亚博APP买球

師資隊伍

方俊

 

個人履歷

亞博APP買球安全技術及工程博士(2004)
亞博APP買球博士后 (2004-2006)
亞博APP買球副研究員(2007-至今)
教育部新世紀優秀人才支持計劃 (2012)
  University of California, San Diego
訪問學者(2014-2015

  

研究方向

特殊條件下著火、燃燒、火蔓延火災動力學機理與防控技術

  

主講課程

火災控制技術基礎

課程編號: 232085;學時: 40/60;學分: 3

現代安全監測技術

(課程編號: SE1520701;學時: 60;學分: 3)

  

個人獲獎

安徽省教學成果一等獎(1/5)(2020

高等學校科學研究優秀成果獎(自然科學獎二等)(4/6)(2017

教育部新世紀優秀人才計劃(2012

王寬誠育才獎二等獎(2013

安徽省自然科學優秀論文一等獎(2013

中國科大首屆青年教師教學基本功競賽二等獎

2012

  http://wp.freemoviesavage.com/_upload/article/images/0c/f4/bf98cc1846088e0596e35ba16c49/W020111028389490235043.jpg

學位/職稱

工學博士

亞博APP買球副研究員

博士生導師

  

辦公室電話

(+86)551 63607119

E-mail: fangjun@freemoviesavage.com

 

科研項目

燃燒拖曳與輻射影響下壓縮空氣泡沫的鋪展運動與抑制火焰機理:
國家自然科學基金委面上項目,主持,執行期: 2021.01-2024.12

微重力強迫對流條件下高溫導線過載著火與火蔓延機制:

國家自然科學基金委面上項目,主持,執行期: 2016.01-2019.12

微重力強迫對流條件下火災與非火災顆粒群光散射規律與反演識別方法:

國家自然科學基金項目,主持,執行期: 2011.1-2013

西藏低壓缺氧環境對火災煙氣探測的影響機理:

國家自然科學基金委青年基金項目,主持,執行期: 2008.01-2010.12

教育部新世紀優秀人才支持計劃項目:

教育部人才項目,主持,2013.01-2015.12
環境風作用下固體火災復雜擴散燃燒行為的基礎問題研究:

國家自然科學基金委重點項目,重要骨干,2017.01-2021.12
城市地下空間復雜邊界條件下火災動力學行為研究:

國家自然科學基金委專項基金項目,重要骨干,2014.1-2018.12
化工園區大型油氣火災滅火技術及裝備研究:

科技部重點研發計劃課題子課題,主持,2016.07-2019.12
基于物聯網技術的交通樞紐綜合體火災防控關鍵技術研究:

科技部十二五科技支撐課題子課題,主持,2011.10-2013.12

 

學術任職

國際火災安全科學學會終身會員
國際燃燒學會會員
清華大學合肥公共安全研究院消防安全科技專家
工程與材料學部、信息科學部國家自然科學基金委通訊評議專家
141516屆國際火災探測大會分會主席
17屆國際火災探測/滅火大會Technical Program Committee委員

 

代表性論著

編著:

吳龍標,方俊,謝啟源.《火災探測與信息處理》,北京: 化學工業出版社,2006

廖光煊,方俊.《燃燒技術手冊》第23火災探測與清潔高效滅火技術,北京: 化學工業出版社,2008

 

發明專利:

一種熱分層環境下煙氣羽流運動模擬實驗裝置,ZL200810246203.32010-06-23

電導線陰燃煙顆粒采集設備,ZL201110178867.22013-8-7

一種強迫對流環境下擴散火焰實驗裝置,ZL201110211328.42013-07-07

 

特邀報告:

浮力/動量主控下的燃燒與火焰形態及輻射行為(主題特邀報告), 2017年中國工程熱物理學會燃燒學學術年會, 中國南京, 2017-10-132017-10-15

 

代表性論文:

[1]L. Zhao, Q. Zhang, R. Tu, J. Fang, J. Wang, Y. Zhang, Effects of electric current and sample orientation on flame spread over electrical wires, Fire Safety Journal, 112 (2020).

[2]K. Wang, J. Fang, H.R. Shah, S. Mu, X. Lang, J. Wang, Y. Zhang, A theoretical and experimental study of extinguishing compressed air foam on an n-heptane storage tank fire with variable fuel thickness, Process Safety and Environmental Protection, 138 (2020) 117-129.

[3]S. Tao, J. Fang, Y. Meng, H.R. Shah, L. Yang, Ignition risk analysis of common building material cylindrical PMMA exposed to an external irradiation with in-depth absorption, Construction and Building Materials, 251 (2020).

[4]K. Li, J. Wang, S. Luo, Z. Wang, X. Zhou, J. Fang, L. Su, R. Tu, Experimental investigation on combustion characteristics of flammable refrigerant R290/R1234yf leakage from heat pump system for electric vehicles, Royal Society Open Science, 7 (2020).

