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王长安  
研究领域(方向)

固体燃料高效清洁利用(包含能源安全技术)

污染物协同控制与固废处理

CO2捕集技术(富氧燃烧技术,空气直接碳捕集技术DAC等)

新型锅炉技术与积灰结渣控制

新型储能技术(铝基金属燃料储能,氨燃料储能,热储能等)

CFD数值模拟与分子反应动力学模拟

个人及工作简历

2022/01~至今     :西安交通大学能源与动力工程学院,教授、博士生导师

2019/01~至今     :能动学院热能工程系副主任(分管研究生招生等)、党支部组织委员,院教代会代表、教学督导、评估专家

2013/10~2021/12:西安交通大学能源与动力工程学院,讲师、副教授(硕导)、副教授(博导)

2013/10~2016/12:西安交通大学动力工程及工程热物理专业,博士后

2014/07~2015/07:美国宾州州立大学地球与矿物科学学院,访问学者

2010/09~2013/09:西安交通大学热能工程系,工学博士

2009/09~2010/07:西安交通大学热能工程系,工学硕士(保送,硕博连读)

2007/09~2009/07:西安交通大学国际经济与贸易专业,经济学学士(双学位)

2005/09~2009/07:西安交通大学能源动力系统及自动化专业,工学学士

科研项目

1. 富油煤原位热解能质输运定向调控机理与关键技术研究,陕西省重点研发项目,2024.1~,负责人.

2. 旋风富氧燃烧中高碱煤燃料氮转化机理与熔渣流动传热特性研究,国家自然科学基金,2022~,负责人.

3. 多级孔吸脱附耦合过渡金属催化剂及VOCs高效净化系统,中科院创新研究院-榆林学院联合基金,2021~,负责人.

4. 燃煤耦合气化残炭 O2/CO2 燃烧基础科学问题研究,省部共建煤炭高效利用与绿色化工国家重点实验室开放课题特别资助,2020~,负责人.

5. 半焦制民用清洁型煤关键技术研究,中国博士后基金特别资助, 2019~,负责人.

6. 燃煤耦合超低挥发分碳基燃料O2/CO2燃烧NOx控制机理研究,陕西省自然科学基础研究计划面上项目,2019~,负责人.

7. 煤气化废水高温热处理特性与有机污染物转化行为研究,污染控制与资源化研究国家重点实验室开放课题,2019~,负责人.

8. 生物质焦分子建模及其气化特性动力学模拟研究, 可再生能源电力技术湖南省重点实验室开放基金,2018~,负责人.

9. 煤气化废水有机污染物热降解特性研究,黑龙江省博士后资助经费项目,2018~,负责人.

10 超低挥发分碳基燃料低NOx燃烧技术,国家重点研发计划课题, 2017.7~,负责人.

11. 高碱金属煤O2/CO2燃烧的积灰结渣机理研究,国家自然科学基金, 2016~,负责人.

12. 复杂气氛下准东煤燃烧碱金属凝结与沾污机理研究,中国博士后基金,2014~,负责人.

学术及科研成果、专利、论文

2022-2023年发表论文

[1]Wang, C.; Wang, C.a.*; Luo, M.; Dai, L.; Wang, P.; Che, D. Simulation study on fuel-nitrogen migration characteristics of oxy-fuel co-combustion of various ultra-low volatile coal-based solid fuels. Process Safety and Environmental Protection, 2023, 173: 812-822.

[2]Zhao, L.; Wang, C.a.*; Luo, M.; Zhao, P.; Che, D. CO2 gasification behavior of chars from high-alkali fuels and effects of Na, K, Ca, and Fe species via synthetic coal char. Journal of Thermal Analysis and Calorimetry, 2023, 148(13):6423-6437.

[3]Wang, C.; Wang, C.a.*; Luo, M.; Zhao, L.; Wang, P.; Hou, Y.; Zhao, P. Che, D. Co-gasification behaviors of various coal-based solid fuels blends at initial stage of oxy-fuel co-combustion. Energy, 2023, 271:127111.

[4]Lyu, Q.; Wang, C.a.*; Zhao, P.; Zhou, L.; Hou, Y.; Chen, M.; Du, Y.; Che, D. Numerical study on coal/sludge co-combustion characteristics in a 330 MW wall-fired boiler. Journal of Energy Engineering, 2023, 149(5): 04023025.

