王利刚
姓名:王利刚
职称:教授
职务:固体氧化物电池技术团队带头人
院系:能源电力创新研究院
研究方向:
固体氧化物电池技术基础与应用基础研究
过程系统工程方法与应用
联系方式:
电话:
邮箱:ligang.wang@ncepu.edu.cn
地址:主楼D区1006
个人简介及主要荣誉称号:
王利刚,男,教授,华北电力大学固体氧化物电池技术团队带头人。2016年毕业于柏林工业大学,获工学博士学位。主要开展固体氧化物电池材料-电池-电堆-系统等多层面的基础与应用研究,主持、参与12项旨在提升欧盟固体氧化物电池产业领导力的欧盟第七框架及地平线2020项目,其中主持项目/课题6次,以课题负责人参与的欧盟ECo项目被评为欧盟燃料电池与氢能联合行动组研究进展成功案例,被提名为最佳案例。他系统地评估了多种电制燃料与电-燃料双向转化技术,原创提出了与生物质气化结合的三模式电网平衡电厂,为固体氧化物电池技术大型化发展提供了新方向;研究了甲烷电热催化合成反应机理与固定床反应器设计和调控,设计示范了 3 千瓦高温电制氢与甲烷系统,设计了电动氢能汽车一体化续航站供能系统,具有丰富的产业与技术研发经验。已发表SCI论文47篇,被引超过1260次,累计8次应邀在欧洲著名机构与会议做专题报告,受邀任2020欧洲燃料电池论坛系统分会主席,受邀任Frontiers in Energy Research客座编辑与评论编辑。
教学与人才培养情况:
1.教学课程:
无
2.学生培养(含合作指导)
在读博士:Philippe Aubin(瑞士洛桑联邦理工大学),刘桦(丹麦科技大学),张雨檬,马帅,李承周
毕业博士:张汉飞(意大利比萨大学),Megha Rao(丹麦科技大学),Gabriele Loreti(意大利图西亚大学),李永毅,孙杨,李晓恩,姚尔人(西安交通大学),付鹏,黄圣伟
在读硕士:曲椿煜,袁春宇,王卓,杜智宇,胡自坤
毕业硕士:Phillip Pietsch(德国达姆斯塔特大学)
3.学生获得荣誉
无
主要科研项目情况:
(1) 欧盟委员会,Horizon 2020,826161,WASTE2GRIDS: Converting waste to offer flexible grid balancing services with highly-integrated efficient solid-oxide plants,2019-01至2020-12,53万欧元,已结题,主持
(2) 欧盟委员会,Horizon 2020,731224,BALANCE: Increasing penetration of renewable power alternative fuels and grid flexibility by cross-vector electrochemical processes,2016-12至2019-11,285万欧元,已结题,课题主持
(3) 欧盟委员会,Horizon 2020,699892,ECo: Efficient Co-Electrolyser for Efficient Renewable Energy Storage,2016-05至2019-04,250万欧元,已结题,课题主持
(4) 欧盟委员会,Horizon 2020,826234,Waste2Watts: Unlocking unused bio-WASTE resources with low cost cleaning and Thermal integration with Solid oxide fuel cells,2019-01至2020-12,168万欧元,已结题,课题主持
(5) 欧盟委员会,Horizon 2020,815284,BLAZE: Biomass Low cost Advanced Zero Emission small-to-medium scale integrated gasifier-fuel cell combined heat and power plant,2019-03至2022-02,425万欧元,在研,课题主持
(6) 欧盟委员会,Horizon 2020,SEP-210667815,PROMETEO: Hydrogen PROduction by MEans of solar heat and power in high TEmperature Solid Oxide Electrolysers,2021-01至2024-07,250万欧元,在研,参加
(7) 欧盟委员会,Horizon 2020,815284,Nautilus: Nautical Integrated Hybrid Energy System for Long-haul Cruise Ships,2020-07至2024-07,789万欧元,在研,参加
(8) 欧盟委员会,Horizon 2020,731125,PENTAGON: Unlocking European grid local flexibility trough augmented energy conversion capabilities at district-level,2016-12至2019-11,443万欧元,已结题,参加
(9) 欧盟委员会,Horizon 2020,735692,CH2P: Cogeneration of Hydrogen and Power using solid oxide based system fed by methane rich gas,2017-02至2020-07,686万欧元,已结题,参加
(10) 欧盟委员会,Horizon 2020,691797,STORE&GO: Innovative large-scale energy STOragE technologies AND Power-to-Gas concepts after Optimisation,2016-03至2020-02,2800万欧元,已结题,参加
(11) 欧盟委员会,欧盟第七框架,621173,SOPHIA: Solar integrated pressurized high temperature electrolysis,2014-04至2017-09,330万欧元,已结题,参加
主要获奖情况:
无
代表性论著:
2021年文章
[1] Zhang, Y., Wang, N., Tong, X., Wang*, L., Yang, Y. Reversible solid-oxide cell stack based power-to-x-to-power systems: Economic potential evaluated via plant capital-cost target. (2021) Applied Energy, 290: 116700. (SCI)
