九州体育

师(shi)资队伍

段强领


个(ge)人履历

九州(zhou)体育安全科(ke)学(xue)与工程(cheng)博(bo)士(shi)(2016)

九州体育博士后 (2016-2018)

九州体育特任副研(yan)究(jiu)员 (2018-2020)

九州体(ti)育副教授(shou) (2020至今)

 

研究方向

氢(qing)能开发利用中的火灾安全

锂离子电池(chi)火灾动(dong)力(li)学(xue)及消防对(dui)策

火灾爆炸事故预测与(yu)防控方法

 

主讲课程

课(ke)程名称: 能源火灾安全理(li)论及(ji)方法学(xue)

(课程(cheng)编号: SE15230.01;学(xue)时(shi): 60;学分(fen): 3

 

个人获(huo)奖

中国公路(lu)学(xue)会科学(xue)技术(shu)奖  一等奖(2018

中国消防协会科技创新(xin)奖  一等(deng)奖(2018

 

学位/职称

工学博士

九州体育副研究(jiu)员

硕士生导师

  

办公室(shi)电(dian)话(hua)

(+86)551 63606191

E-mail: duanql@fun-genius.com


学术任职:

国(guo)际火灾安全科学学会(IAFSS)会员(2016-)

国际燃(ran)烧(shao)学会会员(2017-)

中国化工学会(hui)会(hui)员(2019-

中国(guo)能源研究(jiu)会会员(2019-

 

科研项目

锂浆料电池储能系统火灾危险性(xing)评(ping)估研究:

国(guo)家重点研(yan)发计划项目子课题(ti),主持,执行(xing)期(qi): 2019.12-2024.11

高压氢泄漏过程(cheng)中激(ji)波诱导自燃(ran)发生的内在机理与(yu)预(yu)测模型研究(jiu):

国家(jia)自(zi)然科学基金青年项目,主持(chi),执行期: 2018.1-2020.12

管道内障(zhang)碍物对高压氢气泄(xie)漏自燃的影(ying)响及其机理研究:

中国博士后科学(xue)基金特别资助项目,主持,执行期: 2017.6-2018.04

管道(dao)几(ji)何结构对高压氢气泄漏(lou)自燃的影(ying)响机制研究:

中(zhong)国(guo)博(bo)士(shi)后科学基金(jin)项目,主(zhu)持(chi),执行期: 2016.11-2018.09

区域级(ji)化(hua)工园(yuan)区应急保(bao)障资源(yuan)规划优(you)化(hua)配置与调(diao)度技术(shu)研究:

十三五国(guo)家(jia)重点研发计划项目子课题,研究骨干,执行期: 2016.06-2019.12

受限(xian)空(kong)间内氢/空(kong)气预(yu)混火焰(yan)与(yu)压(ya)力波(bo)相互作用的规(gui)律与(yu)机制研(yan)究(jiu):

国家(jia)自然科学基金青年项目(mu),研究骨干(gan),执行(xing)期: 2015.01-2017.12

/空气预混(hun)火焰传(chuan)播和突(tu)变(bian)的动力学机制及其抑制方法(fa)研究:

国(guo)家自然(ran)科学(xue)基(ji)金面(mian)上项(xiang)目,研究骨干,执行期: 2014.01-2017.12

 

代表性论著

[1] Cao H, Duan Q*, Chai H, Li X, Sun J*. Experimental study of the effect of typical halides on pyrolysis of ammonium nitrate using model reconstruction. Journal of Hazardous Materials. 2020; 384: 121297.

[2] Gong L, Li Z, Jin K, Gao Y, Duan Q*, Zhang Y, Sun J*. Numerical study on the mechanism of spontaneous ignition of high-pressure hydrogen during its sudden release into a tube. Safety Science, 2020, 129: 104807.

[3] Chai H, Duan Q*, Cao H, Li M, Sun J*. Effects of nitrogen content on pyrolysis behavior of nitrocellulose. Fuel. 2020; 264: 116853.

[4] Zeng Q, Duan Q*, Li P, Zhu H, Sun D, Sun J*. An experimental study of the effect of 2.5% methane addition on self-ignition and flame propagation during high-pressure hydrogen release through a tube. International Journal of Hydrogen Energy. 2019; 45(4): 3381-90.

