透平内部非稳态流动试验研究进展

doi:10.13675/j.cnki. tjjs. 180711

推进技术 ›› 2019, Vol. 40 ›› Issue (10): 2161-2174.DOI: 10.13675/j.cnki. tjjs. 180711

• 综述 • 下一篇

透平内部非稳态流动试验研究进展

邵梓一^1,2,李文^1,2,张雪辉¹,陈海生^1,2

1.中国科学院工程热物理研究所，北京 100190;2.中国科学院大学工程科学学院，北京;100049

发布日期:2021-08-15
作者简介:邵梓一，硕士生，研究领域为叶轮机械气动热力学。E-mail：shaoziyi@iet.cn
基金资助:
国家自然科学基金 51606188 51522605;“九七三”计划 2015CB251302;中国科学院前沿科学重点研究项目 QYZDB-SSW-JSC023;北京市科技计划项目 D161100004616001 D161100004616002国家自然科学基金（51606188；51522605）；“九七三”计划（2015CB251302）；中国科学院前沿科学重点研究项目（QYZDB-SSW-JSC023）；北京市科技计划项目（D161100004616001；D161100004616002）。

Experimental Research Progress on InternalUnsteady Flow of Turbine

1.Institute of Engineering Thermophysics,Chinese Academy of Sciences,Beijing 100190,China;2.School of Engineering Science,University of Chinese Academy of Sciences,Beijing 100049,China

Published:2021-08-15

摘要/Abstract

摘要： 为探究透平内部流场的非稳态特性及其演变特征，通过归纳国内外透平内部流动的试验研究，回顾了轴流透平、向心透平采用的试验方法及取得的研究进展，分析总结了试验方案与研究中存在的问题。目前，轴流式透平与平面叶栅的试验数量较多，试验的压力温度较低；向心式透平试验研究还比较少，并且试验多处于高温高压环境；随着接触式测量设备性能的大幅提升，其目前在透平非稳态试验中得到广泛应用，例如气动探针已经能够满足1×10⁶Hz的高频采集要求；上游尾迹以及叶顶泄漏涡扰动下轴流式透平叶表附面层的转捩机制，以及向心式透平盘腔泄漏流与主流流场的非定常掺混等问题还有待进一步研究。

关键词: 透平;内部流场;试验研究;非稳态流动;动静干涉;二次涡;尾迹;综述

Abstract: To clarify the unsteadiness and evolution process of internal flow field in turbines, the experimental method and research progress of the axial turbine and radial turbine were reviewed based on domestic and foreign researches, and some disadvantages of present experimental scheme and research were also performed. The results show that experiments, whose pressure and temperature are usually low, in axial turbines and linear cascades have been widely investigated, while relatively less experiments, whose pressure and temperature are relatively high, in radial turbines can be seen in the existing literatures. The contact measurement has been widely used in unsteady experiments of turbines for its increasingly improved performance. For example, the pneumatic probes could meet the requirement of high sampling rate, which may be up to 1×10⁶Hz, very well. However, the transition mechanisms of surface boundary layer under the disturbance of upstream wake and tip leakage vortex in axial turbines are still not fully explained and need further researches, so does the unsteady mixing between the cavity leakage flow and the main flow in radial turbines.

Key words: Turbine;Internal flow field;Experimental research;Unsteady flow;Rotor-stator interaction;Secondary vortex;Wake;Review

邵梓一,李文,张雪辉,陈海生. 透平内部非稳态流动试验研究进展[J]. 推进技术, 2019, 40(10): 2161-2174.

SHAO Zi-yi^1,2,LI Wen^1,2,ZHANG Xue-hui¹,CHEN Hai-sheng^1,2. Experimental Research Progress on InternalUnsteady Flow of Turbine[J]. Journal of Propulsion Technology, 2019, 40(10): 2161-2174.

