Research Progress of Plasma Magnetic Fluid Power Generation

doi:10.15982/j.issn.2095-7777.2018.04.003

PDF(1068 KB)

Journal of Deep Space Exploration ›› 2018, Vol. 5 ›› Issue (4) : 331-346. DOI: 10.15982/j.issn.2095-7777.2018.04.003

HUANG Hulin¹, LI Linyong¹, LI lai¹, LIU Feibiao²

Author information +

History +

Abstract

The working principle and power generation process of a plasma magnetohydrodynamic power generation system （MHDPG）is introduced，and the hot topics and key problems in the current research of MHDPG are analyzed. The research results and research progress are reviewed from both numerical simulation and experimental are analyzed investigations. It is believed that the MHDPG will be paid more and more attention，and will promote the development of aerospace technology.

Keywords

magnetic fluid power generation / plasma / numerical simulation and experimental research / aerospace power

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

HUANG Hulin, LI Linyong, LI lai, LIU Feibiao. Research Progress of Plasma Magnetic Fluid Power Generation. Journal of Deep Space Exploration, 2018, 5(4): 331‒346 https://doi.org/10.15982/j.issn.2095-7777.2018.04.003

This is a preview of subscription content, contact us for subscripton.

References

[1] 刘飞标,朱安文,唐玉华. 磁流体发电系统在空间电源中的应用研究[J]. 航天器工程,2015,24(1):111-119
LIU F B,ZHU A W,TANG Y H. Research on MHD power generation system in space electrical power application[J]. Spacecraft Engineering,2015,24(1):111-119
[2] 张百灵,朱涛,李益文,等. 超声速气流磁流体加速技术的应用与发展[J]. 力学与实践,2013,35(2):13-21
ZHANG B L,ZHU T,LI Y W,et al. Application and development of supersonic airflow acceleration technology based on magnetohydrodynamics[J]. Mechanics in Engineering,2013,35(2):13-21
[3] KOMATSU F,TANAKA M,MURAKAMI T,et al. Experiments on high-temperature inert gas plasma MHD electrical power generation with hall and diagonal connections[J]. Electrical Engineering in Japan,2015,193(3):17-23
[4] MURAKAMI T，OKUNO Y. Experiment and simulation of MHD power generation using convexly divergent channel[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013：861-72.
[5] LIBERATI A,OKUNO Y. Influence of anode-region boundary-layer separation on disk MHD-generator performance[J]. IEEE Transactions on Plasma Science,2007,35(5):1588-1597
[6] VEEFKIND A,KARAVASILEV P,WANG D. Performance experiments with a shock-tunnel-driven argon-cesium MHD disk generator[J]. Journal of Propulsion and Power,2015,4(4):363-369
[7] HARADA N,KIZUKA N,OKAMURA T,et al. Improvement of enthalpy extraction over 30% using a disk MHD generator with inlet swirl[J]. Energy Conversion & Management,1995,36(5):355-364
[8] ICHINOKIYAMA D，FUJINO T. Numerical analysis of non-equilibrium disk magnetohydrodynamic generator with swirl vanes[C]//AIAA Propulsion and Energy Froum.[S. l.]：AIAA，2016.
[9] LIBERATI A，MURAKAMI T，OKUNO Y，et al. Numerical simulation of less divergent disk MHD generator with high magnetic flux density[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013.
[10] MURAKAMI T，OKUNO Y，YAMASAKI H. A Seed-free supersonic non-equilibrium MHD generator with an rf-power assist plasma-initiation[C]//35th AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2004：2268.
[11] INUI Y,ITO H,ISHIDA T. Two dimensional simulation of closed cycle disk MHD generator considering nozzle and diffuser[J]. Energy Conversion and Management,2004,45(13):1993-2004
[12] ISHIKAWA M，SHIOMI T，INUI Y. Numerical examination of Ar-Cs MHD disk generator experiment with strong interaction[C]//Plasma Dynamics and Lasers Conference. [S.l.]：AIAA，2006：1357-1359.