[2] Zhang, H., Wang*, L., Van herle, J., Maréchal, F., Desideri, U. Techno-economic comparison of 100% renewable urea production processes. (2021) Applied Energy. 116401. (SCI)
[3] Carbone, C., Gracceva, F., Pierro, N., Motola, V., Zong, Y., You, S., Pérez-Fortes, M., Wang, L., Agostini, A.. Potential Deployment of Reversible Solid-Oxide Cell Systems to Valorise Organic Waste, Balance the Power Grid and Produce Renewable Methane: A Case Study in the Southern Italian Peninsula. (2021) Frontiers in Energy Research, 618229. (SCI)
[4] Zhang, Y., Wang, N., Li, C., Pérez-Fortes, Duan, L., Van herle, J., Maréchal, F., Lin, T., Wang*, L., Yang, Y.. Triple-mode grid-balancing plants via biomass gasification and reversible solid-oxide cell stack: Economic feasibility evaluation via plant capitalcost target, Frontiers in Energy Research, (2021) Accepted. (SCI)
2020年文章
[5] Wang*, L., Zhang, Y., Pérez-Fortes, M., Aubin, P., Lin, T., Yang, Y., Maréchal, F., Van herle, F. Reversible solid-oxide cell stack based power-to-x-to-power systems: Comparison of thermodynamic performance. (2020) Applied Energy, 115330. (SCI)
[6] Zhang, H., Wang*, L., Van herle, J., Maréchal, F., Desideri, U. Techno-economic evaluation of biomass-to-fuels with solid-oxide electrolyzer. (2020) Applied Energy, 115113. (SCI)
[7] Sadok, R., Benveniste, G., Wang, L., Clavreul, J., Brunot, A., Cren, J., Jegoux, M., Hagen, A. Life Cycle Assessment of Power-to-Gas Applications via Co-Electrolysis of CO2 and H2O. (2019) Journal of Physics: Energy, 2(2):024006 (13pp). https://doi.org/10.1088/2515-7655/ab72dd. (SCI)
[8] Sun†, S., Wang†,*, L., Xu, C., Maréchal, F., Van herle, J., Yang, Y. Enhancing operational flexibility of coal-fired power plants via power-to-hydrogen. (2020) Applied Energy, 114608.https://doi.org/10.1016/j.apenergy.2020.114608 (SCI)
[9] Li, Y., Zhang, G., Wang, L., Yang, Y. Part-load performance analysis of a combined cycle with intermediate recuperated gas turbine. (2020) Energy Conversion and Management, 112346. (SCI)
[10] Zhang, H., Wang*, L., Pérez-Fortes, M., Van herle, J., Maréchal, F., & Desideri, U. Techno-economic optimization of biomass-to-methanol with solid-oxide electrolyzer. (2020) Applied Energy, 11407. (SCI)
[11] Zhang, H., Wang*, L., Van herle, J., Maréchal, F., Desideri, U. Techno-economic comparison of green ammonia production processes. (2020) Applied Energy, 114135. (SCI)
[12] Wang*, L., Zhang, Y., Li, C., Pérez-Fortes, M., Lin, T.-E., Maréchal, F., Van herle, J., Yang, Y. Triple-mode grid-balancing plants via biomass gasification and reversible solid-oxide cell stack: Concept and thermodynamic performance. (2020) Applied Energy, 115987. (SCI) (SCI)
[13] Wang*, L., Fu, P., Yang, Z., Lin, T.-E., Yang, Y., Tsatsaronis, G. Advanced Exergoeconomic Evaluation of Large-Scale Coal-Fired Power Plant. (2020) Journal of Energy Engineering, 146:04019032.1-.11. (SCI)