参考文献

[1] Ainley D G, Mathieson G C R. A Method of Performance Estimation for Axial-Flow Turbines[R]. UK: British Aeronautical Research Council Technical Report R&M， No. 2974.
[2] Palmer R M. D. I. G. T. Radial Inflow Turbine-Scroll and Nozzle Performance-Part 1[R]. UK: Ricardo， 1963.
[3] Smith L. Secondary Flow in Axial-Flow Turbomachinery[J]. Journal of Engineering for Power， 1955， 77: 1065-1076.
[4] Reynolds B， Lakshminarayana B. Characteristics of Lightly Loaded Fan Rotor Blade Wakes[R]. NASA-CR-3188.
[5] Dring R P， Joslyn H D， Hardin L W， et al. Turbine Rotor-Stator Interaction[J]. Journal of Engineering for Power， 1982， 104(4): 729-742.
[6] Hodson H P， Howell R J. Bladerow Interactions， Transition， and High-Lift Aerofoils in Low-Pressure Turbines[J]. Annual Review of Fluid Mechanics， 2005， 37: 71-98.
[7] Howell R J， Ramesh O N， Hodson H P， et al. High Lift and Aft-Loaded Profiles for Low-Pressure Turbines[J]. Journal of Turbomachinery， 2000， 123(2): 181-188.
[8] 朱俊强，屈骁，张燕峰，等. 高负荷低压涡轮内部非定常流动机理及其控制策略研究进展[J]. 推进技术， 2017， 38(10): 2186-2199.
[9] 陈海生，谭春青. 叶轮机械内部流动研究进展[J]. 机械工程学报， 2007， 43(2): 1-12.
[10] 张玮，王元，徐忠. 叶轮机械内部流动测量及动静相互作用的实验研究进展[J]. 流体机械， 2001， 29(8): 6-10.
[11] Langston L S. Secondary Flows in Axial Turbines-A Review[J]. Annals of the New York Academy of Sciences， 2001， 934(1): 11-26.
[12] Sieverding C H. Recent Progress in the Understanding of Basic Aspects of Secondary Flows in Turbine Blade Passages[J]. Journal of Engineering for Gas Turbines and Power， 1985， 107(2): 248-257.
[13] Squire H B， Winter K G. The Secondary Flow in a Cascade of Airfoils in a Nonuniform Stream[J]. Journal of the Aeronautical Sciences， 1951， 18(4): 271-277.
[14] Klein A. Investigation of the Entry Boundary Layer on the Secondary Flows in the Blading of Axial Turbines[R]. BHRA T-1004.
[15] Moore J. Trajectories Flow ， Mixing and Entropy Fluxes in a Turbine Cascade[R]. AGARD CP-351.
[16] Yamamoto A. Production and Development of Secondary Flows and Losses in Two Types of Straight Turbine Cascades, Part 1: A Stator Case[J]. Journal of Turbomachinery， 1987， 109(2): 186-193.
[17] Blair M F. An Experimental Study of Heat Transfer and Film Cooling on Large-Scale Turbine Endwalls[J]. Journal of Heat Transfer， 1974， 96(4): 524-529.
[18] Langston L S， Nice M L， Hooper R M. Three-Dimensional Flow Within a Turbine Cascade Passage[J]. Journal of Engineering for Power， 1977， 99(1): 21-28.
[19] Moore J， Smith B L. Flow in a Turbine Cascade, Part 2: Measurement of Flow Trajectories by Ethylene Detection[J]. Journal of Engineering for Gas Turbines & Power， 1984， 106(2): 409-413.
[20] Sieverding C H， Van Den Bosche P. The Use of Coloured Smoke to Visualize Secondary Flows in a Turbine-Blade Cascade[J]. Journal of Fluid Mechanics， 1983， 134(1): 85-89.
[21] Wang H P， Olson S J， Goldstein R J， et al. Flow Visualization in a Linear Turbine Cascade of High Performance Turbine Blades[J]. Journal of Turbomachinery， 1997， 119(1): 1-8.
[22] Dean R C J， Senoo Y. Rotating Wakes in Vaneless Dffusers[J]. Journal of Basic Engineering， 1960， 82(3): 563-570.
[23] Kerrebrock J L， Mikolajczak A A. Intra-Stator Transport of Rotor Wakes and Its Effect on Compressor Performance[J]. Journal of Engineering for Power， 1970， 92(4): 359-368.
