基本信息
姓名:徐钱
系所:热科学与能源工程系
职称:副教授
办公地点:机电楼914
邮箱:qianxu@ustb.edu.cn
教育及工作经历
2009.09-2013.06,北京科技大学-土木与环境工程学院,建筑环境与设备工程,学士
2010.03-2013.06,北京科技大学-经济管理学院,信息管理与信息系统,管理学双学位
2017.11-2018.05,英国伯明翰大学-化学工程系储能中心,国家公派联合培养博士
2013.09-2018.06,北京科技大学-能源与环境工程学院,动力工程及工程热物理,博士
2018.06-2020.12,北京科技大学-能源与环境工程学院,教师博士后/讲师,兼任博士研究生辅导员
2020.06-至今,北京科技大学-能源与环境工程学院,特聘副教授、副教授
2023.09-至今,北京科技大学-能源与环境工程学院,教授岗
2010.03-2013.06,北京科技大学-经济管理学院,信息管理与信息系统,管理学双学位
2017.11-2018.05,英国伯明翰大学-化学工程系储能中心,国家公派联合培养博士
2013.09-2018.06,北京科技大学-能源与环境工程学院,动力工程及工程热物理,博士
2018.06-2020.12,北京科技大学-能源与环境工程学院,教师博士后/讲师,兼任博士研究生辅导员
2020.06-至今,北京科技大学-能源与环境工程学院,特聘副教授、副教授
2023.09-至今,北京科技大学-能源与环境工程学院,教授岗
研究领域
时空两域多相流动热质输运调控,应用场景如下:
(1)工业炉窑热工优化、固废资源化与烟气多污染物协同处置;
(2)城市生命线管网多源力学载荷作用安全韧性评估及智能运维;
(3)人体血管血液多尺度耦合动力学建模与智能疾病风险评估;
(4)极端热湿场景主被动多模态调控技术及海陆空天电应用。
(1)工业炉窑热工优化、固废资源化与烟气多污染物协同处置;
(2)城市生命线管网多源力学载荷作用安全韧性评估及智能运维;
(3)人体血管血液多尺度耦合动力学建模与智能疾病风险评估;
(4)极端热湿场景主被动多模态调控技术及海陆空天电应用。
研究生培养
根据研究方向每年招收博士/硕士研究生,课题组提倡积极快乐健康的学习生活氛围,欢迎您的加入!
开设课程
1.《工程流体力学》32学时
2.《暖通工程》32学时
3.《流体机械》32学时
4.《热过程模拟软件实训》32学时
2.《暖通工程》32学时
3.《流体机械》32学时
4.《热过程模拟软件实训》32学时
学术/社会兼职
RARE METALS 青年编委(SCI)
INT J PHOTOENERGY青年编委(SCI)
工程科学学报青年编委(EI)
应用基础与工程科学学报青年编委(EI)
科大讯飞校企合作导师
北京城市副中心绿色发展创新服务平台专家委员
北京能源学会科创部秘书长
北京博士后联谊会副秘书长
北京科技大学博士后联谊会理事长
INT J PHOTOENERGY青年编委(SCI)
工程科学学报青年编委(EI)
应用基础与工程科学学报青年编委(EI)
科大讯飞校企合作导师
北京城市副中心绿色发展创新服务平台专家委员
北京能源学会科创部秘书长
北京博士后联谊会副秘书长
北京科技大学博士后联谊会理事长
代表性论文及著作
方向一:工业炉窑热工优化、固废资源化与烟气多污染物协同处置
[1] Xu Qian, Zou Z, Chen Y, et al. Performance of a novel-type of heat flue in a coke oven based on high-temperature and low-oxygen diffusion combustion technology [J]. Fuel, 2020, 267: 117160. [ESI 高被引论文、TOP期刊、1区、IF: 6.7]
[2] Xu Qian, Shen M, Xie K, et al. Heat and mass transfer mechanism and control strategy of clean low carbon combustion technology in the novel-type coke oven flue with MILD combustion [J]. Fuel, 2022, 320: 124001. [TOP期刊、1区、IF: 6.7]
[3] Shi K, Feng J, Yang G, Xu Qian*, et al. Numerical study of NOx emission reduction by MILD and air staged synergistic combustion in a new type of coke oven flue [J]. International Communications in Heat and Mass Transfer, 2024, 159. [TOP期刊、1区、IF: 6.4]
[4] Fan H, Feng J, Bai W, Nevzat Akkurt, Xu Qian*, et al. A study on the combustion performance and NOx emissions characteristics of a novel U-type radiant tube based on MILD combustion theory [J]. Fuel, 2023,346, [TOP期刊、1区、IF: 6.7]
