盛敏,讲席教授,博导,ylzzcom永利总站检测网址反应安全中心主任(筹)(https://rcsc.ecust.edu.cn/)
Min Sheng,Chair Professor,Ph.D. Supervisor,Chair of Reactive Chemical Safety Center @ ECUST (https://rcsc.ecust.edu.cn/en/)
美国注册专业工程师,国家级重点人才,上海市海外领军人才。曾就职于美国陶氏化学总部,陶氏杜邦农化公司,担任全球反应安全专家,实验室主任和技术主管等职位,管理过陶氏化学全球总部(美国密西根)的反应危险品安全实验室和杜邦公司全球唯一的爆炸危害实验室,其中陶氏总部的实验室曾发明了目前电池热安全和化工反应安全风险评估中广泛应用的绝热加速热量仪(ARC)。
Registered Professional Engineer (P.E.) in Michigan State, USA. Had led the Dow Reactive Chemicals (RC) lab in Midland, Michigan (Dow global headquarter) and the DuPont explosion hazard lab (the only reactivity hazard lab in DuPont globally). This Dow RC lab invented the accelerating rate calorimeter (ARC) in the 1979, which is still one of the most popular tools for reactivity hazard evaluation of both chemical process and Lithium battery.
联系方式:
地址:上海市梅陇路130号ylzzcom永利总站检测网址实验8楼333室
Email:minsheng@ecust.edu.cn
Contact info:
Add: Meilong Road 130, East China University of Science & Technology, 200237, Shanghai
Email: minsheng@ecust.edu.cn
研究方向:
化工反应性安全(实验室安全,化学反应安全,化工过程本质安全等),电池热安全(包括电池材料热稳定性,电池单体热安全等),各类热量仪的工业应用,反应动力学及实际工况仿真
Research interest:
Reactivity hazard evaluation (e.g., Lab safety, Chemical process safety), Battery thermal safety (e.g., Thermal stability of battery materials, Battery cell thermal hazard), Calorimetry application, Reaction kinetics, and Process simulations.
教育背景:
2007-2011:工学博士,美国奥本大学,工程学院,化学工程系
2000-2007:工学学士和硕士,天津大学,化工学院,制药工程系
Education:
2007-2011:Ph.D. degree, Chemical Engineer, Auburn University, AL, USA
2000-2007:Master and Bachelor’s degree: Pharmaceutical Engineer, Tianjin University, China
工作经历:
2022-至今:yl23455永利公司
2018-2022:陶氏杜邦农化公司(2019更名为科迪华,世界500强),反应危险品安全部技术经理
2012-2018:美国陶氏化学,反应危险品安全部全球反应安全专家,陶氏化学全球总部反应危险品安全实验室主任
2007:中国天辰化学工程公司,工艺工程部初级工程师
Professional experiences:
2022-till now: Professor, School of Resources and Environmental Engineering, East China University of Science & Technology
2018-2022: Technical Leader, Reactive Chemicals (RC) group, DowDuPont Ag Division (Corteva)
2012-2018: RC SME (subject matter experts), Reactive Chemicals (RC) group, The Dow Chemical Company, led the RC testing lab in Midland, Michigan (Dow global headquarter)
2007: Process Engineer, China TianChen Engineering Corporation
学术兼职:
美国材料与试验协会危险化学品组(ASTM E27)委员会委员
AICHE下CCPS/LPS委员会委员
AICHE反应泄压阀设计会(DIERS)委员会委员
2021年中国化学品安全协会外聘专家组组长
美国普渡大学安全中心的科学技术顾问
美国化学会ACS的化学健康与安全杂志的编委会委员
Committee and Broad Memberships
Committee member of ASTM E27 Hazard Potential of Chemicals
Committee member of AICHE CCPS/LPS
Committee member of AICHE DIERS
Scientific Advisor of Purdue University P2SAC safety center
Editorial Advisory Board member of ACS Chemical Health & Safety
主要承担的科研项目:
(1)一手创立陶氏杜邦农化公司的反应危险品安全部,建立两个全新测试中心,培训过3位反应安全专家和6位实验分析员,2017.8-2022.3
(2)创立联合国新运输法规要求的“单体自加速聚合温度” (SAPT)的恒温热量仪测试的新方法,2015.1-2017.12,主持
(3)正在修订ASTM E537(差分扫描量热仪DSC的热安全测试标准),ASTM E1981(绝热加速量热仪ARC的热安全测试标准)和ASTM E680(爆炸品压敏测试标准),2019.10-目前,主持
Main Projects:
(1) Established the RC group for DowDuPont Ag Division, built two new RC testing labs, and trained three RC SMEs and six RC analysts, 2017.8-2022.3
(2) Developed a new isothermal calorimetric testing method to determine the monomer Self-Accelerating Polymerization Temperature (SAPT) for a new transportation regulation of The United Nations, led the team from a joint session of several industry consortia committees (Basic Acrylic Monomer Manufacturers, European Basic Acrylate Manufacturers, and Methacrylate Producers Association), 2015.1-2017.12
(3) Leading the update of ASTM E537 (Standard Test Method for The Thermal Stability of Chemicals by Differential Scanning Calorimetry), ASTM E1981 (Standard Guide for Assessing Thermal Stability of Materials by Methods of Accelerating Rate Calorimetry), and ASTM E680 (Standard Test Method for Drop Weight Impact Sensitivity of Solid-Phase Hazardous Materials), From 2019.10 to now.