[5]Wang, C.a.*; Chen, M.; Zhou, L.; Hou, Y.; Zhao, P.; Che, D. Correlations of chemical properties of sludge in China: A comparison study between municipal sludge and industrial sludge. Journal of the Energy Institute, 2023, 108:101202.

[6]Wang, C.a.; Chen, M.; Zhao, P.; Zhou, L.; Hou, Y.; Zhang, J.; Lyu, Q.*; Che, D. Investigation on co-combustion characteristics and NOx emissions of coal and municipal sludge in a tangentially fired boiler. Fuel, 2023, 340:127608.

[7]Gao, X.; Wang, C.a.*; Bai, WG; Hou, Y.; Che, D. Review of research on aluminum fuels as energy carriers for controllable hydrogen production and power generation. Energies 2023, 16(1):436.

[8]Gao, X.; Wang, C.a.*; Bai, W.*; Hou, Y.; Che, D. Experimental investigation of the catalyst-free reaction characteristics of micron aluminum powder with water at low and medium temperatures. Journal of Energy Storage, 2023, 59:106543.

[9]Wang, L.; Wang, C.a.*; Bai W.; Jin, L.; Yang, X.; Che, D. Split-flow layouts of supercritical CO2 Brayton cycle for coal-fired power plant considering the flue gas residual heat utilization. Asia-Pacific Journal of Chemical Engineering, 2023, 18(2):e2874.

[10]Wang, P.; Bai, B.*; Wang, C.a.*; Du, Y.; Wang, C.; Che, D. Experimental and kinetics study of NO heterogeneous reduction on semi-coke and its chars: Effects of high-temperature rapid pyrolysis and atmosphere. Energy 2023, 264:126300.

[11]Wang, C.a.*; Hou, Y.; Feng, Q.; Wang, C.; Gao, X.; Che, D. Numerical simulation of co-firing ultra-low volatile carbon based-fuels with bituminous coal under oxy-fuel conditions. Fuel 2023, 332(1): 126087.

[12]Wang, C.a.*; Mao, Q.; Wang, C.; Zhao, L.; Ma, L.; Duan, Z.; Che, D. Oxyfuel cofiring characteristics of biomass with ultralow volatile carbon-based fuels. Journal of Energy Engineering 2023, 149(1):04022045.

[13]Wang, C.;Wang, C.a.*; Zhao, L.; Luo, M.; Feng, Q.; Mao, Q.; Zhang, J.; Che, D. Oxy-fuel co-combustion characteristics and kinetics of various ultra-low volatile coal-based solid waste blends. Journal of Thermal Analysis and Calorimetry 2022, 147:15017–15032.

[14]Wang, C.a.*; Luo, M.; Tang, G.; Jin, L.; Zhao, L.; Che, D. Staged co-gasification characteristics of pyrolyzed semi-coke and antibiotic filter residue under oxy-fuel condition. Asia-Pacific Journal of Chemical Engineering, 2022 17(5): e2812.

[15]Ma, L.; Mao, Q.;Wang, C.a.*; Duan, Z.; Liu, J.; Yang, F.; Wang, Z.; Che, D. Investigation of pyrolysis and mild oxidation characteristics of tar-rich coal via thermogravimetric experiments. ACS Omega 2022, 7(29): 25613-25624.

[16]Wang, C.a.*; Zhao, L.; Sun, R.; Zhou, L.; Jin, L.; Che, D. Experimental study on NO emission and ash deposition during oxy-fuel combustion of high-alkali coal under oxygen-staged conditions. Energy 2022, 251: 123875.

[17]Wang, C.; Wang, C.a.*; Tang, G.; Zhang, J.; Gao, X.; Che, D. Co-combustion behaviors and NO formation characteristics of semi-coke and antibiotic filter residue under oxy-fuel condition. Fuel 2022, 319: 123779.

[18]Wang, C.; Wang, C.a.*; Feng, Q.; Mao, Q.; Gao, X.; Du, Y.; Li G.; Che, D. Experimental evaluation on NOx formation and burnout characteristics of oxy-fuel co-combustion of ultra-low volatile carbon- based solid fuels and bituminous coal. Energy 2022, 248: 123578.

[19]Wang, C.a.*; Gao, X.; Tang, G.; Zhao, L.; Mao, Q.; Du, Y.; Che, D. Thermogravimetric study on oxy-fuel co-combustion characteristics of semi-coke and antibiotic filter residue. Journal of Thermal Analysis and Calorimetry 2022, 147(17): 9505-9522.