[5] Xu Qian, Feng J, et al. Influence of the operating parameters and nozzle characteristics on flat double-P radiant tube performance [J]. Applied Thermal Engineering, 2019, 155: 175-184. [TOP期刊、1区、IF: 6.1]
[6] Xu Qian, Feng J, Zhou J, et al. Performance analysis of a novel W-type radiant tube [J]. Applied Thermal Engineering, 2019, 152: 482-489. [TOP期刊、1区、IF: 6.1]
[7] Xu Qian, Feng J, Zhou J, et al. Study of a new type of radiant tube based on the traditional M-type structure [J]. Applied Thermal Engineering, 2019, 150: 849-857. [TOP期刊、1区、IF: 6.1]
[8] Xu Qian, Feng J. Analysis of nozzle gas speed on the performance of the zoned and staged gas-fired radiant tube [J]. Applied Thermal Engineering, 2017, 118: 734-741. [TOP期刊、1区、IF: 6.1]
[9] Xu Qian, Feng J. Analysis of nozzle designs on zoned and staged double P-type gas-fired radiant tube [J]. Applied Thermal Engineering, 2016, 114: 44-50. [TOP期刊、1区、IF: 6.1]
[10] Xu Qian, Shen M, Shi K, et. al. Influence of jet angle on diffusion combustion characteristics and NOx emissions in a self-reflux burner [J]. Case Studies in Thermal Engineering, 2021, 25: 100953. [3区、IF: 6.4]
[11] Xu Qian, Shen M, Shi K, et. al. Effect of the Mixing Structure Parameters of a Self-reflux Burner on Combustion Characteristics and NOx Emission [J]. Journal of Thermal Science, 2021, 30: 1224-1236. [3区、IF: 1.8]
[12] Xu Qian, Nevzat Akkurt, et. al. Effects of Optimized Operating Parameters on Combustion Characteristics and NOx Emissions of a Burner Based on Orthogonal Analysis [J]. Journal of Thermal Science, 2021, 30: 1212-1223. [3区、IF: 1.8]
[13] Xu Qian, Wang K, Feng J, et. al. Performance analysis of a novel Flue Gas Self-Circulated Burner based on the Low-NOx Combustion [J]. Journal of Energy Engineering, 2020, 146(2): 04019041. [4区、IF: 2.0]
[14] 徐钱, 冯俊小, 周闻华. 分级气体成分对燃气辐射管热过程影响的数值模拟及研究[J]. 工程科学学报, 2016, 39(1):96-106. [EI, 北京青年优秀科技论文]
[15] 徐钱, 冯俊小. 基于正交法扁双P型辐射管仿真模拟及结构优化[J]. 工程科学学报, 2017, 39(4) :581-592. [EI, 北京青年优秀科技论文]
[16] 徐钱, 冯俊小, 周闻华, 等. 分区分级双P型辐射管喷口结构位置特性研究[J]. 工程科学学报, 2017, 39(5) :756-761. [EI]
[17] 徐钱, 冯俊小, 周闻华, 等. 分区分级燃气辐射管模型验证及仿真研究[J]. 工程科学学报, 2016, 38(11):1620-1628. [EI]
[18] 徐钱, 冯俊小, 周敬之. 立式镁还原罐还原过程中结构传热特性分析[J]. 化工进展, 2018, 37(2): 459-467. [EI]
方向二:城市生命线管网多源力学载荷作用安全韧性评估及智能运维
[1] Xu Qian, Application and Extension of Numerical Methods in Heating Pipeline (数值方法于供热管道的应用及拓展) [M] .Singapore: Springer Singapore; 北京: 中国科学技术出版社, 2025. ISBN 978-981-96-1119-5.