[13] MACHERET S O,SHNEIDER M N,MILES R B. Magnetohydrodynamic power extraction from cold hypersonic airflows with external ionizers[J]. Journal of Propulsion & Power,2015,18(2):424-431
[14] HARADA N，SAKAMOTO N，ENDO H. Closed cycle MHD system using He/Xe working gas[C]//33rd Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2002.
[15] HARADA N，SAKAMOT N，ENDO H. Closed cycle MHD system using He/Xe working gas[C]//Plasmadynamics and Lasers Conference.[S. l.]：AIAA，1997.
[16] PAVSHUK V A,PANCHENKO V P. Open-cycle multi-megawatt MHD space nuclear power facility[J]. Atomic Energy,2008,105(3):175-186
[17] 徐益谦,蔡崧,赵以钰. 燃煤磁流体发电研究的现状与前景[J]. 东南大学学报(自然科学版),1990,20(2):106-113
[18] MACHERET S O,SHNEIDER M N,MILES R B,et al. Electron-beam-generated plasmas in hypersonic magnetohydrodynamic channels[J]. AIAA Journal,2012,39(39):1127-1138
[19] MURRAY R C，ZAIDI S H，SHNEIDER M N，et al. Observation of MHD effects with non-equlibrium ionization in cold supersonic air flows[C]//AIAA Aerospace Sciences Meeting and Exhibit.[S. l.]：AIAA，2004.
[20] SHIBKOV V，CHERNIKOV A，ERSHOV A，et al. Microwave discharges in supersonic plasma aerodynamics[C]//AIAA Aerospace Sciences Meeting and Exhibit.[S. l.]：AIAA，2004.
[21] 王宇天,张百灵,李益文,等. 基于均匀模型的低气压电容耦合射频放电特性研究[J]. 真空科学与技术学报,2016,36(7):773-778
WANG Y T,ZHANG B L,LI Y W,et al. Modeling and characterization of low-pressure capacitive coupled rf discharge properties[J]. Chinese Journal of Vacuum Science and Technology,2016,36(7):773-778
[22] SHIMIZU K,OKUNO Y,YAMASAKI H,et al. Numerical simulation of plasma and fluid flow in a shock-tube-driven disk MHD generator[J]. IEEE Transactions on Plasma Science,2000,28(5):1706-1712
[23] TANAKA M,OKUNO Y. Performance of a seed-free disk magnetohydrodynamic generator with self-excited joule heating in the nozzle[J]. IEEE Transactions on Plasma Science,2017,45(3):454-460
[24] MURAKAMI T,OKUNO Y,KABASHIMA S. Plasma stabilization and improvement in the performance of a nonequilibrium disk MHD generator by a radio-frequency electromagnetic field[J]. IEEE Transactions on Plasma Science,1999,27:2(2):604-612
[25] LIBERATI A,MURAKAMI T,OKUNO Y,et al. Numerical simulation of MHD flow behavior and performance in the disk MHD generator of closed loop experimental facility[J]. Journal of Arthroplasty,2006,28(9):168-71
[26] SAKAI T,MATSUMOTO M,MURAKAMI T,et al. Numerical simulation of power generation characteristics of a disk MHD generator with high‐temperature inert gas plasma[J]. LEEJ Transactions on Power & Energy,2012,179(129):553-558
[27] HARADA N,KIZUKA N,OKAMURA T,et al. Improvement of enthalpy extraction over 30% using a disk MHD generator with inlet swirl[J]. Energy Conversion & Management,1995,36(5):355-364
[28] LIBERATI A,MURAKAMI T,OKUNO Y,et al. Numerical simulation on performance of disk MHD generator in the closed-loop experimental facility[J]. IEEE Transactions on Plasma Science,2006,34(6):2669-2677
[29] LIBERATI A，MURAKAMI T，OKUNO Y，et al. Numerical simulation of less divergent disk MHD generator with high magnetic flux density[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013.
[30] LIBERATI A,OKUNO Y. Influence of anode-region boundary-layer separation on disk MHD-generator performance[J]. IEEE Transactions on Plasma Science,2007,35(5):1588-1597
[31] LIBERATI A，OKUNO Y. Numerical Simulation of High Mach Number-Low Static Pressure Plasma in A Highly Efficient Disk MHD Generator[C]//39th Plasmadynamics and Lasers Conference. Seattle，Washington：[s. n.]，2008.
[32] KABASHIMA S,YAMASAKI H,SHIODA S,et al. Dynamic properties of nonequilibrium plasma in disk MHD generator[J]. Journal of Propulsion & Power,1985,1(6):425-431