[20]Lyu, Q.; Wang, C.a.*; Liu, X.; Che D. Numerical study on the homogeneous reactions of mercury in a 600 MW coal-fired utility boiler. Energies 2022, 15(2):446.

[21]Wang, C.a.; Yuan, M.; Li, H.; Zhao, L.; Han, T.; Zhu, C.; Che, D*. Ash fusion behaviors and physico-chemical characteristics of high-alkali coals under oxy-fuel condition. International Journal of Coal Preparation and Utilization 2022, 42 (2): 113-123.

 

2022-2023年授权发明专利

[1]马丽,李惠彦辰,王长安,段中会,王振东,毛崎森,曹虎生,车得福. 一种富油煤自生热与电加热耦合的原位热解系统. 发明,ZL 2022 1 0423053.9,2023-09-08.

[2]车得福,陈美静,王长安,毛崎森,侯育杰,宁星,薛香玉,邓磊. 一种富油煤地下原位气化-热解-余热利用一体化系统. 发明,ZL 2022 1 0783948.3,2023-06-27.

[3]王长安,赵林,侯育杰,毛崎森,陈美静,宁星,薛香玉,车得福. 一种富油煤原位热解多相产物分离系统. 发明,ZL202211165569.4,2023-06-23.

[4]车得福,陈美静,王长安,侯育杰,毛崎森,宁星,薛香玉,邓磊. 一种富油煤温和氧化自生热与水蒸气加热耦合的原位热解系统. 发明,ZL202211122730.X,2023-06-20.

[5]杨甫,毛崎森,段中会,王长安,马丽,宁星,付德亮,车得福. 一种水蒸气注热原位热解富油煤的系统及方法. 发明,ZL 2022 1 0423064.7,2023-06-09.

[6]段中会,陈美静,王长安,马丽,侯育杰,杨甫,赵林,王振东,车得福 一种富油煤地下直接热解提油系统. 发明,ZL202210785034.0,2023-06-13.

[7]王长安,高昕玥,白文刚,罗茂芸,侯育杰,车得福. 一种基于铝燃料储能的能源转化系统及方法. 发明,ZL202210509756.3,2023-06-09.

[8]车得福,宁星,王长安,邓磊,朱涛,黄笑乐,毛崎森,薛香玉. 模拟地下有机质岩原位热解提油气的试验系统及工作方法. 发明,ZL202210278337.3,2023-05-16.

[9]王长安,高昕玥,白文刚,侯育杰,罗茂芸,车得福. 一种基于铝-水反应的氢气-蒸汽联合循环发电系统及方法. 发明,ZL202210510679.3,2023-01-17.

[10]王长安,李惠彦辰,傅泳清,高志豪,毛崎森,车得福. 一种实现粉状与纤维状物料连续混合给料的装置. 发明,ZL202111102922.X,2023-01-03.

[11]张锦萍,陈磊,刘银河,王长安,车得福. 一种光伏-富氧燃烧耦合发电系统及方法,发明,ZL202111452662.9,2022-09-16..

[12]王长安,王超伟,高昕玥,王鹏乾,车得福. 一种气化飞灰低NOx燃烧熔融处理系统和方法,发明,ZL202110315024.6,2022-10-25.

[13]车得福,王彦成,王长安,高昕玥,刘虎,薛景文. 一种气化飞灰分级资源化利用系统及方法,发明,ZL202110744280.7,2022-08-29.

[14]王长安,王超伟,金丽艳,王鹏乾,杜勇博,车得福. 一种动力循环低NOx掺烧兰炭的系统和方法,发明,ZL202010718054.7,2022-08-16.

[15]王长安,王超伟,高昕玥,王鹏乾,车得福. 一种煤化工多联产耦合半焦低NOx燃烧的系统和方法,发明,ZL202110316148.6,2022-06-07.

[16]王长安,毛崎森,周磊,赵林,车得福. 一种富油煤地下热解热能循环利用系统,发明,ZL202110876085.X,2022-06-07.

[17]王长安,毛崎森,周磊,赵林,车得福. 一种富油煤原位热解与碳捕集耦合的系统,发明,ZL202110874316.3,2022-05-20.

[18]王长安,金丽艳,王超伟,冯芹芹,赵林,车得福. 一种耦合富氧燃烧的超临界CO2循环冷热电联产系统,发明,ZL202011018901.5,2022-04-22.

联系方式
电子邮箱:changanwang@mail.xjtu.edu.cn
联系电话:029-82668703
联系地址:能源馆420
更新日期:2024-03-19