[5]Y. Zhang, J. Fang, J.W. Wang, L.Y. Zhao, Y.M. Zhang, Ignition and flame spread over thermal aging electrical wires in subatmospheric pressure, Journal of Thermoplastic Composite Materials, (2019).

[6]Y. Zhang, J. Fang, J. Wang, L. Zhao, Y. Zhang, The effects of angular orientation and ultraviolet aging on ETFE wire flame spread, Fire and Materials, 43 (2019) 393-400.

[7]J. Wang, J. Fang, L. Zhao, J. Guan, Y. Zhang, J. Sun, L. Hu, Sooting tendencies of propane jet diffusion flame under crossflow, Fuel, 245 (2019) 247-252.

[8]H. Wan, Z. Gao, J. Ji, J. Fang, Y. Zhang, Experimental study on horizontal gas temperature distribution of two propane diffusion flames impinging on an unconfined ceiling, International Journal of Thermal Sciences, 136 (2019) 1-8.

[9]R. Tu, X. Ma, Y. Zeng, X.J. Zhou, L. He, T.Y. Fang, J. Fang, Coupling effects of pressure and inclination on downward flame spread over flexible polyurethane foam board, Building and Environment, 164 (2019).

[10]J. Fang, S. Zheng, J. Wang, K. Wang, H.R. Shah, J. Wang, An analysis of heat feedback effects of different height embedded plates on promotion of pool fire burning using a variable B number, International Journal of Thermal Sciences, 145 (2019).

[11]J. Fang, Y. Zhang, X.Y. Huang, Y. Xue, J.W. Wang, S.W. Zhao, X.Z. He, L.Y. Zhao, Dripping and Fire Extinction Limits of Thin Wire: Effect of Pressure and Oxygen, Combustion Science and Technology, (2019) 1-16.

[12]L.-y. Zhao, J. Fang, X.-z. He, J.-w. Wang, S.-q. Tao, Y.-m. Zhang, An analysis of width effects on flame spread in conjunction with concurrent forced flow using a variable B-number, Combustion and Flame, 194 (2018) 334-342.

[13]K. Wang, J. Fang, J. Wang, S. Zheng, L. Zhao, J. Guan, Y. Zhang, A Mixture Fraction-Based Model and Axial Thermal Positions for Buoyancy/Momentum-Controlled Jet Diffusion Flames, Combustion Science and Technology, 192 (2018) 62-77.

[14]J. Wang, J. Fang, J. Guan, Y. Zhang, J. Sun, Effect of crossflow on the air entrainment of propane jet diffusion flames and a modified Froude number, Fuel, 233 (2018) 454-460.

[15]J. Ji, Q. Tong, L.Z.L. Wang, C.C. Lin, C. Zhang, Z. Gao, J. Fang, Application of the EnKF method for real-time forecasting of smoke movement during tunnel fires, Advances in Engineering Software, 115 (2018) 398-412.

[16]J. Fang, S. Zhao, J. Wang, Y. Xue, X. He, Y. Zhang, Sub-atmospheric bursting ignition of fluorinated ethylene propylene wire insulation, Fire Safety Journal, 100 (2018) 45-50.

[17]J. Fang, J. Wang, R. Tu, R. Shang, Y.-m. Zhang, J.-j. Wang, Optical thickness of emissivity for pool fire radiation, International Journal of Thermal Sciences, 124 (2018) 338-343.

[18]J. Fang, Y.-R. Meng, J.-W. Wang, L.-Y. Zhao, X.-Z. He, J. Ji, Y.-M. Zhang, Experimental, numerical and theoretical analyses of the ignition of thermally thick PMMA by periodic irradiation, Combustion and Flame, 197 (2018) 41-48.

[19]J. Fang, X.-z. He, K.-y. Li, J.-w. Wang, Y.-m. Zhang, Transition condition and control mechanism of subatmospheric flame spread rate over horizontal thin paper sample, Combustion and Flame, 188 (2018) 90-93.

[20]J.W. Wang, J. Fang, S.B. Lin, J.F. Guan, Y.M. Zhang, J.J. Wang, Tilt angle of turbulent jet diffusion flame in crossflow and a global correlation with momentum flux ratio, Proceedings of the Combustion Institute, 36 (2017) 2979-2986.

[21]J.W. Wang, J. Fang, Y. Zeng, Y.M. Zhang, J.J. Wang, Flame shape of buoyant jet diffusion flames at sub-atmospheric pressures, in: J. Chao, N.A. Liu, V. Molkov, P. Sunderland, F. Tamanini, J. Torero (eds.) Proceedings of the Eighth International Seminar on Fire and Explosion Hazards (ISFEH8), USTC Press, Hefei, 2016, pp. 643-649.

[22]J.W. Wang, J. Fang, J.F. Guan, Y. Zeng, Y.M. Zhang, Flame volume and radiant fraction of jet diffusion methane flame at sub-atmospheric pressures, Fuel, 167 (2016) 82-88.

