Home Technology Heat transfer distribution of single oblique jet impingement in crossflow under different inlet conditions
Article
Licensed
Unlicensed Requires Authentication

Heat transfer distribution of single oblique jet impingement in crossflow under different inlet conditions

  • Juan He , Qinghua Deng EMAIL logo , Kun Xiao and Zhenping Feng
Published/Copyright: April 13, 2022
Become an author with De Gruyter Brill
Author Information
International Journal of Turbo & Jet-Engines
From the journal International Journal of Turbo & Jet-Engines Volume 40 Issue s1

Abstract

To further reveal the interaction between crossflow and jet, single oblique jet impingement in crossflow is studied. The influences of Reynolds number (Re = 3750–15,000), oblique angle (θ = 50°–90°), jet intake mode (jet normal to inlet plane and jet along hole axis), crossflow ratio (CR = 0.1–0.3) and temperature ratio (TR = 1.0–1.2) are considered. For both jet intake modes, with the decrease of θ, the peak value of Nusselt number increases and its location shifts upstream. The Nusselt number for case of jet normal to inlet plane is higher than that of jet along hole axis with wider lateral coverage range. The CR affects the convection heat transfer between crossflow and target surface, and it also affects the interaction between crossflow and jet. Synthetically, the best heat transfer appears at CR = 0.2. The Nusselt number decreases sharply when TR goes from 1.0 to 1.1, while the decline trend slows down when TR goes from 1.1 to 1.2.

Keywords: crossflow ratio; jet impingement; jet intake mode; oblique angle; temperature ratio
Corresponding author: Qinghua Deng, Shaanxi Engineering Laboratory of Turbomachinery and Power Equipment, Institute of Turbomachinery, Xi’an Jiaotong University, Xi’an 710049, China, E-mail:

  1. Author contribution: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.

  2. Research funding: None declared.

  3. Conflict of interest statement: The authors declare no conflicts of interest regarding this article.

References

1. Martin, H. Heat and mass transfer between impinging gas jets and solid surfaces. Adv Heat Tran 1977;13:1–60, https://doi.org/10.1016/s0065-2717(08)70221-1.Search in Google Scholar

2. Viskanta, R. Heat transfer to impinging isothermal gas and flame jets. Exp Therm Fluid Sci 1993;6:111–34, https://doi.org/10.1016/0894-1777(93)90022-b.Search in Google Scholar

3. Goldstein, RJ, Behbahani, AI, Heppelmann, KK. Streamwise distribution of the recovery factor and the local heat transfer coefficient to an impinging circular air jet. Int J Heat Mass Tran 1986;29:1227–35, https://doi.org/10.1016/0017-9310(86)90155-9.Search in Google Scholar

4. Downs, SJ, James, EH. Jet impingement heat transfer-a literature survey. In: 24th national heat transfer conference and exhibition, Pennsylvania; 1987.Search in Google Scholar

5. Lee, DH, Chung, YS, Won, SY. The effect of concave surface curvature on heat transfer from a fully developed round impinging jet. Int J Heat Mass Tran 1999;42:2489–97, https://doi.org/10.1016/s0017-9310(98)00318-4.Search in Google Scholar

6. Mao, JK, Liu, ZX, Guo, W. Experiment of heat transfer on concave surface in single jet impingement cooling system in small jet-to-target space. J Propuls Technol 2008;29:143–8.Search in Google Scholar

7. Pawar, S, Patel, DK. The impingement heat transfer data of inclined jet in cooling applications: a review. J Therm Sci 2019;29:1–12, https://doi.org/10.1007/s11630-019-1200-y.Search in Google Scholar

8. Hollworth, BR, Berry, RD. Heat transfer from arrays of impinging jets with large jet-to-jet spacing. J Heat Tran 1978;100:352–7, https://doi.org/10.1115/1.3450808.Search in Google Scholar

9. Huber, AM, Viskanta, R. Effect of jet-jet spacing on convective heat transfer to confined, impinging arrays of axisymmetric air jets. Int J Heat Mass Tran 1994;37:2859–69, https://doi.org/10.1016/0017-9310(94)90340-9.Search in Google Scholar

10. Xie, R, Wang, H, Xu, B, Wang, W. A review of impingement jet cooling in combustor liner. Oslo, Norway: ASME Turbo Expo; 2018, GT2018-76335.10.1115/GT2018-76335Search in Google Scholar