[33] KABASHIMA S，YAMASAKI Y，SHIODA S. Magnetohydrodynamics in a closed cycle inert gas MHD generator[C]//19th AIAA，Fluid Dynamics，Plasma Dynamics，and Lasers Conference.[S. l.]：AIAA，1987：1217.
[34] OKAMURA T,OKUNO Y. Performance of Disk MHD generator with high magnetic flux density[J]. Energy Conversion & Management,2001,42(7):855-866
[35] FUKUDA H,KABASHIMA S. Ring-shaped discharge structures in a closed cycle MHD disk generator[J]. Journal of Propulsion & Power,1987,3(3):249-254
[36] SUEKANE T,YOSHIKAWA K,KABASHIMA S. The effects of boundary layer phenomena on the performance of disk CCMHD generator[J]. IEEE Transactions on Plasma Science,1995,23(1):97-102
[37] LOU G，SHIMIZU K，OKUNO Y. Influences of inlet fluctuation of seed fraction on the performance of CCMHD generator with strong MHD interaction[C]//Plasmadynamics and Lasers Conference.[S. l.]：[s. n.]，2013.
[38] LOU G,SHIMIZU K,OKUNO Y. Performance of closed cycle disk MHD generator with inlet fluctuation of seed fraction[J]. IEEE Transactions on Plasma Science,2003,31(1):129-136
[39] HARADA N,TSUNODA K. Study of a disk MHD generator for nonequilibrium plasma generator (NPG) system[J]. Energy Conversion & Management,1998,39(5):493-503
[40] HARADA N. High performance pulsed power generation system using a disk MHD generator driven by NPG system[C]//IEEE International Pulsed Power Conference.[S. l.]：IEEE，1997：480-488.
[41] LITCHFORD J R，HARADA N. Multi-MW closed cycle MHD nuclear space power via nonequilibrium He/Xe working plasma[C]//Proceedings of Nuclear and Emerging Technologies for Space. Albuquerque，NM：[s. n.]，2011.
[42] HARADA N. High efficiency and low specific mass mixed inert gas non-equilibrium MHD Single system for space power[J]. Power,2005,2:238-246
[43] HARADA N，KIEN L C，HISHIKAWA M. Basic studies on closed cycle MHD power generaor system for space application[C]//35th AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2004：2365.
[44] HARADA N，SAKAMOTO N，ENDO H. Closed cycle MHD system using He/Xe working gas[C]//Plasmadynamics & Lasers Conference.[S. l.]：AIAA，1997.
[45] HARADA N，LE C K，TASHIRO T. Closed cycle MHD generator using He/Xe working plasma[C]//Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013.
[46] HARADA N. High efficiency and low specific mass mixed inert gas non-equilibrium MHD single system for space power[J]. Power,2005,149:238-246
[47] HARADA N. Recent progress in the study of closed cycle MHD system[J]. Stroke:a Journal of Cerebral Circulation,2013,23(4):519-26
[48] HARADA N，TASHIRO T. Influence of recombination coefficient on discharge structure and plasma stability in closed cycle MHD generator with He/Xe working gas[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2003.
[49] HARADA N，LE C K，TASHIRO T. Closed cycle MHD generator using He/Xe working plasma[C]//Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013.
[50] YAMAGUCHI H，ISHIKAWA M. Stability analyses of a large-scale transonic coal-fired disk MHD generator designed for CO₂ recovery[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2003.
[51] KOBAYASHI H,OKUNO Y. Feasibility study on frozen inert gas plasma MHD generator[J]. IEEE Transactions on Plasma Science,2000,28(4):1296-1302
[52] NAGAI S，OKUNO Y，KOBAYASHI H. R-z two-dimensional numerical simulation of frozen inert gas plasma MHD generator[C]//34th AIAA Plasmadynamics and Lasers Conference.Orlando，Florida：AIAA，2013.
[53] KOBAYASHI H，SATOU Y，OKUNO Y. Numerical simulation on performance of frozen inert gas plasma MHD generator[C]//Plasma-dynamics and Lasers Conference.[S. l.]：AIAA，2013.
