石心怡 教授

2200 最高學歷:美國凱斯西儲大學   機械工程博士
研究領域:燃燒與推進,火場研究,熱流分析,能源工程,微重力科學
聯絡方式:電話:(03)211-8800 分機 5745 
     e-mail: hyshih@mail.cgu.edu.tw
實 驗 室:燃燒與熱流系統實驗室  分機  5728

簡歷

      ●學歷:

      美國凱斯西儲大學 機械與航太工程學系 博士後

      美國凱斯西儲大學 機械與航太工程學系 博士

      美國凱斯西儲大學 機械與航太工程學系 碩士

      國立交通大學 機械工程系 學士

 ● 經歷:

        長庚大學 教授 

        長庚大學 副教授 

         長庚大學 助理教授 

         工業技術研究院 系統與航太中心 研究員

         美國凱斯西儲大學機械與航太工程學系 博士後副研究員

目前進行中研究計畫的計劃名(起、迄日期)

           

計畫編號

名稱

起訖日期

NERPD2D0421

稀釋效應對合成氣體相向噴流擴散火焰可燃極限與NOx排放影響分析

2014/8/1~2015/7/31

發表論文

  1. Maaz Ajvad, Hsin-Yi Shih (2019). Combustion Analysis of Syngas Fuels Applied in a Micro Gas Turbine Combustor with a Rotating Casing. Proceedings of the ASME Turbo Expo, paper No. GT2019-90799, V04AT04A049, DOI: https://doi.org/10.1115/GT2019-90799. (EI)
  2. Chi-Rong Liu, Min-Tsung Sun, Hsin-Yi Shih (2018). Model Simulation and Design Optimization of a Can Combustor with Methane/Syngas Fuels for a Micro Gas Turbine. International Journal of Turbo and Jet Engines. DOI: https://doi.org/10.1515/tjj-2017-0057. (SCI, IF=863, 24/31, Engineering: Aerospace)
  3. Kuo-Hsing Yang, Hsin-Yi Shih (2017). NO Formation of Opposed-jet Syngas Diffusion Flames: Strain rate and Dilution Effects. International Journal of Hydrogen Energy, 42: 24517-24531. (SCI, IF=4.084, 31/103, Energy and Fuels)
  4. Chi-Rong Liu, Hsin-Yi Shih (2016). The Design and Model Simulation of a Micro Gas Turbine Combustor Supplied with Methane/Syngas Fuels. Proceedings of the ASME Turbo Expo, paper No. GT2016-56528, DOI: https://doi.org/10.1115/GT2016-56528. (EI)
  5. Chi-Rong Liu, Hsin-Yi Shih (2015). Model Analysis of Syngas Combustion and Emissions for a Micro Gas Turbine. Journal of Engineering for Gas Turbine and Power, vol. 137, 061507, pp1-10. (SCI, IF=1.653, 73/129, Mechanical Engineering)
  6. Hsin-Yi Shih, Chi-Rong Liu (2014). A Computational Study on the Combustion of Hydrogen/Methane Blended Fuels for a Micro Gas Turbine. International Journal of Hydrogen Energy, 39: 15103-15115. (SCI, IF=4.084, 31/103, Energy and Fuels)
  7. Hsin-Yi Shih, Jou-Rong Hsu, Yu-Heng Lin (2014). Computed Flammability Limits of Opposed-jet H2/CO Syngas Diffusion Flames. International Journal of Hydrogen Energy, 39: 3459-3468. (SCI, IF=4.084, 31/103, Energy and Fuels).
  8. Shih, H. Y. and Hsu, J. R., “Dilution Effects Analysis of Opposed-jet H2/CO Syngas Diffusion Flames,” Combustion Theory and Modelling, 17 (3): 543-562, 2013.
  9. Shih, H. Y. and Hsu, J. R., “Computed NOx Emission Characteristics of Opposed-jet Syngas Diffusion Flames,” Combustion and Flame, 159: 1851-1863, 2012.
  10. Shih, H. Y. and Hsu, J. R. “Computed Extinction Limits and Flame Structures of Opposed-jet Syngas Diffusion Flames,” Applied Mechanics and Materials v.110-116, p4899-4906, 2012.
  11. Chang, Y. Z., Hung, K. T., Shih, H. Y., Tsai, Z. R. “Surrogate Neural Network and Multi-objective Direct Algorithm for the Optimization of a Swiss-roll Type Recuperator,” International Journal of Innovative Computing Information and Control, v.8, n12, pp.8199-8241, 2012.
  12. Shih, H. Y. and Hsu, J. R., “A Computational Study of Combustion and Extinction of Opposed-jet Syngas Diffusion Flames,” International Journal of Hydrogen Energy, 36: 15868-15879, 2011.
  13. Shih, H. Y., Liu, C. R., “A Computational Study of hydrogen Substitution Effects on the Combustion performance for a Micro Gas Turbine,” Proceedings of ASME Turbo Expo, v3, pp.713-721, 2011.
  14. Shih, H. Y., Liu, C. R., “Combustion Characteristics and Hydrogen Addition Effects on the Performance of a Can Combustor for a Micro Gas Turbine,” Proceedings of ASME Turbo Expo, v5, pp.271-280, 2010.
  15. Shih, H. Y. and Huang, Y. C., “Thermal Design and Model Analysis of the Swiss-roll Recuperator for an Innovative Micro Gas Turbine,” Applied Thermal Engineering, 29: 1493-1499, 2009.
  16. Shih, H. Y., “Computed Flammability Limits and Spreading Rates of Upward Flame Spread over a Thin Solid in Low-Speed Buoyant Flows,” Combustion Science and Technology, 181: 379-395, 2009.
  17. Shih, H. Y. and Liu, C. R., “Combustion Characteristics of a Can Combustor with a Rotating Casing for an Innovative Micro Gas Turbine,” Journal of Engineering for Gas Turbines and Power, vol. 131, No.4, July, 2009.
  18. Shih, H. Y., “Flame Spread and Interactions in an Array of Thin Solids in Low-Speed Concurrent Flows,” Combustion Theory and Modelling, vol. 13, No. 3: 443-459, 2009.
  19. Shih, H. Y., “Computed Extinction Limits and Flame Structures of H2/O2 Counterflow Diffusion Flames with CO2 Dilution,” International Journal of Hydrogen Energy, 34: 4005-4013, 2009.
  20. Shih, H. Y. and Wu, H. C., “An Experimental Study of Upward Flame Spread and Interactions over Multiple Solid Fuels,” Journal of Fire Sciences, 26: 435-453, 2008.
  21. Chang, Y. Z., Hung, K. T., Shih, H. Y., “Optimizing the Swiss-roll Recuperator of an Innovative Micro Gas Turbine by a Surrogate Neural Network and the Multi-Objective Direct Algorithm,” Proceedings of the ASME Turbo Expo, v1, p713-721, 2008.
  22. Shih, H. Y., Liu, C. R., “Combustion Characteristics of a Can Combustor with a Rotating Casing for an Innovative Micro Gas Turbine,” Proceedings of ASME Turbo Expo, v3, Part A, pp. 21-29, 2008.
  23. Shih, H. Y., Wang, D. and Kuo, C. R., “Feasibility Study of an Innovative Micro Gas Turbine with a Swiss-roll Recuperator,” Proceedings of the ASME Turbo Expo, v5 Part A, p459-466, 2006.
  24. Ferkul, P., Kleinhenz, J., Shih, H. Y. et. al., “Solid Fuel Combustion Experiments in Microgravity Using a Continuous Fuel Dispenser and Related Numerical Simulations,” Microgravity Science and Technology XV/2 pp3-12, 2004.
  25. Kumar, A., Shih, H. Y. and T’ien, J. S., “A Comparison of Extinction Limits and Spreading Rates in Opposed and Concurrent Spreading Flames over Thin Solids,” Combustion and Flames, 132: 667-677, 2003.
  26. Shih, H. Y. and T’ien, J. S., “A Three-Dimensional Model of Flame Spread over a Thin Solid in Low-Speed Concurrent Flow,” Combustion Theory and Modelling, 7: 677-704, 2003.
  27. Feier, I. I., Shih, H. Y., Sacksteder, K. R., and T’ien, J. S. “Upward Flame Spread over Thin Solids in Partial Gravity,” Proceedings of the Combustion Institute 29: 2569-2577, 2002.
  28. Shih, H. Y. and T’ien, J. S., “Modeling Concurrent Flame Spread over a Thin Solid in a Low-Speed Flow Tunnel,” Proceedings of the Combustion Institute 28: 2777-2784, 2000.
  29. Shih, H. Y. and T’ien, J. S., “Modeling Concurrent Flame Spread over a Thin Solid in a Low-Speed Flow Tunnel,” Proceedings of the Combustion Institute 28: 2777-2784, 2000.
  30. Shih, H. Y., Bedir, H., T’ien, J. S., and Sung, C. J., “Computed Flammability Limits of Opposed-Jet H2/O2/CO2 Diffusion Flames at Low Pressure,” Journal of Propulsion and Power, vol. 15, No. 6, November-December, pp. 903-908, 1999.