[24] Adachi T， Murakami Y. Three-Dimensional Velocity Distribution Between Stator Blades and Unsteady Force on a Blade Due to Passing Wakes[J]. Bulletin of JSME， 1979， 22(170): 1074-1082.
[25] Dunker R J. Flow Measurements in the Stator Row of a Single-Stage Transonic Axial-Flow Compressor with Controlled Diffusion Stator Blade[R]. AGARD-CP-23.
[26] Bhinder F S. Investigation of Flow in the Nozzleless Spiral Casing of a Radial Inward-Flow Gas Turbine[J]. Proceedings of the Institution of Mechanical Engineers， Part A: Journal of Power and Energy， 1969， 184(37): 66-71.
[27] Siddon T E. On the Response of Pressure Measuring Instrumentation in Unsteady Flow[J]. Australian & New Zealand Journal of Public Health， 1969， 37(4): 305-310.
[28] Wisler D C， Mossey P W. Gas Velocity Measurements Within a Compressor Rotor Passage Using the Laser Doppler Velocimeter[J]. Journal of Engineering for Power， 1973， 95(2): 91-96.
[29] Schodl R. A Laser Dual-Beam Method for Flow Measurements in Turbomachines[R]. ASME 74-GT-157.
[30] Wisler D C. Shock Wave and Flow Velocity Measurements in a High Speed Fan Rotor Using the Laser Velocimeter[J]. Journal of Engineering for Power， 1977， 99(2): 181-187.
[31] Bryanston-Cross P J. High Speed Flow Visualisation[J]. Progress in Aerospace Sciences， 1986， 23(2): 85-104.
[32] Paone N， Riethmuller M L， Braembussche R A V D. Experimental Investigation of the Flow in the Vaneless Diffuser of a Centrifugal Pump by Particle Image Displacement Velocimetry[J]. Experiments in Fluids， 1989， 7(6): 371-378.
[33] Bacci T， Becchi R， Picchi A， et al. Adiabatic Effectiveness on High-Pressure Turbine Nozzle Guide Vanes under Realistic Swirling Conditions[J]. Journal of Turbomachinery， 2018， 141(1).
[34] Senoo A， Tsujita S M， Yamamoto A. Investigation of Internal Flow in Ultra—Highly Loaded Turbine Cascade by PIV Method[J]. Journal of Thermal Science， 2000， 9(3): 193-198.
[35] Gomes R A， Niehuis R. Aerothermodynamics of a High-Pressure Turbine Blade with Very High Loading and Vortex Generators[J]. Journal of Turbomachinery， 2012， 134(1).
[36] Wang S， Sun H， Di J， et al. High-Resolution Measurement and Analysis of the Transient Secondary Flow Field in a Turbine Cascade[J]. Proceedings of the Institution of Mechanical Engineers， Part A: Journal of Power and Energy， 2014， 228(7): 799-812.
[37] Liu Y， Zhang T L， Zhang M， et al. Numerical and Experimental Investigation of Aerodynamic Performance for a Straight Turbine Cascade with a Novel Partial Shroud[J]. Journal of Fluids Engineering， 2015， 138(3).
[38] Zhang M， Liu Y， Zhang T， et al. Aerodynamic Optimization of a Winglet-Shroud Tip Geometry for a Linear Turbine Cascade[J]. Journal of Turbomachinery， 2017， 139(10).
[39] 钟兢军，魏曼，陆华伟. 压力面小翼对涡轮叶栅不同间隙下流场影响的实验[J]. 航空动力学报， 2016， 31(1): 84-91.
[40] Dring R P， Joslyn H D. Measurement of Turbine Rotor Blade Flows[J]. Journal of Engineering for Gas Turbines & Power， 1981， 103(2): 400-405.
[41] Goldman L J， Mclallin K L. Cold-Air Annular-Cascade Investigation of Aerodynamic Performance of Core-Engine-Cooled Turbine Vanes. 1: Solid-Vane Performance and Facility Description[R]. NASA-TM-X-3224.