[54] KOBAYASHI H,OKUNO Y,KABASHIMA S. Three-dimensional simulation of nonequilibrium seeded plasma in closed cycle disk MHD generator[J]. IEEE Transactions on Plasma Science,1997,25(2):380-385
[55] SAKAI T,MATSUMOTO M,MURAKAMI T,et al. Numerical simulation of power generation characteristics of a disk MHD generator with high‐temperature inert gas plasma[J]. IEEJ Transactions on Power & Energy,2012,179(129):553-558
[56] INUI Y. New Conceptual design method of non-equilibrium disk MHD generator[J]. Energy Conversion & Management,1993,36(2):109-119
[57] INUI Y,EMOTO N,ISHIKAWA M,et al. Conceptual design of coupled nonequilibrium disk MHD generator and superconducting magnet system[J]. Energy Conversion & Management,1996,37(12):1765-1774
[58] INUI Y，KOSUGI A，ISHIKAWA M. Effect of diffuser back pressure on performance of supersonic closed-cycle disk MHD generator[C]//Plasmadynamic and Lasers Conference.[S. l.]：AIAA，1999.
[59] ISHIKAWA M，SHIOMI T，INUI Y. Numerical examination of Ar-Cs MHD disk generator Experiment with strong interaction[C]//Plasma Dynamics and Lasers Conference.[S. l.]：AIAA，2006：1357-1359.
[60] ISHIKAWA M,SHIOMI T,INUI Y,et al. Analysis of Ar-Cs magnetohydrodynamics disk generator with strong interaction[J]. Journal of Propulsion & Power,2015,14(3):403-408
[61] RIKIYA T，FUJINO T，OKUNO Y. Numerical Simulation of Frozen Inert Gas Plasma Magnetohydrodynamic Generator with Collisional-Radiative Model. [C]//14 th Inthernatinal Energy Conversion Engineering Conference. [S.l.]: AIAA, 2016.
[62] HARA T,VEEFKING A,RIETJENS L H T. Numerical simulation of the inhomogeneous discharge structure in noble gas MHD generators[J]. AIAA Journal,2012,20:1473-1480
[63] VEEFKIND A,KARAVASILEV P,WANG D. Performance experiments with a shock-tunnel-driven argon-cesium MHD disk generator[J]. Journal of Propulsion and Power,2015,4(4):363-369
[64] VEEFKIND A. Experiments on plasma-physical aspects of closed cycle MHD power generation[J]. IEEE Transactions on Plasma Science,2005,32(6):2197-2209
[65] DOGADAYEV R V，PANCHENKO V P，POLULYAKH Y P，et al. The disk MHD generator on a nonequilibrium Ar-Cs plasma for a MHD gas-turbine power plant[C]//Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2002.
[66] PAVSHUK V A,PANCHENKO V P. Open-cycle multi-megawatt MHD space nuclear power facility[J]. Atomic Energy,2008,105(3):175-186
[67] RANKIN R,SELF S A R. Study of the insulating wall boundary layer in a faraday MHD generator[J]. AIAA Journal,2015,18(9):1094-1100
[68] MACHERET S,SHNEIDER M,MILES R. Electron Beam Generated Plasmas in Hypersonic MHD Channels[J]. AIAA Journal,2001,39(6):1127-1138
[69] MACHERET S,SHNEIDER M,MILES R. MHD power extraction from cold hypersonic air flow with external ionizers[J]. Journal of Propulsion & Power,1999,18(2):424-431
[70] MACHERET S，SHNEIDER M，MILES R. Potential performance of supersonic MHD power generators[C]//39th AIAA Aerospace Sciences Meeting & Exhibit.Reno，NV：[s.n.]，2001.
[71] MACHERET S O,SHNEIDER M N,MILES R B. Magnetohydrodynamic power extraction from cold hypersonic airflows with external ionizers[J]. Journal of Propulsion & Power,2015,18(2):424-431
[72] MACHERET S O，SCHNEIDER M，MURRAY R，et al. Rdhwt/Mariah II MHD Modeling and experiments Review[C]// 24th AIAA Aerodynamic Measurement Technology and Ground Testing Conference.Portland，Oregon：AIAA，2004.
[73] SHNEIDER M，MACHERET S，MILES R. Electrode sheaths and boundary layers in hypersonic MHD channels[C]//Plasmadynamic and Lasers Conference. [S. l.]：AIAA，1999.
[74] GAITONDE D V. Three-dimensional flow-through scramjet simulation with MGD energy-bypass[C]//Aerospace Sciences Meeting and Exhibit. [S. l.]：AIAA，2003.