代表性论文(Representative publications)
吴展华,盛敏,绝热加速量热仪在反应安全风险评估应用中的常见问题,化工进展,2023,42(7),3374-3382,(https://hgjz.cip.com.cn/CN/10.16085/j.issn.1000-6613.2023-0509)
Min Sheng*, Practical Estimation Techniques of Reaction Heat, Org. Process Res. Dev. 2021, 25, 8, 1862–1872
Min Sheng*, Qiang Yang*, Darren Huff, Andrew Schafer, Craig Tucker, Daniel Valco, Thermal Instability and Associated Potential Safety Hazards of Rhodium(I) Precatalyst Complexes with weakly Coordinated Ligands, Org. Process Res. Dev., 2021, 25, 4, 1054–1064.
Min Sheng*, Daniel Valco and Craig Tucker, Heat Loss in ARC Analysis and Thermal Lag for High Self-Heat Rates, Org. Process Res. Dev., 2021, 25, 1, 108-119.
Yang, Qiang*; Sheng, Min; Yongliang Huang; Potential Safety Hazards Associated with Using N,N-Dimethylformamide in Chemical Reactions, Org. Process Res. Dev., 2020, 24, 9, 1586–1601
Qiang Yang*; Min Sheng; et al., Potential Explosion Hazards Associated with the Autocatalytic Thermal Decomposition of Dimethyl Sulfoxide and Its Mixtures, Org. Process Res. Dev., 2020, 24, 6, 916–939.
Min Sheng*, Daniel Valco, Craig Tucker, Elizabeth Cayo, Tyler Lopez, Practical Use of Differential Scanning Calorimetry (DSC) for Thermal Stability Hazard Evaluation, Org. Process Res. Dev., 2019, 23, 10, 2200-2209.
Qiang Yang*; Min Sheng; James Henkelis; et al., Explosion Hazards of NaH in DMSO, DMF and DMAc, Org. Process Res. Dev., 2019, 23(10), 2210-2217
Min Sheng, Florin Dan, et al., Calorimetric Method To Determine Self-Accelerating Polymerization Temperature (SAPT) for Monomer Transportation Regulation: A Heat Balance Approach, Org. Process Res. Dev., 2019, 23 (5), pp 750-761
Min Sheng*, Florin Dan, et al., Calorimetric Method To Determine Self-Accelerating Polymerization Temperature (SAPT) for Monomer Transportation Regulation: Kinetics and Screening Criteria, Org. Process Res. Dev., 2019, 23 (5), pp 737-749
Min Sheng*, D Frurip, D Gorman, Reactive chemical hazards of diazonium salts, Journal of Loss Prevention in the Process Industries, 2015, 38, 114
D. Gorman, J. Farr, R. Bellair, W. Freeman, D. Frurip, A. Hielscher, H. Johnstone, M. Linke, P. Murphy, Min Sheng, K. van Gelder, D. Viveros. Enhanced NOAA chemical reactivity worksheet for determining chemical compatibility, Process Safety Progress, 2014, 33(1), 4–18