 11. WORKING OF TURBOMATCH: Turbomatch is an iterative FORTRAN code that runs a series of calculations based on off-design matching process. Turbomatch has a set of inbuilt compressor and turbine maps which are scaled according to fit the given design conditions of a particular gas turbine engine. The scaled compressor map is then used as a tool to predict the off-design performance characteristics of the engine. The modelling of the engine is done using a .dat file consisting of various codewords called “BRICKS”, that represent the various components of an engine like Intake, Compressor, Gas Duct, Turbine, Nozzle, Heat exchanger etc. The data that is required by the code to do the performance calculations are fed in the form of brick data and Station Vectors. The numerical results are then extracted in excel and the comparison of value is done using spreadsheets and graphs. The compressor map is then plotted by using the scaled compressor map data values and the running lines for various compressors at different conditions are plotted and analysed. PROBLEM STATEMENT: 3 turbofan high bypass aero-engines namely, i.) CFM-56-7B27 ii.) Rolls Royce Trent 1000 iii.)Pratt and Whitney 4084, were chosen for the project.
  • 12. The project involved simulating the off-design conditions for the above- mentioned aero-engines on Turbomatch version 1 and the in-development Turbomatch Version 2. The project involved: 1.) Plotting the running lines and graphs for SFC, Specific thrust and Net thrust vs TET, for different flight mach numbers and altitudes. 2.) Studying the variation of takeoff thrust, SFC and specific thrust with variation in ambient temperature, for a constant TET. 3.) Finding the errors between numerical values and compare running lines predicted by the two versions of Turbomatch, for different off design conditions. ENGINE DISCUSSIONS: CFM56-7B-27: CFM56-7B-27 is a high bypass 2 spool turbo-fan aero-engine powering Boeing- 777. The engine has a single stage fan (low pressure compressor) and the intermediate 3-stage compressor(booster) on the same spool, which is driven by a 4-stage low pressure Turbine. It has a 9-stage high pressure compressor on the second spool which is driven by a 1-stage high pressure turbine. Technical specifications at takeoff(Rated to ISA conditions): Mass flow rate into the engine=354 Kg/s Overall pressure ratio=32.8 Turbine entry temperature=1600 K Bypass ratio=5.1 Net thrust=121 KN
  • 13. PW 4084: PW 4084 is a high bypass 2 spool turbo-fan aero-engine powering Boeing-737. The engine has a single stage fan (low pressure compressor) and the intermediate 5-stage compressor(booster) on the same spool, which is driven by a 5-stage low pressure Turbine. It has a 15-stage(5 stages variable) high pressure compressor on the second spool which is driven by a 2-stage high pressure turbine. Technical specifications at takeoff(Flat-Rated to +15 K deviation ISA conditions): Mass flow rate into the engine=1157 Kg/s Overall pressure ratio=34.2 Turbine entry temperature=1705 K Bypass ratio=6.41 Net thrust=373.8 KN TRENT-1000: Trent-1000 is a high bypass 3 spool turbo-fan aero-engine powering Boeing- 787. The engine has a single stage fan (low pressure compressor) , which is driven by a 6-stage low pressure Turbine, an 8-stage intermediate pressure compressor on the second spool which is driven by a 1-stage intermediate pressure turbine, and a 6-stage high pressure turbine driven by a single-stage high pressure turbine. Technical specifications at takeoff (Rated to +15K deviation from ISA conditions): Mass flow rate into the engine=1199.30 Kg/s Overall pressure ratio=44.72 Turbine entry temperature=1820 K Bypass ratio=10.38
  • 14. Net thrust=309 KN ANALYSIS AND CONCLUSIONS: CFM56-7B27: RUNNING LINES: The running lines of the compressors got for CFM56 are given below: (TM-2) Running lines for the fan
  • 15. Running lines for the booster compressor
  • 16. Running lines for the high pressure compressor
  • 17. COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
  • 18. Running line comparison for Intermediate compressor:
  • 19. Running line comparision for high pressure compressor INFERENCES: 1.) It could be said that the operating region of the CFM-56 fan lies below the surge line for altitudes between 0 and 8000 metres and between speeds of M=0 and M=0.8.