[5] Duan Q, Xiao H, Gong L, Li P, Zeng Q, Gao W, Sun J*. Experimental study of shock wave propagation and its influence on the spontaneous ignition during high-pressure hydrogen release through a tube. International Journal of Hydrogen Energy. 2019; 44:22598-22607.

[6] Chai H, Duan Q*, Jiang L, Gong L*, Chen H, Sun J. Theoretical and experimental study on the effect of nitrogen content on the thermal characteristics of nitrocellulose under low heating rates. Cellulose. 2019; 26:763-776.

[7] Chai H, Duan Q*, Jiang L, Sun J*. Effect of inorganic additive flame retardant on fire hazard of polyurethane exterior insulation material. Journal of Thermal Analysis and Calorimetry. 2019; 135: 2857-2868.

[8] Gong L, Duan Q*, Liu J, Li M, Jin K, Sun J*. Effect of burst disk parameters on the release of high-pressure hydrogen. Fuel. 2019; 235: 485-494.

[9] Gong L, Duan Q*, Liu J, Li M, Jin K, Sun J*. Experimental investigation on effects of CO2 additions on spontaneous ignition of high-pressure hydrogen during its sudden release into a tube. International Journal of Hydrogen Energy. 2019; 44: 7041-7048.

[10] Gong L, Duan Q*, Sun J*, Molkov V. Similitude analysis and critical conditions for spontaneous ignition of hydrogen release into the atmosphere through a tube. Fuel. 2019; 245: 413-419.

[11] Li P, Duan Q*, Gong L, Jin K, Chen J, Sun J*. Effects of obstacles inside the tube on the shock wave propagation and spontaneous ignition of high-pressure hydrogen. Fuel. 2019; 236: 1586-1594.

[12] Li P, Duan Q*, Zeng Q, Jin K, Chen J, Sun J*. Experimental study of spontaneous ignition induced by sudden hydrogen release through tubes with different shaped cross-sections. International Journal of Hydrogen Energy. 2019; 44: 23821-23831.

[13] Duan Q, Xiao H, Gong L, Jin K, Gao W, Chai H, Sun J*. Experimental study on spontaneous ignition and subsequent flame development caused by high-pressure hydrogen release: Coupled effects of tube dimensions and burst pressure. Fire Safety Journal. 2018; 97: 44-53.

[14] Gong L, Duan Q*, Liu J, Li M, Li P, Jin K, Sun J*. Spontaneous ignition of high-pressure hydrogen during its sudden release into hydrogen/air mixtures. International Journal of Hydrogen Energy. 2018; 43: 23558-23567.

[15] Duan Q, Zhang F, Xiong T, Wang Q, Xiao H, Wang Q, Xiao H, Gao W, Gong L, Jin K, Sun J*. Experimental study of spontaneous ignition and non-premixed turbulent combustion behavior following pressurized hydrogen release through a tube with local enlargement. Journal of Loss Prevention in the Process Industries. 2017; 49: 814-821.

[16] Gong L, Duan Q*, Sun Q, Jin K, Sun J*. Effects of the geometry of downstream pipes with different angles on the shock ignition of high-pressure hydrogen during its sudden expansion. International Journal of Hydrogen Energy. 2017; 42: 8382-8391.

[17] Duan Q, Xiao H, Gao W, Gong L, Wang Q, Sun J. Experimental study on spontaneous ignition and flame propagation of high-pressure hydrogen release via a tube into air. Fuel. 2016;181: 811-819.

[18] Duan Q, Xiao H, Gao W, Gong L, Sun J. Experimental investigation of spontaneous ignition and flame propagation at pressurized hydrogen release through tubes with varying cross-section. Journal of Hazardous Materials. 2016; 320: 18-26.

[19] Duan, Q, Xiao, H, Gao, W, Shen, X, Wang, Q, Sun, J*, 2015, Experimental investigation on shock waves generated by pressurized gas release through a tube, Journal of Loss Prevention in the Process Industries. 36: 39-44.

[20] Duan, Q, Xiao, H, Gao, W, Wang, Q., Shen, X., Jiang, L, Sun, J*, 2015, An experimental study on shock waves and spontaneous ignition produced by pressurized hydrogen release through a tube into atmosphere, International Journal of Hydrogen Energy. 40(25): 8281-8289.


 


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