[42] 高丽敏，韦楠，高杰，等. 基于内流场PSP测量技术的图像后处理[J]. 实验流体力学， 2013， 27(1): 93-97.
[43] Mahadevan S， Kapat J S， Kumar R， et al. Study of Secondary Flow and Coolant Film Interaction in a High Subsonic Cascade[J]. International Journal of Heat and Fluid Flow， 2016， 62: 189-202.
[44] Matsunuma T. Unsteady Flow Field of an Axial-Flow Turbine Rotor at a Low Reynolds Number[J]. Journal of Turbomachinery， 2007， 129(2): 360-371.
[45] Matsunuma T， Segawa T. Active Tip Clearance Flow Control for an Axial-Flow Turbine Rotor Using Ring-Type Plasma Actuators[R]. ASME GT2014-26390.
[46] Japikse D. Advanced Experimental Techniques in Turbomachinery[M]. USA: Concepts ETI， Inc.， 1986.
[47] Gaetani P， Persico G， Dossena V， et al. Investigation of the Flow Field in a High-Pressure Turbine Stage for Two Stator-Rotor Axial Gaps， Part I: Three-Dimensional Time-Averaged Flow Field[J]. Journal of Turbomachinery， 2007， 129(3): 572-579.
[48] Yamamoto A， Murao R， Suzuki Y， et al. A Quasi Unsteady Study on Wake Interaction of Turbine Stator and Rotor Cascades[J]. Journal of Turbomachinery， 1995， 117(4): 553-561.
[49] Greitzer E M， Nikkanen J P， Haddad D E， et al. A Fundamental Criterion for the Application of Rotor Casing Treatment[J]. Journal of Fluids Engineering， 1979， 101(2): 237-243.
[50] Gamache R N， Greitzer E M. Reverse Flow in Multistage Axial Compressors[J]. Journal of Propulsion and Power， 1990， 6(4): 461-473.
[51] Binder A， Fo?Rster W， Kruse H， et al. An Experimental Investigation into the Effect of Wakes on the Unsteady Turbine Rotor Flow[J]. Journal of Engineering for Gas Turbines and Power， 1985， 107(2): 458-465.
[52] Binder A， F?rster W， Mach K， et al. Unsteady Flow Interaction Caused by Stator Secondary Vortices in a Turbine Rotor[J]. Journal of Turbomachinery， 1986， 109(2): 251-256.
[53] Eymann S， Reinmoller U， F?rster W， et al. Improving 3D Flow Characteristics in a Multistage LP Turbine by Means of Endwall Contouring and Airfoil Design Modification， Part 1: Design and Experimental Investigation[R]. ASME GT2002-30352.
[54] Hodson H P. Measurements of Wake-Generated Unsteadiness in the Rotor Passages of Axial Flow Turbines[J]. Journal of Engineering for Gas Turbines and Power， 1985， 107(2): 467-475.
[55] Babinsky H， Hodson H P， Kuschel U， et al. Geometries for Five-Hole-Type Probes with Planar Sensor Arrays[J]. AIAA Journal， 2001， 39(12): 2414-2416.
[56] Yamamoto A， Mimura F， Tominaga J， et al. Unsteady Three-Dimensional Flow Behavior Due to Rotor-Stator Interaction in an Axial-Flow Turbine[R]. ASME 93-GT-404.
[57] Yamamoto A. Interaction Mechanisms Between Tip Leakage Flow and the Passage Vortex in a Linear Turbine Rotor Cascade[J]. Journal of Turbomachinery， 1988， 110(3): 329-338.
[58] Zaccaria M A， Lakshminarayana B. Unsteady Flow Field Due to Nozzle Wake Interaction with the Rotor in an Axial Flow Turbine， Part I: Rotor Passage Flow Field[J]. Journal of Turbomachinery， 1997， 119(2): 201-213.
[59] Zaccaria M A， Lakshminarayana B. Unsteady Flow Field Due to Nozzle Wake Interaction with the Rotor in an Axial Flow Turbine， Part II: Rotor Exit Flow Field[J]. Journal of Turbomachinery， 1997， 119(2): 214-224.