[75] GAITONDE D V. Magnetohydrodynamic energy-bypass procedure in a three-dimensional scramjet[J]. Journal of Propulsion & Power,1971,22(3):498-510
[76] ISHIKAWA M,ITOH K. Three dimensional constricted electric current near anode and cathode of faraday MHD generator[J]. Energy Conversion & Management,2003,44(13):2111-2124
[77] TAMADA Y，NIWA N，TAKAHASHI T，et al. Influence of cross-sectional shape on generator performance and electromagnetic fluid phenomena of DCW-MHD generators for hypersonic airplanes[C]//AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2013.
[78] TAKAHASHI T,FUJINO T,ISHIKAWA M. Comparison of generator performance of small-scale MHD generators with different electrode dispositions and load connection systems[J]. Journal of International Council on Electrical Engineering,2014,4(3):192-198
[79] GOTOH D，TAKAHASHI T，FUJINO T，et al. Computational Analysis of HVEPS Scramjet MHD Power Generation[C]//38th AIAA Plasmadynamics and Lasers Conference. Miami，FL：AIAA，2007.
[80] NAGAKUBO Y，YAMASHITA T，TAKAHASHI T，et al. Comparison of generator performance of small-scale diagonal and faraday MHD generators[C]//Plasmadynamics and Lasers Conference. [S. l.]：AIAA，2013.
[81] MATSUMOTO M,MURAKAMI T,OKUNO Y. Numerical study on feasibility of pulsed-heat-source high-temperature inert gas MHD electrical power generation[J]. Transactions of the Japan Society for Aeronautical & Spaceences,2008,51(173):164-169
[82] TANAKA M,OKUNO Y. High-temperature inert gas plasma faraday-type magnetohydrodynamic generator with various working gases[J]. Journal of Propulsion and Power,2016,32(4):1-6
[83] TANAKA M,MURAKAMI T,OKUNO Y. Numerical simulation of performance of high-temperature inert gas plasma faraday-type magnetohydrodynamic generator[J]. Journal of Propulsion & Power,2015,38(6):1-8
[84] OKAMURA T，HARADA N，KABASHIMA S，et al. Review and new results of high enthalpy extraction experiments at Tokyo institute of technology[R]. American Society of Mechanical Engineers. Fairfield，NJ （United States）：[s.n.]，1994.
[85] HARADA N,SUEKANE T,TSUNODA K,et al. High-enthalpy extraction demonstration with closed-cycle disk MHD generators[J]. Journal of Engineering for Gas Turbines and Power,1996,118(1):15-21
[86] HARADA N，SUEKANE T，OKAMURA T，et al. Improvement of generator performance in FUJI-1 CCMHD blow-down experiment[R]. American Society of Mechanical Engineers，Fairfield，NJ （United States），1993.
[87] OKUNO Y,OKAMURA T,YOSHIKAWA K,et al. Closed cycle MHD power generation Experiments with FUJI-1 blow-down facility[J]. Tokyo Tech,ILG-MHD,1996(1):155-164
[88] OKUNO Y，OKAMURA T，YOSHIKAWA K，et al. High enthalpy extraction experiments with CCMHD Fuji-1 blow-down facility[C]//29th AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，1998.
[89] OKUNO Y，OKAMURA T，OSHIKAWA K，et al. Power generation experiments with CCMHD Fuji-1 blow-down facility[C]//30th Plasmadynamic and Lasers Conference. [S. l.]：AIAA，1999.
[90] OKUNO Y,OKAMURA T,YOSHIKAWA K,et al. High enthalpy extraction experiments with Fuji-1 MHD blow-down facility[J]. Energy Conversion and Management,1999,40(11):1177-1190
[91] HARADA N，SAITO Y，TSUNODA K，et al. Closed cycle MHD blow-down experiments with helium working gas[C]//22nd Fluid Dynamics，Plasma Dynamics and Lasers Conference. [S. l.]：AIAA，1990.
[92] OKUNO Y,OKAMURA T,SUEKANE T,et al. Magnetohydrodynamic power generation experiments with Fuji-1 blowdown facility[J]. Journal of Propulsion and Power,2003,19(5):894-900
[93] SUEKANE T. Behavior of fully ionized seed plasma excited by microwave[J]. IEEE Transactions on Plasme Sciences,1997,25(1):7-14