  • 20. 2.) The surge margin of the fan is very low for non dimensional running speeds beyond 1.06. So care needs to be taken when the engine is operated in the region. 3.) The running lines for for different altitudes and a constant number are almost constant for the fan. 4.) The intermediate compressor severely limits the running speed of the spool, though. 5.) Since the square roots of total temperature at the entry of the fan and intermediate compressor are comparable, we could say the same about their non dimensional speeds at a particular running condition. 6.) The running lines of the intermediate compressor clearly imply that the spool is free to operate at any speed for Mach numbers between 0 and 0.4 . 7.) Beyond a Mach number of 0.4, care needs to be taken to ensure that the CN of the fan is lies between 0.85 and 1.15 to ensure smooth running of both the fan and intermediate compressor. 8.) High pressure compressor could be operated safely for any Mach number between 0 and 0.8 and at any altitude between 0 and 8000m, without surging problem, eventhough the thrust required at a particular condition might restrict the operating condition. Running lines lie in a very narrow region implying good running stability. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) The interpolation feature in Turbomatch-2 helps predict the running lines beyond the surge line. 2.) Turbomatch-2 predicted fairly smooth running lines while Turbomatch-1 showed wavy fluctuations in running lines whenever the running line approached the surge line. The differences are clearly visible in the results predicted for the intermediate compressor.
  • 21. SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted. Thrust vs TET for Altitude=2000m 1.) As expected for a given TET, thrust decreases with increasing Mach number owing it to the increased mass flow into the engine, and thus a reduction in the overall pressure ratio of then engine, failure of ram pressure increase to compensate for the decrease in pressure ratio and also to higher momentum drag. 2.) As expected, increase in TET increases the net thrust produced, for a given mach number.
  • 22. Specific thrust vs TET for Altitude=2000m 1.) As expected the specific thrust increased with an increase in turbine inlet temperature for a particular mach number. 2.) For a given turbine inlet temperature, increase in Mach number reduces the specific thurst owing it to increase in momentum drag.
  • 23. SFC vs TET for Altitude=2000m 1.) With the increase in turbine inlet temperature there is an increase in the rotational speed of the spool, thus increasing the overall pressure ratio and the overall thrust. So a drop in SFC with increase in TET is clearly noticeable. 2.) Though SFC falls initially, the SFC starts increasing from a particular point on the curve. This could be attributed to the choking of the nozzle that occurs with an increase in mass flow rate due to increase in rotational speed.
  • 24. 3.) After the point of choking, there is no increase in thrust due to momentum thrust, eventhough there is an increase in pressure thrust. But the increase in overall thrust does not compensate proportionally for the increase in pressure thrust, thus increasing the SFC. Similar curves obtained for flight altitude=4000m, 6000m and 8000m show a similar trend. VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1600 K)
  • 25. SFC vs Ambient Temperature(TET=1600 K) Specific thrust vs Ambient Temperature(TET=1600 K)
  • 26. INFERENCES: 1.) For a given TET, thrust increases almost linearly, with decrease in ambient temperature. 2.) SFC and specific thrust increase with decrease in ambient temperature. There is an increase in fuel consumption, because lower ambient temperature thermodynamically causes lesser temperature at the entrance of combustor, thus requiring more fuel to be burnt to reach the required TET. 3.) The graphs clearly imply that achieving a certain amount of thrust consumes lesser fuel with reduction in ambient temperature and requires a lesser TET, since a lower rotational speed would balance out the reduction in temperature and give the required value of CN, to generate the required amount of thrust. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for Ambient temperature Off- design conditions TM1 value TM2 value %error Atttribute: Temperature deviation from ISA condtions(K) 168450 163260.0000 3.0810329 -50.0 164630 159470.0000 3.1343012 -45.0 160880 155510.0000 3.3378916 -40.0