[2] Xu Qian, Wang K, Zou Z, et. al. A new type of two-supply, one-return, triple pipe-structured heat loss model based on a low temperature district heating system [J]. Energy, 2021, 218: 119569. [ESI 高被引论文、TOP期刊、1区、IF: 9.0]
[3] Zheng Q, Shu Z, Yang G, Xu Qian*, et al. Analysis of the mechanical characteristics and plasticity-hazardous zones development of natural gas pipeline under overload [J]. Tunnelling and underground space technology, 2023, 142: 1-14. [TOP期刊、1区、IF: 6.7]
[4] Wang K, Xie K, Xu Qian*, et. al. Numerical evaluation of the coupled-uncoupled effectiveness of a fluid-solid-thermal multi-field model for a long-distance energy transmission pipeline [J]. Energy, 2022, 251: 123964. [TOP期刊、1区、IF: 9.0]
[5] Xu Qian, Yang G, et al. Dynamic response model and equivalent solution method of large-diameter buried energy transportation pipeline under moving load [J]. Journal of Natural Gas Science and Engineering, 2022, 106: 104724. [TOP期刊、2区、IF: 4.9]
[6] Chen X, Ren L, Zheng Q, Xu Qian*, et al. Heat loss optimization and economic evaluation of a new fourth generation district heating triple pipe system [J]. Applied Thermal Engineering, 2023, 233: 121160. [TOP期刊、1区、IF: 6.1]
[7] Zheng Q, Shu Z, Xu Qian*, et al. A review of advances in mechanical behaviors of the underground energy transmission pipeline network under loads [J]. Gas Science and Engineering, 2023, 117,:205074. [2区、IF: 5.2]
[8] Xu Qian*, Zhong L, Shu M, Yang G, et al. Analysis of the mechanical behavior and prediction of the plastic zone of a large-diameter buried gas pipeline under ground overload [J]. Gas Science and Engineering. 2023, 110. [2区、IF: 5.2]
[9] Xu Qian, Feng J, Liu L, et al. Analysis of mechanical-fluid-thermal performance of heat pipeline system with structural deformation effects [J]. International Journal of Heat and Mass Transfer, 2019,128:12-23. [TOP期刊、1区、IF: 5.0]
[10] Xu Qian, Feng J, Zhang S. Effects of different loads on structure stress of ‘‘L”-type large-diameter pipeline under burying and trench conditions based on fluid–structure–heat coupling [J]. International Journal of Heat and Mass Transfer, 2017, 115:387-397. [TOP期刊、1区、IF: 5.0]
[11] Xu Qian, Feng J, Zhang S. Combined effects of different temperature and pressure loads on the “L”-type large-diameter buried pipeline [J]. International Journal of Heat and Mass Transfer, 2017, 111:953-961 [TOP期刊、1区、IF: 5.0]
[12] Xu Qian, Feng J, Zhang S. Influence of end side displacement load on stress and deformation of ‘‘L”-type large-diameter buried pipe network [J]. Applied Thermal Engineering, 2017, 126: 245-254. [TOP期刊、1区、IF: 6.1]
[13] Xu Qian, Feng J, Zhang S. Effects of different loads on structure stress of “L”-type large-diameter buried pipe network based on fluid–structure-heat coupling [J]. International Communications in Heat and Mass Transfer, 2017, 86: 222-230. [TOP期刊、1区、IF: 6.4]
[14] Xu Q, Feng J-X. Effects of different loads on structure deformation of “L”-type large-diameter buried pipe network based on flow–heat–solid coupling. Heat Transfer- Asian Research. 2017; 46:1327–1341. [EI]
方向三:极端热湿场景主被动多模态调控技术及海陆空天电应用
[1] Xu Qian, Wang K, Feng J, et. al. A comparative investigation on the effect of different nanofluids on the thermal performance of two-phase closed thermosyphon [J]. International Journal of Heat and Mass Transfer, 2020, 149: 119-189. [ESI 高被引论文、TOP期刊、1区、IF: 5.0]
[2] Liu D.H, Xie K, et. al, Xu Qian*. Numerical evaluation of convective heat transfer properties of two dimensional rotating PCM melt in the unilaterally heated rectangular container [J]. Renewable Energy, 2022, 193: 920-940. [TOP期刊、1区、IF: 9.0]
[3] Xu Qian, Yang G, Wang C, Liu Z, Zhang X, et al. Experimental study on the reinforcement of a gravity heat pipe based on a latent thermal functionally fluid [J]. Energy, 2023, 278: 127782. [TOP期刊、1区、IF:9.0]
[4] Xu Qian, Zhu L.D, et al. Heat transfer performance by forced convection of microencapsulated phase change material-latent functional thermal fluid flowing in a mini-channels heat sink [J]. Applied Thermal Engineering, 2022, 216: 119158. [TOP期刊、1区、IF: 6.1]
[5] Xu Qian, Zhu L. D, Pei Y, et al. Heat transfer enhancement performance of microencapsulated phase change materials latent functional thermal fluid in solid/liquid phase transition regions [J]. International Journal of Heat and Mass Transfer, 2023, 214: 124461. [TOP期刊、1区、IF: 5.0]