[94] MURAKAMI T,OKUNO Y,KABASHIMA S. Structure of inductively coupled plasma with metal vapor ionization[J]. IEEE transactions on plasma science,1997,25(4):769-775
[95] FUJINO T,MURAKAMI T,OKUNO Y,et al. Experimental studies on performance of a nonequilibrium disk MHD generator with radio-frequency preionization[J]. IEEE transactions on plasma science,2003,31(1):166-173
[96] ITOH T，MURAKAMI T，FUJINO T，et al. Improvement in performance of He/Cs MHD generator by applying radio-frequency electromagnetic field[C]//35th AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2004.
[97] MURAKAMI T，OKUNO Y，YAMASAKI H. A seed-free supersonic non-equilibrium mhd generator with an rf-power assist plasma-initiation[C]. 35th AIAA Plasmadynamics and Lasers Conference.[S. l.]：AIAA，2004.
[98] MURAKAMI T,OKUNO Y,YAMASAKI H. RF-assisted magnetohydrodynamic power generation in a pure-argon plasma[J]. Applied Physics Letters,2005,86(17):171502
[99] MURAKAMI T,OKUNO Y,YAMASAKI H. Performance of RF-assisted magnetohydrodynamics power generator[J]. Physics of plasmas,2005,12(11):113503
[100] MURAKAMI T,OKUNO Y. Experiments and numerical simulations on high-density magnetohydrodynamic electrical power generation[J]. Journal of Applied Physics,2008,104(6):063307
[101] MURAKAMI T，OKUNO Y. High-density MHD energy conversion in a seed-free argon plasma[C]//39th Plasmadynamics and Lasers Conference. [S. l.]：AIAA，2008.
[102] MURAKAMI T,OKUNO Y. Simulation and demonstration of magnetohydrodynamic energy conversion in a high-temperature inert gas[J]. Physics of Plasmas,2009,16(3):033501
[103] KLINE J，ZAIDI S，MURRAY R，et al. Nonequilibrium ionization techniques for MHD power extraction in high-speed flows[C]//Aerospace Sciences Meeting and Exhibit. [S. l.]：AIAA，2013.
[104] MILES R,SHNEIDER M,VASILYAK L,et al. Magnetohydrodynamic power generation using externally ionized,cold,supersonic air as working fluid[J]. AIAA Journal,2006,44(1):119-127
[105] MEYER R，MCELDOWNEY B，CHINTALA N，et al. Experimental studies of plasma assisted ignition and MHD supersonic flow control[C]//41st AIAA Aerospace Sciences Meeting & Exhibit.Reno，NV：AIAA，2003.
[106] MEYER R，MCELDOWNEY B，CHINTALA N，et al. Measurements of electrical parameters of a supersonic nonequilibrium MHD channel[C]//34th AIAA Plasmadynamics and Lasers Conference. [S. l.]：AIAA，2003.
[107] MEYER R，CHINTALA N，ADAMOVICH I，et al. Lorentz force effect on a supersonic ionized boundary layer[C]//42nd AIAA Aerospace Sciences Meeting and Exhibit.[S. l.]：AIAA，2004.
[108] MEYER R,NISHIHARA M,HICKS A,et al. Measurement of flow conductivity and density fluctuations in supersonic nonequilibrium magnetohydrodynamic flows[J]. AIAA Journal,2005,43(9):1923-1930
[109] NISHIHARA M,JIANG N,RICH J W,et al. Low-temperature supersonic boundary layer control using repetitively pulsed magnetohydrodynamic forcing[J]. Physics of Fluids,2005,17(10):106102
[110] NISHIHARA M,RICH J W,LEMPERT W R,et al. Low-temperature M = 3 flow deceleration by lorentz force[J]. Physics of Fluids,2006,18(8):086101
[111] NISHIHARA M，JIANG N，LEMPERT W，et al. MHD supersonic boundary layer control using pulsed discharge ionization[C]//43rd AIAA Aerospace Sciences Meeting and Exhibit. [S.l.]：AIAA，2005.
[112] LINEBERRY J T，BEGG L L，CASTRO J H，et al. HVEPS scramjet-driven MHD power demonstration test results[C]//AIAA Plasmadynamics and Lasers Conference. [S. l.]：AIAA，2007.
[113] MOELLER BT，LINEBERRY J，BEGG L L，et al. HVEPS combustion driven MHD power demonstration tests[C]//Plasmadynamics and Lasers Conference. [S. l.]：AIAA，2006.