[14] Ma, S., Lin, M., Lin, T.-E., Lan, T., Wang*, L. Fuel cell-battery hybrid systems for mobility and off-grid applications: A review. (2020) Renewable and Sustainable Energy Reviews, 135. (SCI)
[15] Lin, Y.-T., Darvishi, S., Preet, A., Huang, T.-Y., Lin, S.-H., Girault HH, Wang, L., Lin, T.. A Review: Electrochemical Biosensors for Oral Cancer. (2020) Chemosensors, 8:54. (SCI)
[16] Lin, Y.-T., Preet, A., Chiu, Y.-P., Yip, Girault, H., Darvishi, S., Wang, L., Lin, T.. Technology. Communication - Scanning Electrochemical Microscopy Analysis of Interleukin-6 in Oral Cancer. (2020) ECS Journal of Solid State Science and Technology, 9:115028. (SCI)
[17] Lin, Z., Hsu, W.-S., Preet, A., Yeh, L.-H., Lin, Chen, Y., Pao, Y., Lin, S., Lee, S., Fan, J., Wang, L., Chiu, Y., Yip, B., Lin, T.. Ingestible polysaccharide battery coupled with a self-charging nanogenerator for controllable disinfection system. Nano Energy, (2021) 105440. (SCI)
2019年文章
[18] Zhang, H., Wang*, L., Maréchal, F., & Desideri*, U. Techno-economic comparison of green ammonia production processes. (2019). Applied Energy, 114135. (SCI)
[19] Wang*, L., Fu, P., Yang, Z., Lin, T.-E., Yang, Y., Tsatsaronis, G. Advanced exergoeconomic evaluation of large-scale coal-fired power plants. (2019) Journal of Energy Engineering, 146(1): 04019032. (SCI)
[20] Zhang, Y., Wang*, L., Wang, N., Duan, L., Zong, Y., You, S., ... & Yang, Y. Balancing wind-power fluctuation via onsite storage under uncertainty: Power-to-hydrogen-to-power versus lithium battery. (2019). Renewable and Sustainable Energy Reviews, 116, 109465. (SCI)
[21] Zhang, H., Wang*, L., Maréchal, F., & Desideri*, U. Techno-Economic Optimization of CO2-to-Methanol with Solid-Oxide Electrolyzer. (2019). Energies, 12(19), 3742. (SCI)
[22] Wang*, L., Chen, M., Küngas, R., Lin, T.-E., Dielthm, S., Maréchal, F.; Van herle, J. Power-to-fuel systems via solid-oxide electrolyzer: operating window and techno-economics. (2019) Renewable and Sustainable Energy Reviews, 110, 174-187. (SCI)
[23] Wang*, L., Rao, M., Diethelm, S., Lin, T.-E., Zhang, H., Hagen, A., Marechal, M., Van herle, J. Power-to-methane via co-electrolysis of H2O and CO2: The effects of pressurized operation and internal methanation. (2019) Applied Energy, 250, 1432-1445. (SCI)
[24] Jeanmonod, G., Wang*, L., Pérez-Fortes, M., Diethelm, S., Maréchal, F., Van herle, J. Trade-off designs of power-to-methane systems via solid-oxide electrolyzerand the application to biogas upgrading. (2019) Applied Energy, 247, 572-581. (SCI)
[25] Pérez-Fortes, M., Mian, A., Santhanam, S., Wang, L., Diethelm, S., Varkaraki, E., Mirabelli, I., Makkus, R., Schoon, R., Maréchal, F., Van herle, J., Design of a pilot SOFC system for the combined production of hydrogen and electricity under refueling station requirements. (2019) Fuel Cell, DOI: 10.1002/fuce.201800200. (SCI)
[26] Zhao†, K., Wang†, L., Moioli, E., Calizzi, M., Züttel, A. Identifying Reaction Species by Evolutionary Fitting and Kinetic Analysis: an Example of CO2 Hydrogenation in DRIFTS. (2019) Journal of Physical Chemistry C, 123 (14), 8785–8792. DOI: 10.1021/acs.jpcc.8b11105. (SCI)