11. Xing, Y, Spring, S, Weigand, B. Experimental and numerical investigation of heat transfer characteristics of inline and staggered arrays of impinging jets. J Heat Tran 2010;132:53–8, https://doi.org/10.1115/1.4001633.Search in Google Scholar

12. Goodro, M, Park, J, Ligrani, P, Fox, M, Moon, HK. Effect of temperature ratio on jet array impingement heat transfer. J Heat Tran 2009;131:103–12, https://doi.org/10.1115/1.2977546.Search in Google Scholar

13. Ekkad, SV, Kontrovitz, D, Nasir, H. Effect of rib turbulators in the first pass on heat transfer distributions in a two-pass channel connected by two rows of holes. New Orleans, Louisiana, USA: ASME Turbo Expo; 2001, 2001-GT-0184.10.1115/2001-GT-0184Search in Google Scholar

14. Ekkad, SV, Pamula, G, Acharya, S. Influence of crossflow-induced swirl and impingement on heat transfer in an internal coolant passage of a turbine airfoil. J Heat Tran 2000;122:27–39, https://doi.org/10.1115/1.1289020.Search in Google Scholar

15. Esposito, E, Ekkad, SV. Jet impingement heat transfer visualization using a steady state liquid crystal method. J Heat Tran 2006;128:738, https://doi.org/10.1115/1.2221301.Search in Google Scholar

16. Taslim, ME, Pan, Y, Bakhtari, K. Experimental racetrack shaped jet impingement on a roughened leading-edge wall with film holes. Amsterdam, The Netherlands: ASME Turbo Expo; 2002, GT2002-30477.10.1115/GT2002-30477Search in Google Scholar

17. Taslim, ME, Bakhtari, K, Liu, H. Experimental and numerical investigation of impingement on a rib-roughened leading-edge wall. J Turbomach 2003;125:31–41, https://doi.org/10.1115/1.1624848.Search in Google Scholar

18. Quan, DL, Liu, SL, Li, JH, Liu, GW. Investigation on cooling performance of impingement cooling devices combined with pins. Reno-Tahoe, Nevada, USA: ASME Turbo Expo; 2005, GT2005-68930.10.1115/GT2005-68930Search in Google Scholar

19. Goldstein, RJ, Behbahani, AI. Impingement of a circular jet with and without crossflow. Int J Heat Mass Tran 1982;25:1377–82, https://doi.org/10.1016/0017-9310(82)90131-4.Search in Google Scholar

20. Adler, D, Baron, A. Prediction of a three-dimensional circular turbulent jet in crossflow. AIAA J 2015;17:168–74.10.2514/3.61091Search in Google Scholar

21. Yuan, LL, Street, RL. Trajectory and entrainment of a round jet in crossflow. Phys Fluids 1998;10:2323–35, https://doi.org/10.1063/1.869751.Search in Google Scholar

22. Smith, SH, Mungal, MG. Mixing, structure and scaling of the jet in crossflow. J Fluid Mech 1998;357:83–122, https://doi.org/10.1017/s0022112097007891.Search in Google Scholar

23. Plesniak, MW, Cusano, DM. Scalar mixing in a confined rectangular jet in crossflow. J Fluid Mech 2005;524:1–45, https://doi.org/10.1017/s0022112004001132.Search in Google Scholar

24. Meyer, KE, Pedersen, JM, Ozcan, O. A turbulent jet in crossflow analyzed with proper orthogonal decomposition. J Fluid Mech 2007;583:199–227, https://doi.org/10.1017/s0022112007006143.Search in Google Scholar

25. Ziefle, J, Kleiser, L. Large-eddy simulation of a round jet in crossflow. AIAA J 2009;47:1158–72, https://doi.org/10.2514/1.38465.Search in Google Scholar

26. Wu, Z, Laurence, D, Iacovides, H, Afgan, I. Direct simulation of conjugate heat transfer of jet in channel crossflow. Int J Heat Mass Tran 2017;110:193–208, https://doi.org/10.1016/j.ijheatmasstransfer.2017.03.027.Search in Google Scholar

27. Wu, Z, Laurence, D, Afgan, I. Direct numerical simulation of a low momentum round jet in channel crossflow. Nucl Eng Des 2017;313:273–84, https://doi.org/10.1016/j.nucengdes.2016.12.018.Search in Google Scholar

