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李曦

职称:教授

电话:027-87557273

邮箱:lixi@hust.edu.cn 或 lixi_wh@126.com

研究方向:燃料电池系统集成与控制,新能源管控系统,多轴联动智能装备控制

个人简介

个人简介

李曦,男,1977年生,博士,教授,博士生导师。200511月毕业于上海交通大学自动化系获工学博士学位;2010年被聘为博士生导师,获华中科技大学学术新人奖,同年入选教育部新世纪优秀人才支持计划;20114月赴美国密歇根大学(安娜堡)访问研究一年;2012年晋升为华中科技大学pbb63365挎包教授,同年被聘为华中学者。

长期从事燃料电池集成与控制等领域的科研和教学。以第一作者或通讯作者身份发表SCI论文三十余篇,含A类论文二十余篇;授权中国发明专利十余项,获软件著作权2项。

参与制定了固体氧化物燃料电池相关国家标准。

 

主要研究领域

燃料电池系统集成与控制,新能源管控系统,多轴联动智能装备控制

 

主持承担的主要科研项目:

1)国家自然科学基金项目(61573162);

2)国家科技支撑计划课题(2015BAI01B08);

3)湖北省科技支撑计划(2015BEC059);

4)国家自然科学基金项目(60804031);

5)教育部新世纪优秀人才支持计划(NCET-10-0411);

(6)湖北省自然科学基金杰出青年基金项目(2016CFA037)

7)武汉市青年科技晨光计划(201150431120);

8)武钢重点技改项目(校20121609);

9)山东省科技重大专项(新兴产业)项目(2015ZDXX0602A02);

10)广东省教育部产学研结合项目(2012A090300009);

11)“十二.五”国家科技部“863”主题项目(固体氧化物燃料电池领域)子课题(2011AA050702);

12)“十一.五”国家科技部“863”目标导向类项目(固体氧化物燃料电池领域)子课题(2006AA05Z148)。

 

参与的主要科研项目:

1)“十.五”国家科技部“863”重点项目(熔融碳酸盐燃料电池领域)(2003AA517020);

2)“十.五”国防预研项目-总装备部(质子交换膜燃料电池领域)xxxx)。

 

近年来第一或通讯作者的部分论文(*表示通讯作者):