[114] LINEBERRY J，BEGG L L，CASTRO J，et al. Scramjet driven MHD power demonstration test - hveps project overview[C]//AIAA/AHI Space Planes and Hypersonic Systems and Technologies Conference. [S. l.]：AIAA，2013.
[115] TANAKA M,MURAKAMI T,OKUNO Y. Plasma characteristics and performance of magnetohydrodynamic generator with high-temperature inert gas plasma[J]. Plasma Science IEEE Transactions on,2014,42(12):4020-4025
[116] TANAKA M,YU A,LIANG Z,et al. Experiments on high-temperature xenon plasma magnetohydrodynamic power generation[J]. IEEE Transactions on Plasma Science,2016,44(7):1-6
[117] TANAKA M,MURAKAMI T,OKUNO Y. Power generation experiments with a high temperature inert gas plasma Faraday type MHD generator[J]. IEEJ Transactions on Power and Energy,2013,134(7):58-65
[118] TANAKA M,MURAKAMI T,OKUNO Y. Plasma fluid flow behavior and power generation characteristics in a high-temperature inert gas plasma faraday MHD generator[J]. IEEJ Transactions on Power and Energy,2016,194(2):46-53
[119] TANAKA M，HITOTSUBASHI Y，OKUNO Y. Fundamental studies of radio-frequency preionization for frozen inert gas plasma magnetohydrodynamic electrical power generation[C]//International Energy Conversion Engineering Conference. [S. l.]：AIAA，2016.
[120] TANAKA M,ZHUANG Y,KOMATSU F,et al. Experiments of high temperature inert gas plasma MHD power generation with a faraday type generator[J]. 電気学会研究会資料. fte,新エネルギー·環境研究会,2013,2011:19-24
[121] MURAKAMI T,ZHUANG Y,OKUNO Y. High-temperature inert gas plasma magnetohydrodynamic energy conversion by using linear-shaped Faraday-type channel[J]. Journal of Applied Physics,2013,113(113):1713-2
[122] KOMATSU F,TANAKA M,MURAKAMI T,et al. Experiments on high‐temperature inert gas plasma MHD electrical power generation with Hall and diagonal connections[J]. IEEJ Transactions on Power & Energy,2014,134(7):620-625
[123] 郑小梅,吕浩宇,徐大军,等. 二维超燃冲压发动机磁控进气道的数值模拟[J]. 推进技术,2010,31(1):12-17
ZHENG X M,LU H Y,XU D J,CAI G B. Numerical simulation of a two-dimensional scramjet MHD controlled inlet[J]. Journal of Propulsion Technology,2010,31(1):12-17
[124] 郑小梅,徐大军,蔡国飙. 磁控进气道二维性能计算[J]. 航空动力学报,2009,24(3):111-117
ZHENG X M,XU D J,CAI G B. Numerical simulation of the two-dimensional magneto-hydro-dynamic controlled inlet[J]. Journal of Aerospace Power,2009,24(3):111-117
[125] 郑小梅,吕浩宇,徐大军,等. MHD加速器模式磁控进气道的优化设计[J]. 航空学报,2010,31(2):223-230
ZHENG X M,LU H Y,XU D J,et al,Optimization of Accelerator Mode MHD controlled inlet[J]. Optimization of Accelerator Mode MHD controlled inlet[J]. ACTA Aeronauticaet Astronautica Sinica,2010,31(2):223-230
[126] 郑小梅,徐大军,蔡国飙. MHD能量旁路超燃冲压发动机可行性分析[J]. 北京航空航天大学学报,2009,35(3):272-275
ZHENG X M,XU D J,CAI G B. Feasibility study of MHD energy bypass scramjet[J]. Journal of Beijing University ofAeronautics and Astronautics,2009,35(3):272-275
[127] 吕浩宇,李椿萱,董海涛. 三维超声速磁流体发生器的流动特性[J]. 中国科学:物理学力学天文学,2009(3):435-445
[128] 吕浩宇,李椿萱. Hall效应对磁流体压缩管道电磁流动特性的影响[J]. 科学通报,2010(12):1182-1188
[129] 吕浩宇,甄华萍,李椿萱,等. 横截面形状对超声速磁流体发生器性能的影响[J]. 航空学报,2015,36(11):3549-3556
LYU H Y,ZHEN H P,LI C X,et al. Influence of cross-sectional shape on the performance of supersonic magnetohydrodynamic generator[J]. Acta Aeronautica ET Astronautica Sinica,2015,36(11):3549-3556
[130] 许振宇,李椿萱. 超声速磁流体管道流动的数值模拟[J]. 北京航空航天大学学报,2005,31(8):893-898
[131] 黄浩,黄护林,张义宁,等. 高超声速等截面磁流体发电机性能研究[J]. 航空动力学报,2013,28(3):573-582
HUANG H,HUANG H L,ZHANG Y N,et al. Performance investigation of hypersonic rectangular MHD generator[J]. Journal of Aerospace Power,2013,28(3):573-582
[132] 黄浩,黄护林,张喜东,等. 基于电子束电离的高超声速磁流体发电机[J]. 推进技术,2013,34(5):706-712