28. Florschuetz, LW, Metzger, DE, Truman, CR. Streamwise flow and heat transfer distributions for jet array impingement with crossflow. J Heat Tran 1981;103:337–42, https://doi.org/10.1115/1.3244463.Search in Google Scholar

29. Florschuetz, LW, Isoda, Y. Flow distributions and discharge coefficient effects for jet array impingement with initial crossflow. J Eng Gas Turbines Power 1983;105:296–304, https://doi.org/10.1115/1.3227415.Search in Google Scholar

30. Kang, LY, Zhang, JZ, Tan, XM. 3-D numerical computation of jet array impingement with initial crossflow. J Nanjing Univ Aeronaut Astronaut 2004;21:128–33.Search in Google Scholar

31. Lamont, JA, Ekkad, SV, Alvin, MA. Effects of rotation on heat transfer for a single row jet impingement array with crossflow. J Heat Tran 2012;134:1–12, https://doi.org/10.1115/1.4006167.Search in Google Scholar

32. Huang, YZ, Ekkad, SV, Han, JC. Detailed heat transfer distributions under an array of orthogonal impinging jets. J Thermophys Heat Tran 2012;12:73–9.10.2514/2.6304Search in Google Scholar

33. Huang, YZ, Ekkad, SV, Han, JC. Detailed heat transfer distributions under an array of inclined impinging jets using transient liquid crystal technique. In: 9th international symposium on transport phenomena in thermal fluids engineering, Singapore; 1996.10.1115/IMECE1996-0067Search in Google Scholar

34. Obot, NT, Trabold, TA. Impingement heat transfer within arrays of circular jets: part Ⅰ – effects of minimum, intermediate, and complete crossflow for small and large spacings. J Heat Tran 1987;109:872–9, https://doi.org/10.1115/1.3248197.Search in Google Scholar

35. Florschuetz, LW, Berry, RA, Metzger, DE. Periodic streamwise variations of heat transfer coefficients for inline and staggered arrays of circular jets with crossflow of spent air. J Heat Tran 1980;102:132–7, https://doi.org/10.1115/1.3244224.Search in Google Scholar

36. Chambers, AC, Gillespie, DRH, Ireland, PT, Dailey, GM. The effect of initial cross flow on the cooling performance of a narrow impingement channel. J Heat Tran 2005;127:358–65, https://doi.org/10.1115/1.1800493.Search in Google Scholar

37. Rao, AG, Belinkov, MK, Krapp, V, Levy, Y. Heat transfer investigations in multiple impinging jets at low Reynolds number. Glasgow, UK: ASME Turbo Expo; 2010, GT2010-22720.10.1115/GT2010-22720Search in Google Scholar

38. Paz, MLD, Jubran, BA. A numerical study of an impingement array inside a three dimensional turbine vane. Glasgow, UK: ASME Turbo Expo; 2010, GT2010-22270.Search in Google Scholar

39. Eroglu, A, Breidenthal, RE. Structure, penetration, and mixing of pulsed jets in crossflow. AIAA J 2001;39:417–23, https://doi.org/10.2514/3.14746.Search in Google Scholar

40. Yu, Y, Zhang, J, Shan, Y. Convective heat transfer of a row of air jets impingement excited by triangular tabs in a confined crossflow channel. Int J Heat Mass Tran 2015;80:126–38, https://doi.org/10.1016/j.ijheatmasstransfer.2014.08.066.Search in Google Scholar

41. Terzis, A, Ott, P, Cochet, M, Wolfersdorf, JV, Weigand, B. Effect of varying jet diameter on the heat transfer distributions of narrow impingement channels. J Turbomach 2016;138: 021004.Search in Google Scholar

42. Terzis, A, Ott, P, Cochet, M, Wolfersdorf, JV, Weigand, B. Aerothermal investigation of a single row divergent narrow impingement channel by particle image velocimetry and liquid crystal thermography. J Turbomach 2015;137: 051003, https://doi.org/10.1115/1.4028294.Search in Google Scholar

43. Esposito, EI, Ekkad, SV, Kim, Y, Dutta, P. Novel jet impingement cooling geometry for combustor liner backside cooling. J Therm Sci Eng Appl 2009;21: 021001, https://doi.org/10.1115/1.3202799.Search in Google Scholar