[1]  Huan Cheng,Xi Li*, et al; Control-Oriented Modeling Analysis and Optimization of Planar Solid Oxide Fuel Cell System.
International Journal of Hydrogen Energy; 10.1016/j.ijhydene.2016.08.213. (SCI,IF=3.205);
[2]  Xiaowei Fu,Yuhan Xiang, Xi Li*, et al; A Novel Ni/YSZ Anode Image Segmentation Method for Solid Oxide Fuel Cell Electrodes Microstructure.
Fuel Cells 2016; Accepted. (SCI,IF=1.769);
[3]  Hongliang Cao, Xi Li*, Thermal management oriented multivariable robust control of a kW scale solid oxide fuel cell stand-alone system.
 IEEE Transactions on Energy Conversion, 2016; 31(2): 596 - 605.(SCI, IF = 2.596)
[4] Xiaowei Fu,Yuhan Xiang, Xi Li*, et al;  Solid oxide fuel cell anode image segmentation based on a novel quantum-inspired fuzzy clustering.
Journal of Power Sources 2015; 300(1): 57-68. (SCI,IF=6.333);
[5] Lin Zhang, Xi Li*, et al; Control strategy for power management, efficiency-optimization and operating-safety of a 5-kW solid oxide fuel cell system.
Electrochimica Acta2015; 177(20):237-249. (SCI,IF=4.803);
[6] Jianhua Jiang, Xi Li*, et al; Modeling and Model-based Analysis of SOFC Thermal-Electrical Management System with an Air Bypass Valve.
Electrochimica Acta2015; 177(20):250-263. (SCI,IF=4.803);
[7] Lin Zhang, Xi Li*, et al;  Dynamic modeling and analysis of a 5-kW solid oxide fuel cell system from the perspectives of cooperative control of thermal safety and high efficiency.
International Journal of Hydrogen Energy 2015; 40(1): 456-476. (SCI,IF=3.205);
[8] Huan Cheng,Xi Li*, et al;  A Nonlinear Sliding Mode Observer for the Estimation of Temperature Distribution in a Planar Solid Oxide Fuel Cell.
International Journal of Hydrogen Energy 2015; 40(1): 593-606. (SCI,IF=3.205);
[9] Jianhua Jiang, Xi Li*, et al; Control-oriented dynamic optimization of steam reformer with an improved optimization algorithm.
International Journal of Hydrogen Energy 2013; 38(26): 11288-11302. (SCI,IF=3.205);
[10] Jianhua Jiang, Xi Li*, et al; Steady-state analysis of 5kW SOFC system with novel configuration.
Electrochemical Society Transactions 2013; 57(1): 437-442.
[11] Cao HongLiang, Xi Li*, Deng ZhongHua, et al; Thermal management oriented steady state analysis and optimization of a kW scale solid oxide fuel cell stand-alone system for maximum system efficiency.
International Journal of Hydrogen Energy 2013; 35(4): 1749-1758. (SCI,IF=3.205);
[12] Jiang Jianhua, Li Xi*,Deng ZhongHua, et al; Thermal management of an independent steam reformer for a solid oxide fuel cell with constrained generalized predictive control.
International Journal of Hydrogen Energy, 2012; 37(17): 12317-12331. (SCI,IF=3.205);
[13] Li Xi*, Deng ZhongHua, Qin Yi, et al;Parameter optimization of thermal-model-oriented control law for PEM fuel cell stack via novel genetic algorithm.
Energy Conversion and Management, 2011; 52(11): 3290-3330. (SCI,IF=4.801);
[14] Li Xi*, Deng ZhongHua, Qin Yi, et al; Novel variable structure control for the temperature of PEM fuel cell stack based on the dynamic thermal affine model.
Energy Conversion and Management, 2011; 52(11): 3265-3274. (SCI,IF=4.801);
[15] Cao HongLiang, Li Xi*, Deng ZhongHua, et al; Dynamic modeling and experimental validation for the electrical coupling in a 5-cell solid oxide fuel cell stack in the perspective of thermal coupling.
International Journal of Hydrogen Energy 2011; 36(7): 4409-4418. (SCI,IF=3.205);
[16] Yang Jie, Li Xi*, et al; Parameter optimization for tubular solid oxide fuel cell stack based on the dynamic model and an improved genetic algorithm.
International Journal of Hydrogen Energy 2011; 36(10): 6160-6174. (SCI,IF=3.205);
[17] Cao HongLiang, Deng ZhongHua, Li Xi*, et al; Dynamic modeling of electrical characteristics of solid oxide fuel cells using fractional derivatives.
International Journal of Hydrogen Energy 2010; 35(4): 1749-1758. (SCI,IF=3.205);
[18] Deng ZhongHua, Cao HongLiang, Li Xi*, et al;  Generalized predictive control for fractional order dynamic model of solid oxide fuel cell output power.
Journal of Power Sources 2010;195(24): 8097-8103. (SCI,IF=6.333);
[19] Yang Jie, Li Xi*, et al; Predictive control of solid oxide fuel cell based on an improved Takagi-Sugeno fuzzy model.
Journal of Power Sources 2009; 193(2): 699-705. (SCI,IF=6.333);
[20] Yang Jie, Li Xi*, et al; Control-oriented thermal management of solid oxide fuel cells based on a modified Takagi-Sugeno fuzzy model.
 Journal of Power Sources 2009; 188(2): 475-482. (SCI,IF=6.333);
近年来授权的部分发明专利(均为第一完成人):
[1] 一种固体氧化物燃料电池系统,ZL 201510684054.9
[2] 一种确定固体氧化物燃料电池系统参数的方法,ZL 201410185972.2
[3] 一种固体氧化物燃料电池电堆温度分布估计方法,ZL 201410184688.3
[4] 一种确定热轧带钢层流冷却温度的方法,ZL 201410110758.0
[5] 一种人工气候室控制方法,ZL 201410269592.7
[6] 一种固体氧化物燃料电池系统及热电协同控制方法,ZL 201310104574.9
[7] 一种面向海洋浮标的固体氧化物燃料电池能量管理系统,ZL 201310552132.0
[8] 一种层流冷却温度场的建模方法及系统,ZL 201310479981.8
[9] 一种层流冷却温度控制方法及系统,ZL 201310600841.1
[10] 用于固体氧化物燃料电池系统的控制器,ZL 201210546452.0
获批计算机软件著作权(均为第一完成人):
[1] 层流冷却过程模型预测控制仿真软件,2014SR046475
[2] 层流冷却生产过程预测仿真软件,2013SR107758
主要的奖励与荣誉:
(1)校“青年五四奖章”(2015);
(2)校优秀班主任(2014)。