  • 27. 157220 151560.0000 3.6000509 -35.0 153590 147490.0000 3.9716127 -30.0 149930 143190.0000 4.4954312 -25.0 146010 138900.0000 4.8695295 -20.0 142520 134700.0000 5.4869492 -15.0 138510 130630.0000 5.6891199 -10.0 134510 126660.0000 5.8359973 -5.0 130460 122480.0000 6.1168174 0.0 126470 118350.0000 6.420495 5.0 122760 114200.0000 6.9729554 10.0 119150 110260.0000 7.4611834 15.0 114470 105600.0000 7.7487551 20.0 110120 101180.0000 8.1184163 25.0 106180 97072.0000 8.5778866 30.0 102050 93284.0000 8.5899069 35.0 98008 89427.0000 8.7554077 40.0 94160 85562.0000 9.1312659 45.0 90149 81765.0000 9.3001586 50.0 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. The error varied between 3 to 9 percent, with Turbomatch-1 predicting higher values than those predicted by Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers. The maximum error between the thrust values predicted by the two versions was found to be around 5 KN and errors were found to lie within +/- 7 percentage, unless the value of net thrust was very low (< 5KN)
  • 28. PW-4084: RUNNING LINES: The running lines of the compressors of the PW-4084 engine are shown below.(As predicted by Turbomatch-2) Running lines for the fan
  • 29. Running lines for booster compressor
  • 30. Running lines for high pressure compressor
  • 31. COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
  • 32. Running lines comparision for intermediate compressor
  • 33. Running lines comparison for high pressure compressor INFERENCES: 1.) There were striking similarities between the running lines of the respective compressors of CFM-56 and PW-4084
  • 34. 2.) This could be owed to the fact that both engines are high bypass 2 spool engines with similar configuration of the spools. 3.) Like in CFM-56 engine, the intermediate compressor restricts the operating speed of the spool. 4.) The running lines for a given Mach number and various altitude almost lie on a same line. 5.) CN of the fan needs to be kept below 1.10 to ensure a safe surge margin, always. 6.) Even though for M<0.4, the spool can be operated at any CN<1.10, for mach numbers close to 0.4, CN must be kept above 0.5 to ensure smooth operation and giving the compressor sufficient surge margin. 7.) Above a speed of M=0.4, care must be taken to ensure that the non- dimensional speed of the intermediate compressor is above 0.80 and below 1.10 to ensure that there is fairly sufficient surge margin. 8.) The high pressure compressor is safe to operate at any non-dimensional speed less than 1.15 for any altitude between 0 to 8000m and for any mach number between 0 and 0.8, without any surging problem, even though thrust required might restrict the operating range. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) The interpolation feature in Turbomatch-2 helps predict the running lines beyond the surge line, while the running line predicted just coincided with the surge line. SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted.
  • 35. Thrust vs TET for Altitude=2000m Specific thrust vs TET for Altitude=2000m
  • 36. SFC vs TET for Altitude=2000m The reasons for the trends observed in the graphs are the same as those mentioned in the inferences section of CFM-56 engine. VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1705 K)
  • 37. Specific thrust vs Ambient temperature(TET=1705 K) SFC vs Ambient temperature(TET=1705 K)
  • 38. INFERENCES: The reasons for the trend observed are the same as those mentioned in CFM- 56 case study. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for rotational speed(PCN) off- design conditions(Altitude=2000m,M=0.2) TM1 value TM2 value %error Attribute: Change in PCN(Alt=2000m,M=0.2) 350890 329190.0000 6.1842743 1.0500 288150 277470.0000 3.7064029 1.0000 236840 233840.0000 1.2666779 0.9500 202390 201140.0000 0.6176194 0.9000 172190 173280.0000 -0.633022 0.8500 145400 173280.0000 -19.17469 0.8000 121620 127760.0000 -5.048512 0.750 100360 104890.0000 -4.51375 0.700 80586 86080.0000 -6.817561 0.650 62412 68379.0000 -9.560661 0.600 48418 54361.0000 -12.27436 0.550 37715 41899.0000 -11.09373 0.500 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers.
  • 39. The maximum error between the thrust values predicted by the two versions was found to be around 20 KN and errors were found to lie within +/- 8 percentage, unless the value of net thrust was lower than or 50KN where error was found to be higher more than 20 percent since there was around 15 KN error constantly between the 2 versions of Turbomatch. For ambient temperature off-design conditions, the error was found to be very low and less than (+/-) 1 percent.