44. Esposito, EI, Kim, Y, Dutta, P. Comparing extended port and corrugated wall jet impingement geometry for combustor liner backside cooling. Montréal, Canada: ASME Turbo Expo; 2007, GT2007-27390.10.1115/GT2007-27390Search in Google Scholar

45. Chi, ZR, Kan, R, Ren, J, Jiang, HD. Experimental and numerical study of the anti-crossflow impingement cooling structure. Int J Heat Mass Tran 2013;64:567–80, https://doi.org/10.1016/j.ijheatmasstransfer.2013.04.052.Search in Google Scholar

46. Parida, PR, Ekkad, SV, Ngo, K. Experimental and numerical investigation of confined oblique impingement configurations for high heat flux applications. Int J Therm Sci 2011;50:1037–50, https://doi.org/10.1016/j.ijthermalsci.2011.01.010.Search in Google Scholar

47. Wang, L, Sundén, B, Borg, A, Abrahamsson, H. Control of jet impingement heat transfer in crossflow by using a rib. Int J Heat Mass Tran 2011;54:4157–66, https://doi.org/10.1016/j.ijheatmasstransfer.2011.06.004.Search in Google Scholar

48. Wang, CL, Wang, L, Sundén, B, Revstedt, J. Effects of a vortex generator pair on jet impingement heat transfer in cross-flow. Montréal, Canada: ASME Turbo Expo; 2015, GT2015-42236.10.1115/GT2015-42236Search in Google Scholar

49. Wang, CL, Luo, L, Wang, L, Sundén, B. Heat transfer and fluid flow of a single jet impingement in crossflow modified by a vortex generator pair. Seoul, South Korea: ASME Turbo Expo; 2016, GT2016-56894.10.1115/GT2016-56894Search in Google Scholar

50. Wang, CL, Wang, L, Sundén, B. A novel control of jet impingement heat transfer in cross-flow by a vortex generator pair. Int J Heat Mass Tran 2015;88:82–90, https://doi.org/10.1016/j.ijheatmasstransfer.2015.04.056.Search in Google Scholar

51. Wang, CL, Luo, L, Wang, L, Sundén, B. Effects of vortex generator on the jet impingement heat transfer at different cross-flow Reynolds number. Int J Heat Mass Tran 2016;96:278–86, https://doi.org/10.1016/j.ijheatmasstransfer.2016.01.042.Search in Google Scholar

52. Madhavan, S, Ramakrishnan, KR, Singh, P, Ekkad, S. Jet impingement heat transfer enhancement by U-shaped crossflow diverters. J Therm Sci Eng Appl 2020;12: 041005, https://doi.org/10.1115/1.4045514.Search in Google Scholar

53. Liu, KX, Zhang, Q. A novel multi-stage impingement cooling scheme-part I: concept study. J Turbomach 2020;142:121008, https://doi.org/10.1115/1.4048183.Search in Google Scholar

54. Liu, KX, Zhang, Q. A novel multi-stage impingement cooling scheme-part II: design optimization. J Turbomach 2020;142:121009, https://doi.org/10.1115/1.4048184.Search in Google Scholar

55. Florschuetz, LW, Metzger, DE, Su, CC. Heat transfer characteristics for jet array impingement with initial crossflow. J Heat Tran 1984;106:34–41, https://doi.org/10.1115/1.3246656.Search in Google Scholar
Received: 2021-07-12
Accepted: 2022-03-26
Published Online: 2022-04-13