[6] Xiong Y. X, Yao C. H, Xu Qian*, Ding Y. L, et al. Waste Semicoke Ash Utilized to Fabricate Shape-stable Phase Change Composites for Building Heating and Cooling [J]. Construction and Building Materials, 2022, 361: 129638. [TOP期刊、1区、IF: 7.4]
[7] Xiong Y.X, Song C.Y, Xu Qian*, et. al. Sludge-incinerated ash based shape-stable phase change composites for heavy metal fixation and building thermal energy storage[J]. Process Safety and Environmental Protection, 2022, 126: 346-356. [TOP期刊、1区、IF: 6.9]
[8] Lin L, Yang D, Xu Qian*, et al. Numerical study on melting and heat transfer characteristics of vertical cylindrical PCM with a focus on the solid-liquid interface heat transfer rate [J]. Journal of Energy Storage, 2023, 72: 1-15. [2区、IF:8.9]
[9] Xu Qian, Yang C, Li G, et al. Numerical investigation on enhanced heat transfer performance of latent functional thermal fluid under phase transition and local motion microscale effects [J]. Applied Thermal Engineering, 2024, 257: 124323. [TOP期刊、1区、IF: 6.1]
[10] Zhao Y, Yuan C, Zhang Y, Qian Xu*, et. al. Thermal performance investigation of latent heat-packed bed thermal energy storage system with axial gas injection [J]. Applied Thermal Engineering. 2025, 258: 124781. [TOP期刊、1区、IF: 6.1]
[11] Xiong Y. X, Yang Y, Xu Qian*, et al. Investigation on low-carbon shape-stable phase change composite by steel slag and carbide slag for solar thermal energy storage [J]. Journal of Energy Storage, 2024, 76: 109736. [2区、IF:8.9]
[12] Xiong Y. X, Fan Y, Wu Y, Xu Qian*, et al. Low-carbon shape-stable phase change composite utilizing semi-coke ash for building thermal energy storage [J]. Solar Energy Materials and Solar Cells, 2024, 270: 112823. [2区、IF:6.3]
[13] Xiong Y. X*, Wang W, Ren J, Akkurt Nevzat, Xu Qian*, et al. Carbide slag recycling to fabricate shape-stable phase change composites for thermal energy storage [J]. Journal of Energy Storage, 2023, 60: 106694. [2区、IF: 8.9]
[14] Xiong Y. X, Xiang L, Xu Qian*, et al. Effects of expanded graphite on NaNO3/semi-coke ash shape-stable phase change composites for thermal energy storage [J]. Journal of Energy Storage, 2023, 72: 108648. [2区、IF:8.9]
[15] Xiong Y. X, Li S, Xu Qian*, et al. Effect of ratio of desulfurization gypsum to carbide slag on low-carbon phase change composites for energy storage [J]. Journal of Energy Storage, 2024, 91: 112086. [2区、IF: 8.9]
[16] Xu Qian, Yang Q, Jia S.H, et. al. Experimental study on synergistic enhancement of thermal performance of a closed two-phase thermosyphon by a TiO2 nanofluid doped with Al2O3 [J]. Case Studies in Thermal Engineering, 2022, 36: 102192. [3区、IF: 6.4]
[17] Wang Z, Zhang H, Xu Qian*, et. al. Experimental study on heat transfer properties of gravity heat pipes in single/hybrid nanofluids and inclination angles [J]. Case Studies in Thermal Engineering, 2022, 34: 102064. [3区、IF: 6.4]
[18] Xiong Y. X, Wang H. X, Xu Qian*, Ding Y. L, et al. Insights into the Enhancement Mechanisms of Molten Salt Nanofluids [J]. International Journal of Photoenergy, 2022, 4912922. [4区、IF: 2.1]
方向四:临床医学、机械、化工、土木等学科交叉
[1] Qiang Y, Boyuan Ran, Li M, Xu Qian*, et. al. GO-functionalized MXene towards superior anti-corrosion coating[J]. Journal of Colloid and Interface Science, 2023, 642: 595-603.[ESI高被引论文、TOP期刊、1区、IF: 9.4]
[2] Xiong Y. X, Xu Qian*, et al. Investigation of a sole gas expander for gas pressure regulation and energy recovery [J]. Energy, 2023, 281. [TOP期刊、1区、IF: 9.0]
[3] Xiong Y. X, Tian X, He M, Xu Qian*, et al. Effects of CO2 capture on waste concrete/sodium nitrate form-stable phase change composites for energy storage [J]. Journal of Cleaner Production, 2024, 440: 140896. [TOP期刊、1区、IF: 9.8]
[4] Xiong Y. X, Li S, Ren J, Xu Qian*, et al. Effect of carbon capture on desulfurization gypsum/carbide slag phase-change composites for waste removal and renewable energy storage [J]. Journal of Environmental Chemical Engineering, 2024, 12(3): 112484. [TOP期刊、2区、IF: 7.4]
[5] Bo Z, Chen P, Xu Qian*, et al. Tightly-connected carbon-coated FeS2 hollow sphere-graphene microstructure for ultrafast and stable potassium ion storage [J]. Journal of Energy Storage, 2024, 84: 110984. [2区、IF: 8.9]
