职称：副教授

电话：13697338231

邮箱：vera53@whut.edu.cn

研究方向：新能源安全、工程安全

个人简介

李萍，女，湖北孝感人，2019年毕业于中国科学技术大学火灾科学国家重点实验室业，获工学博士学位。现任武汉理工大学安全科学与应急管理学院副教授，硕士生导师。

学术兼职及学术交流：

受邀担任SCI国际期刊Sustainability编委，International Journal of Hydrogen Energy、fuel、Process Safety and Environmental Protection等知名期刊审稿人。组织举办第二届国际氢安全科学与工程会议、第十一届火灾科学与消防工程国际研讨会、第三届全国工业安全与应急研讨会、第二届燃烧科学技术与能源利用安全研讨会。参加在俄罗斯圣彼得堡举办的the 9th International Seminar on Fire and Explosion Hazards (ISFEH2019) 并作专题报告。

主讲课程

[1] 本科生课程：建设工程力学基础，安全检测与监测，灾害防治理论与技术，建设施工安全

[2] 研究生课程：灾害学

主持科研项目

[1] 国家自然科学基金青年项目，2024-2026年，30万，主持；

[2] 湖北省交通运输厅科技项目，2024-2026，15万，主持；

[3] 国网安徽电科院2023年变电站（换流站）消防系统（材料）评估检测技术服务,2024-2025,67万，主持；

[4] 砂石矿山“数字化”开采技术研发,2024-2025,180万，主持；

[5] 中央高校自主创新基金：高压氢气室内泄漏致灾演化机理研究，2022-2023，主持；

[6] 雷公尖矿区建筑石料用灰岩矿三维地质模型构建技术服务，2021-2022，主持。

 

发表论文情况

[1] He Song, Zhang Xiaoqian, Wu Xiya, Li Ping*, Xu Lei. Theoretical study of heat transfer model of silica aerogel based on the porous structure of secondary particles. Applied Thermal Engineering. 2024;238.

[2] He Song, Wu Xiya, Zhang Xiaoqian, Sun Junwei, Tian Fuliang, Guo Saiping, Du Haipeng, Li Ping*, Huang Yajun. Preparation and properties of thermal insulation coating based on silica aerogel. Energy and Buildings. 2023;298.

[3] He Song, Li Zhiqi, Ma Yuansheng, Liu Xinyu, Jin Xin, He Chunhua, Li Ping*, Huang Dongmei. Thermal decomposition of hydrophobic silica aerogels: kinetics and reaction mechanism. Journal of thermal analysis and calorimetry. 2023;148(24):13941-57.

[4] He Song, Sun Junwei, Jin Xin, Chen Qilin, Wu Xiya, Tian Fuliang, Zhang Xiaoqian, Li Ping*, Sheng Hongliang. Adsorption enhancement of Congo red dye from wastewater based on edamame shell originated activated carbon by the cations: Experimental and theoretical studies. Diamond and related materials. 2023;136:109930.

[5] Liu Jiajia, Yu Danyang, Li Ping*, Sun Xuxu, Chen Xianfeng. Characteristics of Explosion Hazards in Methane-Air Mixtures Diluted by Hydrogen. Energies. 2023; 16(18).

[6] Ping Li, Qian Zeng, Qiangling Duan*, Xianfeng Chen, Jinhua Sun. Effects of obstacles inside the tube on initial self-ignition of high-pressure hydrogen release through a tube. Fuel, 2023(339) 127354.

[7] Ping Li, Qian Zeng, Qiangling Duan*, Jinhua Sun*. Visualization of spontaneous ignition and flame behavior in tubes with and without obstacles during the high-pressure hydrogen release. Process Safety and Environmental Protection. 2021(153):354-362.

[8] Ping Li, Qiangling Duan*, Kaiqiang Jin, Qian Zeng, Jinhua Sun*. Experimental Study on Shock Waves, Spontaneous Ignition, and Flame Propagation Produced by Pressurized Hydrogen Release through Tubes with Varying Obstacle Location. Fuel. 2021(290)120093.

[9] Chuyuan Huang, Bihe Yuan *, Hongming Zhang, Qi Zhao, Ping Li *, Xianfeng Chen*, et al. Investigation on thermokinetic suppression of ammonium polyphosphate on sucrose dust deflagration: Based on flame propagation, thermal decomposition and residue analysis. Journal of Hazardous Materials. 2020: (403) 123653.

[10] Ping Li, Qiangling Duan*, Liang Gong, Kaiqiang Jin, Jiayan Chen, Jinhua Sun*. Effects of obstacles inside the tube on the shock wave propagation and spontaneous ignition of high-pressure hydrogen. Fuel. 2019: (236) 1586-94.

[11] Chuanju Liu, Daguo Wang, Zhixiu Wang, Bo Ke, Ping Li*, Songtao Yu. Dynamic splitting tensile of granite under freeze-thaw weathering. Soil Dynamics and Earthquake Engineering. 2021: (140) 106411.

[12] Bihe Yuan, Yuanyuan Zhan, Shang Sheng, Ping Li*, Huidong Zhao, Yunlong He. Exploration on the influence mechanism of heteroatom doped graphene on thermal oxidative stability and decomposition of polypropylene. Materials Today Communications. 2020: (25) 101446.

[13] Ping Li, Qiangling Duan*, Qian Zeng, Kaiqiang Jin, Jiayan Chen, Jinhua Sun*. 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.

[14] Ping Li, Bo Ke*, Jian Zhang*, Xianfeng Chen. Numerical Investigation of the Chemical Effect and Inhibition Effect Improvement of C3H2F3Br (2-BTP) Using the Perfectly Stirred Reactor Model. Energies. 2018:(11) 2670.