[60] Rao K V， Delaney R A， Dunn M G. Vane-Blade Interaction in a Transonic Turbine， Part I: Aerodynamics[J]. Journal of Propulsion and Power， 1994， 10(3): 305-311.
[61] Rao K V， Delaney R A， Dunn M G. Vane-Blade Interaction in a Transonic Turbine， Part II: Heat Transfer[J]. Journal of Propulsion and Power， 1994， 10(3): 312-317.
[62] Pfeil H， Herbst R. Transition Procedure of Instationary Boundary Layers[R]. ASME 79-GT-128.
[63] Schulte V， Hodson H P. Unsteady Wake-Induced Boundary Layer Transition in High Lift LP Turbines[R]. ASME 96-GT-486.
[64] 梁赟，刘火星，邹正平. 尾迹对低压涡轮边界层稳定性的影响[J]. 航空动力学报， 2016， 31(4): 886-893.
[65] 李伟，张波，周敏，等. 尾迹扫掠下超高负荷低压涡轮叶片附面层特性[J]. 航空动力学报， 2012， 27(1): 176-182.
[66] Hodson H P， Dawes W N. On the Interpretation of Measured Profile Losses in Unsteady Wake-Turbine Blade Interaction Studies[J]. Journal of Turbomachinery， 1998， 120(2): 276-284.
[67] Hashemi S G R， Lemak R J， Owczarek J A. An Investigation of the Flow Characteristics and of Losses in Radial Nozzle Cascades[J]. Journal of Engineering for Gas Turbines and Power， 1984， 106(2): 502-509.
[68] Eroglu H， Tabakoff W. LDV Measurements and Investigation of Flow Field Through Radial Turbine Guide Vanes[R]. ASME 89-GT-162.
[69] Eroglu H， Tabakoff W. LDV Measurements of Turbulent Stresses in Radial Turbine Guide Vanes[R]. ASME 90-GT-75.
[70] Putra M A， Joos F. Investigation of Secondary Flow Behavior in a Radial Turbine Nozzle[J]. Journal of Turbomachinery， 2013， 135(6).
[71] Natkaniec C K， Kammeyer J， Seume J R. Secondary Flow Structures and Losses in a Radial Turbine Nozzle[R]. ASME GT2011-46753.
[72] Suhrmann J F， Peitsch D. Validation and Development of Loss Models for Small Size Radial Turbines[R]. ASME GT2010-22666.
[73] Simpson A T， Spence S W T， Watterson J K. A Comparison of the Flow Structures and Losses Within Vaned and Vaneless Stators for Radial Turbines[J]. Journal of Turbomachinery， 2009， 131(3).
[74] 李燕生，陆桂林. 向心透平与离心压气机[M]. 北京: 机械工业出版社， 1987.
[75] Futral S M， Holeski D E. Experimental Results of Varying the Blade Shroud Clearance in a 6.02-Inch Radial-Inflow Turbine[R]. NASA-TN-D-5513.
[76] Dambach R， Hodson H P， Huntsman I. An Experimental Study of Tip Clearance Flow in a Radial Inflow Turbine[J]. Journal of Turbomachinery， 1998， 120(4): 644-650.
[77] Pasin A， Tabakoff W. Laser Measurements of Unsteady Flow Field in a Radial Turbine Guide Vane[R]. AIAA92-0394.
[78] Murugan D， Tabakoff W， Hamed A. Flow Field Investigation in the Exit Region of a Radial Inflow Turbine Using LDV[R]. ASME 94-GT-101.
[79] Miller E C， L'ecuyer M R， Benisek E F. Flow Field Surveys at the Rotor Inlet of a Radial Inflow Turbine[J]. Journal of Engineering for Gas Turbines & Power， 1988， 110(3): 552-561.
[80] Lakshminarasimha A N， Tabakoff W， Metwally A. Laser Doppler Velocimeter Measurements in the Vortex Region of a Radial Inflow Turbine[J]. Journal of Propulsion and Power， 1992， 8(1): 184-191.
[81] Binder A， Romey R. Secondary Flow Effects and Mixing of the Wake Behind a Turbine Stator[J]. Journal of Engineering for Power， 1983， 105(1): 40-46.
[82] Moore J， Adhye R Y. Secondary Flows and Losses Downstream of a Turbine Cascade[J]. Journal of Engineering for Gas Turbines & Power， 1985， 107(4): 961-968.
