九州体育

师资队伍

方俊

 

个人履历

九州体育安全技术及工程博(bo)士(shi)(2004)
九州体育博士后 (2004-2006)
九州(zhou)体育副研究员(2007-至今(jin))
教育部(bu)新世(shi)纪优(you)秀人才(cai)支(zhi)持计划 (2012)
  University of California, San Diego
访问学者(zhe)(2014-2015

  

研究(jiu)方向

特(te)殊条件下着火、燃烧、火蔓延火灾动(dong)力学(xue)机理与防(fang)控技术

  

主讲课程(cheng)

火灾控制技术(shu)基础

课程(cheng)编号: 232085;学时: 40/60;学分: 3

现代安(an)全监(jian)测技术

(课程编号: SE1520701;学时(shi): 60;学分: 3)

  

个人获奖(jiang)

安徽(hui)省教学成果一等奖(1/5)(2020

高等(deng)学校科(ke)(ke)学研究(jiu)优秀成果(guo)奖(jiang)(jiang)(自(zi)然科(ke)(ke)学奖(jiang)(jiang)二等(deng))(4/6)(2017

教育(yu)部(bu)新世纪优秀人(ren)才(cai)计(ji)划(hua)(2012

王宽(kuan)诚育(yu)才奖二等奖(2013

安徽省自然科学(xue)优秀(xiu)论文(wen)一等奖(2013

中国科(ke)大(da)首届(jie)青年教(jiao)师教(jiao)学基本功竞赛(sai)二(er)等奖(jiang)

2012

  http://wp.fun-genius.com/_upload/article/images/0c/f4/bf98cc1846088e0596e35ba16c49/W020111028389490235043.jpg

学(xue)位(wei)/职称

工(gong)学博(bo)士

九(jiu)州体育副(fu)研究员

博士生(sheng)导师(shi)

  

办公(gong)室电话(hua)

(+86)551 63607119

E-mail: fangjun@fun-genius.com

 

科研项目

燃烧拖曳与辐射影响下压缩空气泡沫的铺展运动与抑制火焰机理:
国家自然科学基金委面上项目,主持,执行期: 2021.01-2024.12

微重力(li)强迫对(dui)流条件下(xia)高温导(dao)线过载着火(huo)与(yu)火(huo)蔓延机制(zhi):

国家自然科学基金委(wei)面(mian)上项(xiang)目,主持,执行期: 2016.01-2019.12

微重力强迫对流条件下火灾与(yu)(yu)非(fei)火灾颗粒(li)群光散射(she)规律(lv)与(yu)(yu)反演识别(bie)方法:

国家自然(ran)科学基(ji)金(jin)项目,主持,执行期: 2011.1-2013

西藏低压缺氧环境对火灾烟气探测的(de)影响机理:

国家自然(ran)科学基(ji)金委(wei)青年基(ji)金项(xiang)目,主持(chi),执行期: 2008.01-2010.12

教(jiao)育(yu)部新(xin)世纪优秀人才支(zhi)持计划项目(mu):

教育(yu)部人才项目(mu),主持,2013.01-2015.12
环境风作(zuo)用下(xia)固体火灾复杂扩散燃烧行为(wei)的基础问题研究:

国(guo)家自然科学(xue)基(ji)金委重点项(xiang)目,重要骨干,2017.01-2021.12
城市地下空间复(fu)杂边界条件下火(huo)灾动(dong)力学(xue)行为(wei)研究:

国家自然科学基(ji)金委专项(xiang)基(ji)金项(xiang)目(mu),重要骨干(gan),2014.1-2018.12
化工(gong)园区大型油气火(huo)灾灭火(huo)技术及(ji)装备研(yan)究(jiu):

科技(ji)部重点(dian)研发计划课题(ti)子课题(ti),主持,2016.07-2019.12
基于(yu)物联(lian)网(wang)技(ji)术(shu)的(de)交(jiao)通(tong)枢(shu)纽综(zong)合体火灾防控关键技(ji)术(shu)研(yan)究:

科技部十(shi)二五科技支(zhi)撑课(ke)题子(zi)课(ke)题,主持,2011.10-2013.12

 

学术任职

国际(ji)火灾安全科(ke)学学会终(zhong)身会员
国(guo)际(ji)燃(ran)烧学会(hui)会(hui)员(yuan)
清(qing)华大学(xue)合肥(fei)公共安(an)全研究院消防安(an)全科技专家(jia)
工(gong)程与材料学(xue)部(bu)、信息(xi)科(ke)学(xue)部(bu)国家自然科(ke)学(xue)基金委通讯评(ping)议专家
141516届国际火灾(zai)探测大会(hui)分会(hui)主席
17届(jie)国(guo)际火灾探测(ce)/灭火(huo)大(da)会Technical Program Committee委员

 

代表性论著

编著:

吴龙标,方(fang)俊,谢(xie)启源.《火灾(zai)探测与信息处理(li)》,北京: 化学工业出版社,2006

廖光煊(xuan),方俊.《燃(ran)烧技术(shu)手册(ce)》第23火(huo)灾(zai)探测与清洁高效灭火(huo)技术,北京: 化(hua)学(xue)工业出版社,2008

 

发明专利:

一(yi)种热分层(ceng)环(huan)境下烟气(qi)羽流运动模拟实验装(zhuang)置,ZL200810246203.32010-06-23

电导线(xian)阴燃(ran)烟颗粒采集设备,ZL201110178867.22013-8-7

一种强迫对流环境下扩散火焰实验装置,ZL201110211328.42013-07-07

 

特邀报告(gao):

浮力/动量主控下(xia)的燃烧与火焰(yan)形态(tai)及辐射行为(主(zhu)题(ti)特(te)邀报告), 2017年(nian)(nian)中国工(gong)程热(re)物理学(xue)会燃烧(shao)学(xue)学(xue)术年(nian)(nian)会, 中(zhong)国(guo)南京(jing), 2017-10-132017-10-15

 

代表性论文:

[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.

 

 

 

 

 


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