[23]R. Tu, Y. Zeng, J. Fang, Y. Zhang, Low air pressure effects on burning rates of ethanol and n-heptane pool fires under various feedback mechanisms of heat, Applied Thermal Engineering, 99 (2016) 545-549.

[24]J.F. Guan, J. Fang, Y. Xue, J.W. Wang, J.J. Wang, Y.M. Zhang, Morphology and concentration of smoke from fluorinated ethylene propylene wire insulation in microgravity under forced airflow, Journal of Hazardous Materials, 320 (2016) 602-611.

[25]J. Fang, J.W. Wang, J.F. Guan, Y.M. Zhang, J.J. Wang, Momentum- and buoyancy-driven laminar methane diffusion flame shapes and radiation characteristics at sub-atmospheric pressures, Fuel, 163 (2016) 295-303.

[26]J. Fang, C. Jiang, J.W. Wang, J.F. Guan, Y.M. Zhang, J.J. Wang, Oscillation frequency of buoyant diffusion flame in cross-wind, Fuel, 184 (2016) 856-863.

[27]D. Zhang, J. Fang, J.F. Guan, J.W. Wang, Y. Zeng, J.J. Wang, Y.M. Zhang, Laminar jet methane/air diffusion flame shapes and radiation of low air velocity coflow in microgravity, Fuel, 130 (2014) 25-33.

[28]J. Fang, R. Shang, R. Tu, J.X. YI, Y.M. Zhang, Flame image characters of small-scale pool fire at low air pressure plateau, in:  15th International Conference on Automatic Fire Detection, Duisburg, 2014.

[29]D. Zhang, J. Fang, J.F. Guan, J.J. Wang, Y. Zhang, Optimal Parameter of Flame Detection for Outdoor Fire under Transverse Airflow and Illumination Environments, Procedia Engineering, 62 (2013) 916-923.

[30]Y. Zeng, J. Fang, J.W. Wang, J. Li, R. Tu, Y.M. Zhang, Momentum-dominated Methane Jet Flame at Sub-atmospheric Pressure, Procedia Engineering, 62 (2013) 924-931.

[31]R. Tu, J. Fang, Y.M. Zhang, J. Zhang, Y. Zeng, Effects of low air pressure on radiation-controlled rectangular ethanol and n-heptane pool fires, Proceedings of the Combustion Institute, 34 (2013) 2591-2598.

[32]J.F. Guan, J. Fang, D. Zhang, J.J. Wang, Y.M. Zhang, Experiment Study of Oil Tank Fire Characteristics Dependent on the Opening of Tank Top, Procedia Engineering, 62 (2013) 932-939.

[33]Y. Zeng, J. Fang, R. Tu, J. Wang, Y. Zhang, Study on burning characteristics of small-scale ethanol pool fire in closed and open space under low air pressure, in:  ASME 2011 International Mechanical Engineering Congress and Exposition, American Society of Mechanical Engineers, 2011, pp. 1423-1430.

[34]J. Fang, R. Tu, J.F. Guan, J.J. Wang, Y.M. Zhang, Influence of low air pressure on combustion characteristics and flame pulsation frequency of pool fires, Fuel, 90 (2011) 2760-2766.

[35]C.Y. Yu, J. Fang, J.J. Wang, Y.M. Zhang, Video Fire Smoke Detection Using Motion and Color Features, Fire Technology, 46 (2009) 651-663.

[36]J. Fang, J.J. Wang, R. Tu, Y.M. Zhang, X.M. Shu, An experimental evaluation about multiple fire detectors in a high large volume space, in:  14th International Conference on Automatic Fire Detection, Duisburg,Germany, 2009.

[37]J. Fang, C.Y. Yu, R. Tu, L.F. Qiao, Y.M. Zhang, J.J. Wang, The influence of low atmospheric pressure on carbon monoxide of n-heptane pool fires, Journal of Hazardous Materials, 154 (2008) 476-483.

[38]J. Fang, H.Y. Yuan, Experimental measurements, integral modeling and smoke detection of early fire in thermally stratified environments, Fire Safety Journal, 42 (2007) 11-24.

[39]J. Fang, J. Jie, Y. Hong-Yong, Z. Yong-Ming, Early fire smoke movements and detection in high large volume spaces, Building and Environment, 41 (2006) 1482-1493.

[40]J. Fang, J. Ji, H.-Y. Yuan, Y.-M. Zhang, G.-F. Su, Experimental and Numerical Study of Smoke Plumes in Stable Thermally Stratified Environments, Journal of Fire Sciences, 24 (2006) 177-193.

[41]J. Fang, X. Shu, H. Yuan, X. Zheng, Self-preserving size distribution of fire soot fractal coagulation in flaming combustion, Journal of Fire Sciences, 22 (2004) 53-68.