[6] Liu, Z. W, Li, Bo Wen, Xu Qian*, et al. Application and Prospects of Ni−Mn-Based Layered Oxide Cathodes for Sodium-Ion Batteries [J]. ACS Applied Energy Materials, 2024, 7: 3502-3522. [2区、IF: 5.5]
[7] Yao X.Q, Qiang Y.J, Xu Qian*, et. al. Renewable low-cost brassica rapa subsp. Extract for protection of Q235 steel in H2SO4 medium: Experimental and modeling studies [J]. Journal of Industrial and Engineering Chemistry, 2022, 114:427-437. [TOP期刊、2区、IF: 5.9]
[8] Lin L, L Feng, Qian Xu*, Y Chen. Anomalous diffusion in comb model subject to a novel distributed order time fractional Cattaneo-Christov flux [J]. Applied Mathematics Letters, 2020, 102:106-116. [TOP期刊、1区、IF: 2.4]
[9] Xu Qian, Liu Y, Feng J, et. al. Synthesis and Characterization of Disodium Hydrogen Phosphate Dodecahydrate-Lauric-Palmitic Acid Used for Indoor Energy Storage Floor Units [J]. Journal of Thermal Science, 2020, 29: 477-485. [3区、IF: 1.8]
[1] Xu Qian, Zou Z, Chen Y, et al. Performance of a novel-type of heat flue in a coke oven based on high-temperature and low-oxygen diffusion combustion technology [J]. Fuel, 2020, 267: 117160. [ESI 高被引论文、TOP期刊、1区、IF: 6.7]
[2] Xu Qian, Shen M, Xie K, et al. Heat and mass transfer mechanism and control strategy of clean low carbon combustion technology in the novel-type coke oven flue with MILD combustion [J]. Fuel, 2022, 320: 124001. [TOP期刊、1区、IF: 6.7]
[3] Shi K, Feng J, Yang G, Xu Qian*, et al. Numerical study of NOx emission reduction by MILD and air staged synergistic combustion in a new type of coke oven flue [J]. International Communications in Heat and Mass Transfer, 2024, 159. [TOP期刊、1区、IF: 6.4]
[4] Fan H, Feng J, Bai W, Nevzat Akkurt, Xu Qian*, et al. A study on the combustion performance and NOx emissions characteristics of a novel U-type radiant tube based on MILD combustion theory [J]. Fuel, 2023,346, [TOP期刊、1区、IF: 6.7]
[5] Xu Qian, Feng J, et al. Influence of the operating parameters and nozzle characteristics on flat double-P radiant tube performance [J]. Applied Thermal Engineering, 2019, 155: 175-184. [TOP期刊、1区、IF: 6.1]
[6] Xu Qian, Feng J, Zhou J, et al. Performance analysis of a novel W-type radiant tube [J]. Applied Thermal Engineering, 2019, 152: 482-489. [TOP期刊、1区、IF: 6.1]
[7] Xu Qian, Feng J, Zhou J, et al. Study of a new type of radiant tube based on the traditional M-type structure [J]. Applied Thermal Engineering, 2019, 150: 849-857. [TOP期刊、1区、IF: 6.1]
[8] Xu Qian, Feng J. Analysis of nozzle gas speed on the performance of the zoned and staged gas-fired radiant tube [J]. Applied Thermal Engineering, 2017, 118: 734-741. [TOP期刊、1区、IF: 6.1]
[9] Xu Qian, Feng J. Analysis of nozzle designs on zoned and staged double P-type gas-fired radiant tube [J]. Applied Thermal Engineering, 2016, 114: 44-50. [TOP期刊、1区、IF: 6.1]
[10] Xu Qian, Shen M, Shi K, et. al. Influence of jet angle on diffusion combustion characteristics and NOx emissions in a self-reflux burner [J]. Case Studies in Thermal Engineering, 2021, 25: 100953. [3区、IF: 6.4]
[11] Xu Qian, Shen M, Shi K, et. al. Effect of the Mixing Structure Parameters of a Self-reflux Burner on Combustion Characteristics and NOx Emission [J]. Journal of Thermal Science, 2021, 30: 1224-1236. [3区、IF: 1.8]
[12] Xu Qian, Nevzat Akkurt, et. al. Effects of Optimized Operating Parameters on Combustion Characteristics and NOx Emissions of a Burner Based on Orthogonal Analysis [J]. Journal of Thermal Science, 2021, 30: 1212-1223. [3区、IF: 1.8]
[13] Xu Qian, Wang K, Feng J, et. al. Performance analysis of a novel Flue Gas Self-Circulated Burner based on the Low-NOx Combustion [J]. Journal of Energy Engineering, 2020, 146(2): 04019041. [4区、IF: 2.0]
[14] 徐钱, 冯俊小, 周闻华. 分级气体成分对燃气辐射管热过程影响的数值模拟及研究[J]. 工程科学学报, 2016, 39(1):96-106. [EI, 北京青年优秀科技论文]
[15] 徐钱, 冯俊小. 基于正交法扁双P型辐射管仿真模拟及结构优化[J]. 工程科学学报, 2017, 39(4) :581-592. [EI, 北京青年优秀科技论文]
[16] 徐钱, 冯俊小, 周闻华, 等. 分区分级双P型辐射管喷口结构位置特性研究[J]. 工程科学学报, 2017, 39(5) :756-761. [EI]
[17] 徐钱, 冯俊小, 周闻华, 等. 分区分级燃气辐射管模型验证及仿真研究[J]. 工程科学学报, 2016, 38(11):1620-1628. [EI]
[18] 徐钱, 冯俊小, 周敬之. 立式镁还原罐还原过程中结构传热特性分析[J]. 化工进展, 2018, 37(2): 459-467. [EI]
方向二:城市生命线管网多源力学载荷作用安全韧性评估及智能运维
[1] Xu Qian, Application and Extension of Numerical Methods in Heating Pipeline (数值方法于供热管道的应用及拓展) [M] .Singapore: Springer Singapore; 北京: 中国科学技术出版社, 2025. ISBN 978-981-96-1119-5.