  • 40. TRENT 1000: RUNNING LINES: The running lines of the compressors of the Trent-1000 engine are shown below.(As predicted by Turbomatch-2) Running lines for the fan
  • 41. Running lines for intermediate compressor
  • 42. Running lines for the high pressure compressor
  • 43. COMPARISION OF RUNNING LINES OBTAINED ON TM-1 AND TM-2: Running line comparison for fan
  • 44. Running line comparison for intermediate compressor
  • 45. Running lines comparison for high pressure compressor
  • 46. Inferences: 1.) All the compressors are safe to work at any rotational speed for altitudes between 0 to 8000 m and Mach numbers between 0 to 0.85, without surging problems, even though the required thrust at a particular operating condition might restrict the compressor working range. 2.) The intermediate compressor and the high pressure compressor have a narrow working region, which implies good functional stability. COMPARISON BETWEEN RUNNING LINES PREDICTED BY TM-1 AND TM-2: 1.) There were only subtle differences between running lines predicted by the 2 versions of turbomatch, as the surge margin of the running lines was quite sufficient for Turbomatch-1 to give smooth running lines without any problems. SFC,THRUST, SPECIFIC THRUST VS TET PLOTS AND INFERENCES: The figures below represent the plots predicted. Thrust vs TET for Altitude=2000m
  • 47. Specific thrust vs TET for Altitude=2000m SFC vs TET for Altitude=2000m The reasons for the trends observed in the graphs are the same as those mentioned in the inferences section of CFM-56 engine.
  • 48. VARIATION OF THRUST,SFC AND SPECIFIC THRUST WITH AMBIENT TEMPERATURE FOR CONSTANT TURBINE INLET TEMPERATURE: Thrust vs Ambient temperature(TET=1820 K) Specific thrust vs Ambient temperature(TET=1820 K)
  • 49. SFC vs Ambient temperature(TET=1820 K) INFERENCES: The reasons for the trend observed are the same as those mentioned in CFM- 56 case study. NUMERICAL ERROR ANALYSIS: The figure below shows the percentage of numerical error between the values predicted by Turbomatch 1 and Turbomatch 2. Numerical errors in thrust values predicted for rotational speed(PCN) off- design conditions(Altitude=2000m,M=0.2) TM1 value TM2 value %error Attribute: Change in PCN at Alt=2000m,M=0.2 202580 205150.0000 -1.268635 1.000 177830 177860.0000 -0.01687 0.950 154070 155970.0000 -1.233206 0.900
  • 50. 132450 135490.0000 -2.295206 0.850 95510 95776.0000 -0.278505 0.750 77830 78814.0000 -1.264294 0.700 61078 63256.0000 -3.565932 0.650 48521 50381.0000 -3.833392 0.600 38414 39112.0000 -1.817046 0.550 29633 30581.0000 -3.199136 0.500 22013 23075.0000 -4.824422 0.450 15437 16335.0000 -5.817192 0.400 10113 10223.0000 -1.087709 0.350 6300.3 5188.5000 17.646779 0.300 As expected there were differences between the values predicted by Turbomatch-1 and Turbomatch-2. Similarly, errors were found for net thrust values predicted for various off- design altitudes and mach numbers. The maximum error between the thrust values predicted by the two versions was found to be around 3 KN and errors were found to lie within (+/-) seven percentage, unless the value of net thrust was lower than or around 3KN where error was found to be higher more than 20 percent since there was around 2 KN error constantly between the 2 versions of Turbomatch. For ambient temperature off-design conditions, the error was found to be less than (+/-) 5 percent. CONCLUSION: The following things were done successfully using TURBOMATCH versions 1 and 2 for the 3 engines, namely CFM56-7B27, PW-4084 and TRENT-1000 1.) Plotting the running lines and graphs for SFC, Specific thrust and Net thrust vs TET, for different flight mach numbers and altitudes. 2.) Studying the variation of takeoff thrust, SFC and specific thrust with variation in ambient temperature, for a constant TET.
  • 51. 3.) Finding the errors between numerical values and compare running lines predicted by the two versions of Turbomatch, for different off design conditions. BIBLIOGRAPHY: 1.)H Cohen, GFC Rogers, HIH Saravanamutto, Gas Turbine Theory 4th edition, Longman group limited 2.)Dr. Vasilios Pachidis, Gas Turbine Performance simulation 3.)www.wikipedia.org 4.)www.google.com 5.)www.cfmaeroengines.com 6.)www.pw.utc.com 7.)www.rolls-royce.com