© 2022 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. The International Journal of Turbo and Jet Engines
  3. The aerothermodynamic cycle optimal design of a turbofan engine
  4. Multi-condition design optimization of groove flow control technique in an axial-flow pump
  5. Analysis on impulse characteristics of pulse detonation engine with nozzles
  6. Numerical investigation on implication of innovative hydrogen strut injector on performance and combustion characteristics in a scramjet combustor
  7. Optimization of Kiel geometry for better recovery factor in high temperature measurement in aero gas turbine engine
  8. Applicability of correlational data-mining to small-scale turbojet performance map generation
  9. Effect of multi-zone effusion cooling on an adiabatic flat plate for gas turbine application
  10. Flow quality improvement of the wind tunnel testing for a highly-loaded compressor cascade at high incidence
  11. Modeling and analysis of 3D radiative heat transfer in combustor
  12. A creep-fatigue life prediction model considering multi-factor coupling effect
  13. Optimization-based transient control of turbofan engines: a sequential quadratic programming approach
  14. Investigations on the interaction between the front and aft purge flow and the downstream vane of 1.5-stage turbine
  15. A study on design optimization for compressor blisks
  16. Exploration of an unconventional validation tool to investigate aero engine transonic fan flutter signature
  17. Evaluation of non-uniform water film behavior on the performance of an axial aeroengine compressor
  18. Predicting remaining useful life of turbofan engines using degradation signal based echo state network
  19. Effect of G-type integral squeeze film damper on the dynamic characteristics in rotor system
  20. Development of a one-dimensional code for the initial design of a micro gas turbine mixed flow compressor stage
  21. Numerical and experimental investigations of tip clearance effects in a high-flow-coefficient centrifugal compressor
  22. Experimental and numerical investigation on the effect of turboprop engine exhaust gas impingement on pusher aircraft
  23. Heat transfer distribution of single oblique jet impingement in crossflow under different inlet conditions
  24. Performance enhancement and flow separation control in an S-duct by air injection
  25. Gas dynamic analysis of the modern single shaft gas turbine engine flow path
  26. Aero engine health monitoring, diagnostics and prognostics for condition-based maintenance: an overview
  27. Influence of leading edge point on aerodynamic performance of asymmetric leading edge compressor airfoils
  28. The aerothermal performance of turbine blade squealer tip at various Reynolds numbers and Mach numbers with moving endwall
  29. Numerical investigation of a variable stator vane with nonuniform partial radial gaps in an annular compressor cascade
  30. Effect of self-recirculating casing treatment on the unsteady flow and stability of counter-rotating axial-flow compressor
  31. Research on temperature rise characteristics of end V-groove ring seal
  32. Research on the influence of honeycomb cell blockage on the seal leakage characteristics
  33. Vortex structure control based bleed in axial compressor cascade with tip clearance using large eddy simulation
  34. Development and application of a profile loss model considering the low-Re effect in low-pressure turbine
  35. Optimization of ACE mode transition control schedule considering geometric adjustment speed
  36. Numerical investigation of flow control in low-pressure turbine cascade using Gurney Flaps
  37. The design method of the V-shaped groove piston ring
  38. Control of subsonic jets using vanes as vortex generators
  39. Impact investigation of inlet environmental changes on the rated condition performance of a high-pressure compressor
  40. Research on new integral squeeze film damper vibration control of micro turbojet engine at high speed
  41. Effect of the distribution of the upstream probe support on performance of compressor cascade
  42. Effect of bypass ratio on sonic underexpanded co-flow jets with finite lip thickness
  43. Machine learning augmented multi-sensor data fusion to detect aero engine fan rotor blade flutter
  44. CFD analysis of flow control in compressor cascade using MVGs
  45. Quantitative investigation of the evaporation and resistance characteristics of inlet jet precooling
  46. Study on laser de-weight and dynamic balance technology of rotating machines
  47. Integrated design and analysis of inlet and missile with two side layout
  48. Research on turboprop engine control method based on linear parameter varying model
  49. Modeling and validation of the volume effect on the axial fan transient performance
  50. Ground effects on the aerodynamics of a wing with slot type distributed propulsion system for VTOL applications
  51. Multidisciplinary sensitivity analysis for turbine blade considering thickness uncertainties
  52. Accurate measurement and evaluation method of axial compressor efficiency under the influence of multiple factors
  53. Control mechanism of secondary flow in a turbine cascade with non-axisymmetric endwall profiling under Co-rotating incoming vortex
  54. Infrared simulation of aircraft rear fuselage based on a coupled CFD method
  55. Effect of multi-hole trench cooling on an adiabatic flat plate for gas turbine application
  56. Numerical study of transition process in different zones of a compressor cascade channel
https://doi.org/10.1515/tjj-2021-0029
Keywords for this article
crossflow ratio; jet impingement; jet intake mode; oblique angle; temperature ratio