[2] Xu Qian, Wang K, Zou Z, et. al. A new type of two-supply, one-return, triple pipe-structured heat loss model based on a low temperature district heating system [J]. Energy, 2021, 218: 119569. [ESI 高被引论文、TOP期刊、1区、IF: 9.0]
[3] Zheng Q, Shu Z, Yang G, Xu Qian*, et al. Analysis of the mechanical characteristics and plasticity-hazardous zones development of natural gas pipeline under overload [J]. Tunnelling and underground space technology, 2023, 142: 1-14. [TOP期刊、1区、IF: 6.7]
[4] Wang K, Xie K, Xu Qian*, et. al. Numerical evaluation of the coupled-uncoupled effectiveness of a fluid-solid-thermal multi-field model for a long-distance energy transmission pipeline [J]. Energy, 2022, 251: 123964. [TOP期刊、1区、IF: 9.0]
[5] Xu Qian, Yang G, et al. Dynamic response model and equivalent solution method of large-diameter buried energy transportation pipeline under moving load [J]. Journal of Natural Gas Science and Engineering, 2022, 106: 104724. [TOP期刊、2区、IF: 4.9]
[6] Chen X, Ren L, Zheng Q, Xu Qian*, et al. Heat loss optimization and economic evaluation of a new fourth generation district heating triple pipe system [J]. Applied Thermal Engineering, 2023, 233: 121160. [TOP期刊、1区、IF: 6.1]
[7] Zheng Q, Shu Z, Xu Qian*, et al. A review of advances in mechanical behaviors of the underground energy transmission pipeline network under loads [J]. Gas Science and Engineering, 2023, 117,:205074. [2区、IF: 5.2]
[8] Xu Qian*, Zhong L, Shu M, Yang G, et al. Analysis of the mechanical behavior and prediction of the plastic zone of a large-diameter buried gas pipeline under ground overload [J]. Gas Science and Engineering. 2023, 110. [2区、IF: 5.2]
[9] Xu Qian, Feng J, Liu L, et al. Analysis of mechanical-fluid-thermal performance of heat pipeline system with structural deformation effects [J]. International Journal of Heat and Mass Transfer, 2019,128:12-23. [TOP期刊、1区、IF: 5.0]
[10] Xu Qian, Feng J, Zhang S. Effects of different loads on structure stress of ‘‘L”-type large-diameter pipeline under burying and trench conditions based on fluid–structure–heat coupling [J]. International Journal of Heat and Mass Transfer, 2017, 115:387-397. [TOP期刊、1区、IF: 5.0]
[11] Xu Qian, Feng J, Zhang S. Combined effects of different temperature and pressure loads on the “L”-type large-diameter buried pipeline [J]. International Journal of Heat and Mass Transfer, 2017, 111:953-961 [TOP期刊、1区、IF: 5.0]
[12] Xu Qian, Feng J, Zhang S. Influence of end side displacement load on stress and deformation of ‘‘L”-type large-diameter buried pipe network [J]. Applied Thermal Engineering, 2017, 126: 245-254. [TOP期刊、1区、IF: 6.1]
[13] Xu Qian, Feng J, Zhang S. Effects of different loads on structure stress of “L”-type large-diameter buried pipe network based on fluid–structure-heat coupling [J]. International Communications in Heat and Mass Transfer, 2017, 86: 222-230. [TOP期刊、1区、IF: 6.4]
[14] Xu Q, Feng J-X. Effects of different loads on structure deformation of “L”-type large-diameter buried pipe network based on flow–heat–solid coupling. Heat Transfer- Asian Research. 2017; 46:1327–1341. [EI]
方向三:极端热湿场景主被动多模态调控技术及海陆空天电应用
[1] Xu Qian, Wang K, Feng J, et. al. A comparative investigation on the effect of different nanofluids on the thermal performance of two-phase closed thermosyphon [J]. International Journal of Heat and Mass Transfer, 2020, 149: 119-189. [ESI 高被引论文、TOP期刊、1区、IF: 5.0]