Highly  Cited 著作(Max:5篇 Based on Google Scholar 2014/05):

  1. Shih, H. Y., Bedir, H., T’ien, J. S., and Sung, C. J., “Computed Flammability Limits of Opposed-Jet H2/O2/CO2 Diffusion Flames at Low Pressure,” Journal of Propulsion and Power, vol. 15, No. 6: 903-908, 1999. (Citations =18)
  2. Feier, I. I., Shih, H. Y., Sacksteder, K. R., and T’ien, J. S. “Upward Flame Spread over Thin Solids in Partial Gravity,” Proceedings of the Combustion Institute 29: 2569-2576, 2002. (Citations =18)
  3. Kumar, A., Shih, H. Y., and T’ien, J. S., “A Comparison of Extinction Limits and Spreading Rates in Opposed and Concurrent Spreading Flames over Thin Solids,” Combustion and Flames, 132: 667-677, 2003. (Citations =28)
  4. Shih, H. Y., and T’ien, J. S., “A Three-Dimensional Model of Flame Spread over a Thin Solid in Low-Speed Concurrent Flow,” Combustion Theory and Modelling, 7: 677-704, 2000. (Citations =8)
  5. Shih, H.Y., and Huang, Y. C., “Thermal Design and Model Analysis of the Swiss-roll Recuperator for an Innovative Micro Gas Turbine,” Applied Thermal Engineering, 29: 1493-1499, 2009. (Citations =26)

 

專利(請依以下格式填寫)

發明創作中文名稱

發明創作英文名稱

發明人

種類

證書號

專利起

專利迄

氣渦輪引擎

 

郭啟榮、王大維、吳嘉瑞、石心怡、熊道邦、張嘉揚

新型

中華民國專利第196915

2002/11/11

2014/04/29

 

Gas Turbine Engine

C.R. Kuo, T.W. Wang, J.R. Wu,

H.Y. Shih,

T.P. Hsiung,

C.Y. Chang

發明

US.6711889 B2

2004/03/30

2022/07/17
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