HUANG H,HUANG H L,ZHANG X D,et al. Hypersonic Magnetohydrodynamic Generator Based on Electron-Beam-Generated Ionization[J]. Journal of Propulsion Technology,2013,34(5):706-712
[133] 黄浩. 高超声速磁流体发生器性能研究[D].南京：南京航空航天大学，2012.
[134] 胡海洋,杨云军,周伟江. 大霍尔系数下电离气体与磁场相互作用规律数值研究[J]. 力学学报,2011,43(3):453-460
HU H Y,YANG Y J,ZHOU W J. Numerical Research On The Interaction Between Ionized Gas And Magnetic Field Under High Hall Parameter[J]. Chinese Journal of Theoretical and Applied Mechanics,2011,43(3):453-460
[135] 田正雨. 高超声速流动的磁流体力学控制数值模拟研究[D]. 合肥：国防科学技术大学，2008.
[136] 何淼生,杨文将,郑小梅,等. 基于磁流体控制的高超声速进气道黏性效应[J]. 航空动力学报,2013,28(2):365-371
HE M S,YANG W J,ZHENG X M,et al. Viscosity effect of hypersonic inlet based on magnetohydrodynamic control[J]. Journal of Aerospace Power,2013,28(2):365-371
[137] 卜少科,薛雅心. 高超声速磁流体数值模拟研究[J]. 现代电子技术,2014(5):137-139
BU S K,XUE Y X. Research on numerical simulation of hypersonic MHD[J]. Modern Electronics Technique,2014(5):137-139
[138] 张向洪. 高超声速流场电磁干扰数值模拟研究[D]. 南京：南京航空航天大学，2013.
[139] 苏纬仪,张新宇,张堃元. 洛仑兹力控制高超声速进气道边界层分离的数值模拟[J]. 推进技术,2011,32(1):36-41
SU W Y,ZHANG X Y,ZHANG K Y. Numerical investigation of Lorentz force control on hypersonic inlet boundary layer separation[J]. Journal of Propulsion Technology,2011,32(1):36-41
[140] 黄富来,黄护林. 磁场对高超声速弱电离气体流动的影响[J]. 航空学报,2009,30(10):1834-1839
HUANG F L,HUANG H L. Effect of magnetic field on hypersonic weakly ionized gas flow[J]. ACTA Aeronautica Et Astronautica Sinica,2009,30(10):1834-1839
[141] 黄富来,黄护林. 高超声速化学非平衡流动MHD效应的数值模拟[J]. 工程热物理学报,2009,30(11):1946-1948
HUANG F L,HUANG H L. Numerical simulation of mhd effects on hypersonic chemical nonequilibrium flow[J]. Journal of Engineering Thermophysics,2009,30(11):1946-1948
[142] 黄富来,黄护林. 均匀磁场中高超声速弱电离气体流动数值模拟[J]. 航空动力学报,2009,24(11):53-61
HUANG F L,HUANG H L. Numerical simulation of weakly ionized gas hypersonic flow under uniform magnetic field[J]. Journal of Aerospace Power,2009,24(11):53-61
[143] 徐益谦,姚伟文,方秋华. JS-1磁流体发电实验装置的研究[J]. 东南大学学报(自然科学版),1979(s1):5-17
[144] 周纪瑜,徐益谦,魏启东. JS-2磁流体发电机电极的温度场与热应力的数值分析[J]. 东南大学学报(自然科学版),1983,13(1):47-55
[145] 严陆光,居滋象,沙次文等. 磁流体发电的国际进展与我国的战略(续)[J]. 电工电能新技术,1994(2):11-17
[146] 贡光禹. 国外燃煤磁流体发电的研究与开发[J]. 高技术通讯,1991(5):30-33
[147] 佚名. 美国的燃煤磁流体发电研究[J]. 全球科技经济瞭望,1988(11):56-58
[148] 沙次文. 美国田纳西大学空间研究所的磁流体发电研究[J]. 电工电能新技术,1983(3):52-58
[149] 何学裘. 燃煤磁流体发电通道研究的几个问题[J]. 电工电能新技术,1988(2):8-15
[150] 王炳南. 燃煤磁流体发电通道的发展及其关键技术[J]. 电工电能新技术,1987(4):23-28
[151] 李文宏. 燃煤磁流体发电通道绝缘材料--Sialon-BN复合材料[J]. 工程塑料应用,1994(6):11-13
[152] 刘傅博. 燃煤磁流体发电通道绝缘材料的研究与分析[J]. 材料导报,1993(6):50-52
[153] 李文宏,张光明. 用于燃煤磁流体发电通道的Sialon绝缘材料的研究[J]. 现代技术陶瓷,1993(2):17-24
[154] 刘传博. 磁流体(MHD)发电通道绝缘材料的新发展[J]. 材料科学与工程学报,1993(4):60-64
LIU C B. The Latest development in Channel Insulator of MHD Generator[J]. Materials Science & Engineering,1993(4):60-64
[155] 程永元,蔡崧. 高效率、低污染、高强度燃煤磁流体(MHD)发电燃烧室研究[J]. 动力工程学报,1995(5):56-61
[156] 魏启东,蔡崧. 20 MW MHD燃煤燃烧室热态试验研究[J]. 高技术通讯,1995(8):51-54
[157] 郑文德,陈爱元. 燃煤磁流体发电用燃烧室的理论和试验研究[J]. 高技术通讯,1992(7):31-35
[158] 蓝计香,金保升,李大骥等. 磁流体发电种子循环和还原法再生的实验研究[J]. 东南大学学报自然科学版,1990,20(2):123-127
[159] 李希南. 小型爆炸磁流体发电机实验装置研制[D]. 北京：中国科学院电工研究所，2006.
[160] LI Y W,LI Y H,LU H Y,et al. Preliminary experimental investigation on MHD power generation using seeded supersonic argon flow as working fluid[J]. Chinese Journal of Aeronautics,2011,24(6):701-708
[161] FAN H，ZHANG B L，LI Y W，et al. Preliminary experimental investigation on CCRF barrier discharge in supersonic flow[C]//International Conference on Mechanics and Civil Engineering. Wuhan，China：[s.n.]，2014.
[162] YANG P,ZHANG B,LI Y,et al. Investigation of MHD power generation with supersonic non-equilibrium RF discharge[J]. Chinese Journal of Aeronautics,2016,29(4):855-862