[2] Liu D.H, Xie K, et. al, Xu Qian*. Numerical evaluation of convective heat transfer properties of two dimensional rotating PCM melt in the unilaterally heated rectangular container [J]. Renewable Energy, 2022, 193: 920-940. [TOP期刊、1区、IF: 9.0]
[3] Xu Qian, Yang G, Wang C, Liu Z, Zhang X, et al. Experimental study on the reinforcement of a gravity heat pipe based on a latent thermal functionally fluid [J]. Energy, 2023, 278: 127782. [TOP期刊、1区、IF:9.0]
[4] Xu Qian, Zhu L.D, et al. Heat transfer performance by forced convection of microencapsulated phase change material-latent functional thermal fluid flowing in a mini-channels heat sink [J]. Applied Thermal Engineering, 2022, 216: 119158. [TOP期刊、1区、IF: 6.1]
[5] Xu Qian, Zhu L. D, Pei Y, et al. Heat transfer enhancement performance of microencapsulated phase change materials latent functional thermal fluid in solid/liquid phase transition regions [J]. International Journal of Heat and Mass Transfer, 2023, 214: 124461. [TOP期刊、1区、IF: 5.0]
[6] Xiong Y. X, Yao C. H, Xu Qian*, Ding Y. L, et al. Waste Semicoke Ash Utilized to Fabricate Shape-stable Phase Change Composites for Building Heating and Cooling [J]. Construction and Building Materials, 2022, 361: 129638. [TOP期刊、1区、IF: 7.4]
[7] Xiong Y.X, Song C.Y, Xu Qian*, et. al. Sludge-incinerated ash based shape-stable phase change composites for heavy metal fixation and building thermal energy storage[J]. Process Safety and Environmental Protection, 2022, 126: 346-356. [TOP期刊、1区、IF: 6.9]
[8] Lin L, Yang D, Xu Qian*, et al. Numerical study on melting and heat transfer characteristics of vertical cylindrical PCM with a focus on the solid-liquid interface heat transfer rate [J]. Journal of Energy Storage, 2023, 72: 1-15. [2区、IF:8.9]
[9] Xu Qian, Yang C, Li G, et al. Numerical investigation on enhanced heat transfer performance of latent functional thermal fluid under phase transition and local motion microscale effects [J]. Applied Thermal Engineering, 2024, 257: 124323. [TOP期刊、1区、IF: 6.1]
[10] Zhao Y, Yuan C, Zhang Y, Qian Xu*, et. al. Thermal performance investigation of latent heat-packed bed thermal energy storage system with axial gas injection [J]. Applied Thermal Engineering. 2025, 258: 124781. [TOP期刊、1区、IF: 6.1]
[11] Xiong Y. X, Yang Y, Xu Qian*, et al. Investigation on low-carbon shape-stable phase change composite by steel slag and carbide slag for solar thermal energy storage [J]. Journal of Energy Storage, 2024, 76: 109736. [2区、IF:8.9]
[12] Xiong Y. X, Fan Y, Wu Y, Xu Qian*, et al. Low-carbon shape-stable phase change composite utilizing semi-coke ash for building thermal energy storage [J]. Solar Energy Materials and Solar Cells, 2024, 270: 112823. [2区、IF:6.3]
[13] Xiong Y. X*, Wang W, Ren J, Akkurt Nevzat, Xu Qian*, et al. Carbide slag recycling to fabricate shape-stable phase change composites for thermal energy storage [J]. Journal of Energy Storage, 2023, 60: 106694. [2区、IF: 8.9]
[14] Xiong Y. X, Xiang L, Xu Qian*, et al. Effects of expanded graphite on NaNO3/semi-coke ash shape-stable phase change composites for thermal energy storage [J]. Journal of Energy Storage, 2023, 72: 108648. [2区、IF:8.9]