[83] Páty M， Cernat B C， De Maesschalck C， et al. Experimental and Numerical Investigation of Optimized Blade Tip Shapes， Part II: Tip Flow Analysis and Loss Mechanisms[J]. Journal of Turbomachinery， 2019， 141(1).
[84] Zhou Z H， Chen S W， Wang S T. Aerodynamic Optimisation of a Winglet-Cavity Tip in a High-Pressure Axial Turbine Cascade[J]. Proceedings of the Institution of Mechanical Engineers Part G: Journal of Aerospace Engineering， 2018， 232(4): 649-663.
[85] Roy A， Blot D M， Ekkad S V， et al. Thermal Management of a Transonic Turbine: Leakage Flow and Endwall Contouring Effects[J]. Journal of Thermophysics and Heat Transfer， 2018， 32(4): 1031-1044.
[86] Naseri A， Sammak S， Boroomand M， et al. Experimental Investigation of Inlet Distortion Effect on Performance of a Micro Gas Turbine[J]. Journal of Engineering for Gas Turbines and Power， 2018.
[87] Nakajima T， Segawa K， Kitahara H， et al. Experimental Investigation of the Grouped Blade Vibration for Steam Turbine by Noncontact Sensors[J]. Journal of Engineering for Gas Turbines and Power， 2018， 140(5).
[88] Li W， Wang X， Zhang X H， et al. Experimental and Numerical Investigation of Closed Radial-Inflow Turbine with Labyrinth Seals[J]. Journal of Engineering for Gas Turbines and Power， 2018， 140(10).
[89] Ketata A， Driss Z， Abid M S. Experimental Analysis for Performance Evaluation and Unsteadiness Quantification for One Turbocharger Vane-Less Radial Turbine Operating on a Gasoline Engine[J]. Arabian Journal for Science and Engineering， 2018， 43(9): 4763-4781.
[90] Andreoli V， Cuadrado D G， Paniagua G. Prediction of the Turbine Tip Convective Heat Flux Using Discrete Green's Functions[J]. Journal of Heat Transfer， 2018， 140(7).
[91] Whitacker L H L， Tomita J T， Bringhenti C. An Evaluation of the Tip Clearance Effects on Turbine Efficiency for Space Propulsion Applications Considering Liquid Rocket Engine Using Turbopumps[J]. Aerospace Science and Technology， 2017， 70: 55-65.
[92] Stotz S， Niehuis R， Guendogdu Y. Experimental Investigation of Pressure Side Flow Separation on the T106C Airfoil at High Suction Side Incidence Flow[J]. Journal of Turbomachinery， 2017， 139(5).
[93] Papa F， Madanan U， Goldstein R. Modeling and Measurements of Heat/Mass Transfer in a Linear Turbine Cascade[J]. Journal of Turbomachinery， 2017， 139(9).
[94] Netzhammer S， Vogt D M， Kraetschmer S， et al. Aerodynamic Excitation Analysis of Radial Turbine Blades Due to Unsteady Flow from Vaneless Turbine Housings[R]. ASME GT2017-64468.
[95] Lynch S. Three-Dimensional Boundary Layer in a Turbine Blade Passage[J]. Journal of Propulsion and Power， 2017， 33(4): 954-963.
[96] Leonetti M， Lynch S， O’connor J， et al. Combustor Dilution Hole Placement and Its Effect on the Turbine Inlet Flowfield[J]. Journal of Propulsion and Power， 2017， 33(3): 750-763.
[97] Lavagnoli S， De Maesschalck C， Andreoli V. Design Considerations for Tip Clearance Control and Measurement on a Turbine Rainbow Rotor with Multiple Blade Tip Geometries[J]. Journal of Engineering for Gas Turbines and Power， 2017， 139(4).
[98] Kukutla P R， Prasad B V. Secondary Flow Visualization on Stagnation Row of a Combined Impingement and Film Cooled High-Pressure Gas Turbine Nozzle Guide Vane Using PIV Technique[J]. Journal of Visualization， 2017， 20(4): 817-832.