[27] Venkataraman, V., Pérez-Fortes, M., Wang, L., Hajimolana, Y., Boigues, C., Agostini, A., Van herle, J., Aravind, PV. Solid oxide reversible cell systems for energy and chemical applications. (2019) Journal of Energy Storage, 24, 100782. (SCI)
[28] Wang*, L., Yang, Z., Sharma, S., Mian, A., Lin, T., Tsatsaronis, G., Marechal, F. Yang, Y. A review of evaluation, optimization and synthesis of energy systems: Methodology and applications to thermal power plants. (2019) Energies 12 (1), 73. (SCI)
2018年文章
[29] Wang*, L., Düll, J., Marechal, F., Van herle, J. Trade-off designs and comparative exergy evaluation of solid-oxide electrolyzer based power-to-methane plants. (2018) International Journal of Hydrogen Energy, 44 (19), 9529-43. https://doi.org/10.1016/j.ijhydene.2018.11.151. (SCI)
[30] Wang*, L., Pérez-Fortes, M., Madi, H., Diethelm, S., Van herle, J., Maréchal, F. Optimal design of solid-oxide electrolyzer based power-to-methane systems: A comprehensive comparison between steam electrolysis and co-electrolysis. (2018) Applied Energy, 211, 1060-1079. DOI: 10.1016/j.apenergy.2017.11.050 (SCI)
[31] Li, X., Wang, N., Wang*, L., Yang, Y., Maréchal, F. Identification of optimal operating strategy of direct air-cooling condenser for Rankine cycle based power plants. (2018) Applied Energy, 209, 153-166. DOI: 10.1016/j.apenergy.2017.10.081 (SCI)
[32] Zhao, K., Wang, L., Calizzia, M., Moioli, E., Züttel, A. In situ control of the adsorption species in CO2 hydrogenation: determination of intermediates and byproducts. (2018) Journal of Physical Chemistry C, 122 (36), 20888-20893. DOI: 10.1021/acs.jpcc.8b06508 (SCI)
[33] Baldi, F., Wang, L., Pérez-Fortes, M. and Marechal, F. A cogeneration system based on solid oxide and proton exchange membrane fuel cells with hybrid storage for off-grid applications. (2018) Frontiers in Energy Research, 6, p.139. (SCI)
[34] Huang, S., Li, C., Tan, T., Fu, P., Wang*, L. and Yang, Y. Comparative Evaluation of Integrated Waste Heat Utilization Systems for Coal-Fired Power Plants Based on In-Depth Boiler-Turbine Integration and Organic Rankine Cycle. (2018) Entropy, 20(2), p.89. DOI:10.3390/e20020089 (SCI)
[35] Li, Y., Zhang, G., Bai, Z., Song, X., Wang, L., Yang, Y. Backpressure adjustable gas turbine combined cycle: A method to improve part-load efficiency. (2018) Energy Conversion and Management, 174, 739-754. DOI: 10.1016/j.enconman.2018.07.077 (SCI)
[36] Yang, Y.; Li, X.; Yang, Z.; Wei, Q.; Wang, N.; Wang*, L. The Application of Cyber Physical System for Thermal Power Plants: Data-Driven Modeling. (2018) Energies, 11, 690. DOI:10.3390/en11040690 (SCI)
2018年及以前的著作可参阅网络。
团队与实验室:
课题组围绕固体氧化物电池技术开始组建一支国际化、年轻化、强交叉的研发团队,目前已有一名讲师(丹麦科技大学童晓峰博士),将继续从海外引进两位博士,已招收两位入选“华北电力大学新讲师博士后”的博后人才,将于2021年建成“教授-副教授-讲师-博后研究梯队”。硬件方面,研究组正在建设固体氧化物电池材料与电池制备高标准洁净实验室,正在建设华北电力大学-三峡集团氢能联合实验室,并将重点参与华北电力大学国家储能产教融合创新平台建设。