Articles in the same Issue

  1. Frontmatter
  2. The International Journal of Turbo and Jet Engines
  3. The aerothermodynamic cycle optimal design of a turbofan engine
  4. Multi-condition design optimization of groove flow control technique in an axial-flow pump
  5. Analysis on impulse characteristics of pulse detonation engine with nozzles
  6. Numerical investigation on implication of innovative hydrogen strut injector on performance and combustion characteristics in a scramjet combustor
  7. Optimization of Kiel geometry for better recovery factor in high temperature measurement in aero gas turbine engine
  8. Applicability of correlational data-mining to small-scale turbojet performance map generation
  9. Effect of multi-zone effusion cooling on an adiabatic flat plate for gas turbine application
  10. Flow quality improvement of the wind tunnel testing for a highly-loaded compressor cascade at high incidence
  11. Modeling and analysis of 3D radiative heat transfer in combustor
  12. A creep-fatigue life prediction model considering multi-factor coupling effect
  13. Optimization-based transient control of turbofan engines: a sequential quadratic programming approach
  14. Investigations on the interaction between the front and aft purge flow and the downstream vane of 1.5-stage turbine
  15. A study on design optimization for compressor blisks
  16. Exploration of an unconventional validation tool to investigate aero engine transonic fan flutter signature
  17. Evaluation of non-uniform water film behavior on the performance of an axial aeroengine compressor
  18. Predicting remaining useful life of turbofan engines using degradation signal based echo state network
  19. Effect of G-type integral squeeze film damper on the dynamic characteristics in rotor system
  20. Development of a one-dimensional code for the initial design of a micro gas turbine mixed flow compressor stage
  21. Numerical and experimental investigations of tip clearance effects in a high-flow-coefficient centrifugal compressor
  22. Experimental and numerical investigation on the effect of turboprop engine exhaust gas impingement on pusher aircraft
  23. Heat transfer distribution of single oblique jet impingement in crossflow under different inlet conditions
  24. Performance enhancement and flow separation control in an S-duct by air injection
  25. Gas dynamic analysis of the modern single shaft gas turbine engine flow path
  26. Aero engine health monitoring, diagnostics and prognostics for condition-based maintenance: an overview
  27. Influence of leading edge point on aerodynamic performance of asymmetric leading edge compressor airfoils
  28. The aerothermal performance of turbine blade squealer tip at various Reynolds numbers and Mach numbers with moving endwall
  29. Numerical investigation of a variable stator vane with nonuniform partial radial gaps in an annular compressor cascade
  30. Effect of self-recirculating casing treatment on the unsteady flow and stability of counter-rotating axial-flow compressor
  31. Research on temperature rise characteristics of end V-groove ring seal
  32. Research on the influence of honeycomb cell blockage on the seal leakage characteristics
  33. Vortex structure control based bleed in axial compressor cascade with tip clearance using large eddy simulation
  34. Development and application of a profile loss model considering the low-Re effect in low-pressure turbine
  35. Optimization of ACE mode transition control schedule considering geometric adjustment speed
  36. Numerical investigation of flow control in low-pressure turbine cascade using Gurney Flaps
  37. The design method of the V-shaped groove piston ring
  38. Control of subsonic jets using vanes as vortex generators
  39. Impact investigation of inlet environmental changes on the rated condition performance of a high-pressure compressor
  40. Research on new integral squeeze film damper vibration control of micro turbojet engine at high speed
  41. Effect of the distribution of the upstream probe support on performance of compressor cascade
  42. Effect of bypass ratio on sonic underexpanded co-flow jets with finite lip thickness
  43. Machine learning augmented multi-sensor data fusion to detect aero engine fan rotor blade flutter
  44. CFD analysis of flow control in compressor cascade using MVGs
  45. Quantitative investigation of the evaporation and resistance characteristics of inlet jet precooling
  46. Study on laser de-weight and dynamic balance technology of rotating machines
  47. Integrated design and analysis of inlet and missile with two side layout
  48. Research on turboprop engine control method based on linear parameter varying model
  49. Modeling and validation of the volume effect on the axial fan transient performance
  50. Ground effects on the aerodynamics of a wing with slot type distributed propulsion system for VTOL applications
  51. Multidisciplinary sensitivity analysis for turbine blade considering thickness uncertainties
  52. Accurate measurement and evaluation method of axial compressor efficiency under the influence of multiple factors
  53. Control mechanism of secondary flow in a turbine cascade with non-axisymmetric endwall profiling under Co-rotating incoming vortex
  54. Infrared simulation of aircraft rear fuselage based on a coupled CFD method
  55. Effect of multi-hole trench cooling on an adiabatic flat plate for gas turbine application
  56. Numerical study of transition process in different zones of a compressor cascade channel
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2026 De Gruyter Brill
Downloaded on 19.1.2026 from https://www.degruyterbrill.com/document/doi/10.1515/tjj-2021-0029/pdf
Scroll to top button