[99] Bosdas I， Mansour M， Kalfas A I， et al. Unsteady Flow Field and Coarse Droplet Measurements in the Last Stage of a Low-Pressure Steam Turbine with Supersonic Airfoils near the Blade Tip[J]. Journal of Engineering for Gas Turbines and Power， 2017， 139(9).
[100] Volino R J. Control of Tip Leakage in a High Pressure Turbine Cascade Using Tip Blowing[R]. ASME GT2016-56511.
[101] Schmitz J T， Perez E， Morris S C， et al. Highly Loaded Low-Pressure Turbine: Design， Numerical， and Experimental Analysis[J]. Journal of Propulsion and Power， 2016， 32(1): 142-152.
[102] Rebholz P S， Abhari R S， Kalfas A I， et al. Tip-Shroud Cutbacks in a Low-Pressure Gas Turbine Stage[J]. Journal of Propulsion and Power， 2016， 32(5): 1077-1086.
[103] Li S J， Yang S F， Han J C， et al. Turbine Blade Surface Phantom Cooling from Upstream Nozzle Trailing-Edge Ejection[J]. Journal of Thermophysics and Heat Transfer， 2016， 30(4): 770-781.
[104] Bellucci J， Rubechini F， Arnone A， et al. Numerical and Experimental Investigation of Axial Gap Variation in High Pressure Steam Turbine Stages[R]. ASME GT2016-56547.
[105] Shibukawa N， Fukushima T， Iwasaki Y. An Experimental Investigation of the Influence of Flash-Back Flow on Last Three Stages of Low Pressure Steam Turbines[J]. Journal of Engineering for Gas Turbines and Power， 2015， 137.
[106] Guillot S， Ng W F， Hamm H D， et al. The Experimental Studies of Improving the Aerodynamic Performance of a Turbine Exhaust System[J]. Journal of Engineering for Gas Turbines and Power， 2015， 137.
[107] Gomes R A， Niehuis R. Effects of Periodic Unsteady Inflow on Film Cooling and Heat Transfer on Highly Loaded High Pressure Turbine Blades with Flow Separation[J]. Journal of Turbomachinery， 2014， 136(2).
[108] Ciorciari R， Kirik I， Niehuis R. Effects of Unsteady Wakes on the Secondary Flows in the Linear T106 Turbine Cascade[J]. Journal of Turbomachinery， 2014， 136(9).
[109] Restemeier M， Jeschke P， Guendogdu Y， et al. Numerical and Experimental Analysis of the Effect of Variable Blade Row Spacing in a Subsonic Axial Turbine[J]. Journal of Turbomachinery， 2013， 135(2).
[110] Teuber R， Wilson M， Li Y S， et al. Computational Extrapolation of Turbine Sealing Effectiveness from Test Rig to Engine Conditions[J]. Proceedings of the Institution of Mechanical Engineers， Part A: Journal of Power and Energy， 2012， 227(2): 167-178.
[111] Segawa K， Senoo S， Hamatake H， et al. Steady and Unsteady Flow Measurements under Low Load Conditions in a Low Pressure Model Steam Turbine[R]. ASME ICONE20-POWER2012-54862.
[112] Montomoli F， Hodson H， Haselbach F. Effect of Roughness and Unsteadiness on the Performance of a New Low Pressure Turbine Blade at Low Reynolds Numbers[J]. Journal of Turbomachinery， 2010， 132(3).
[113] D'ovidio A， Littlewood L， Congiu F， et al. Comparison between Hot Wire and 5-Hole Pressure Probe Traverse Data in a Variable Density Two-Stages Air Turbine[R]. ASME GT2008-50753.

透平内部非稳态流动试验研究进展

Experimental Research Progress on InternalUnsteady Flow of Turbine

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 0

编辑推荐

Metrics

本文评价