[15] Xiong Y. X, Li S, Xu Qian*, et al. Effect of ratio of desulfurization gypsum to carbide slag on low-carbon phase change composites for energy storage [J]. Journal of Energy Storage, 2024, 91: 112086. [2区、IF: 8.9]
[16] Xu Qian, Yang Q, Jia S.H, et. al. Experimental study on synergistic enhancement of thermal performance of a closed two-phase thermosyphon by a TiO2 nanofluid doped with Al2O3 [J]. Case Studies in Thermal Engineering, 2022, 36: 102192. [3区、IF: 6.4]
[17] Wang Z, Zhang H, Xu Qian*, et. al. Experimental study on heat transfer properties of gravity heat pipes in single/hybrid nanofluids and inclination angles [J]. Case Studies in Thermal Engineering, 2022, 34: 102064. [3区、IF: 6.4]
[18] Xiong Y. X, Wang H. X, Xu Qian*, Ding Y. L, et al. Insights into the Enhancement Mechanisms of Molten Salt Nanofluids [J]. International Journal of Photoenergy, 2022, 4912922. [4区、IF: 2.1]
方向四:临床医学、机械、化工、土木等学科交叉
[1] Qiang Y, Boyuan Ran, Li M, Xu Qian*, et. al. GO-functionalized MXene towards superior anti-corrosion coating[J]. Journal of Colloid and Interface Science, 2023, 642: 595-603.[ESI高被引论文、TOP期刊、1区、IF: 9.4]
[2] Xiong Y. X, Xu Qian*, et al. Investigation of a sole gas expander for gas pressure regulation and energy recovery [J]. Energy, 2023, 281. [TOP期刊、1区、IF: 9.0]
[3] Xiong Y. X, Tian X, He M, Xu Qian*, et al. Effects of CO2 capture on waste concrete/sodium nitrate form-stable phase change composites for energy storage [J]. Journal of Cleaner Production, 2024, 440: 140896. [TOP期刊、1区、IF: 9.8]
[4] Xiong Y. X, Li S, Ren J, Xu Qian*, et al. Effect of carbon capture on desulfurization gypsum/carbide slag phase-change composites for waste removal and renewable energy storage [J]. Journal of Environmental Chemical Engineering, 2024, 12(3): 112484. [TOP期刊、2区、IF: 7.4]
[5] Bo Z, Chen P, Xu Qian*, et al. Tightly-connected carbon-coated FeS2 hollow sphere-graphene microstructure for ultrafast and stable potassium ion storage [J]. Journal of Energy Storage, 2024, 84: 110984. [2区、IF: 8.9]
[6] Liu, Z. W, Li, Bo Wen, Xu Qian*, et al. Application and Prospects of Ni−Mn-Based Layered Oxide Cathodes for Sodium-Ion Batteries [J]. ACS Applied Energy Materials, 2024, 7: 3502-3522. [2区、IF: 5.5]
[7] Yao X.Q, Qiang Y.J, Xu Qian*, et. al. Renewable low-cost brassica rapa subsp. Extract for protection of Q235 steel in H2SO4 medium: Experimental and modeling studies [J]. Journal of Industrial and Engineering Chemistry, 2022, 114:427-437. [TOP期刊、2区、IF: 5.9]
[8] Lin L, L Feng, Qian Xu*, Y Chen. Anomalous diffusion in comb model subject to a novel distributed order time fractional Cattaneo-Christov flux [J]. Applied Mathematics Letters, 2020, 102:106-116. [TOP期刊、1区、IF: 2.4]
[9] Xu Qian, Liu Y, Feng J, et. al. Synthesis and Characterization of Disodium Hydrogen Phosphate Dodecahydrate-Lauric-Palmitic Acid Used for Indoor Energy Storage Floor Units [J]. Journal of Thermal Science, 2020, 29: 477-485. [3区、IF: 1.8]
专利
1.一种焦炉立火道的燃烧装置及燃烧方法
2.一种焦炉蓄热室余热利用与SNCR/SCR耦合脱硝方法与装置
3.钾离子电池正极材料用锂掺杂锰基层状氧化物的制备方法
4.pH响应型长效智能水性防腐涂料及其制备方法
2.一种焦炉蓄热室余热利用与SNCR/SCR耦合脱硝方法与装置
3.钾离子电池正极材料用锂掺杂锰基层状氧化物的制备方法
4.pH响应型长效智能水性防腐涂料及其制备方法
获奖
奖励荣誉:
1.中国科协青年人才托举工程
2.北京市科学技术协会青年人才托举工程
3.面向工业节能减排的余热高效利用与储存关键技术及应用, 中国商业联合会科技进步一等奖(R1)
4.长输直埋管网监测报警与安全防护关键技术研究及产业化, 中国发明协会发明二等奖(R1)
5.深部高应力地层灾源体智能判识与诱导释能关键技术, 中国职业安全健康协会科技进步一等奖(R3)
6.工业废渣低碳低成本复合储热技术及应用, 中国发明协会发明二等奖(R2)
7.全球健康长寿创新大赛三等奖(中国医学科学院,40万元)
8.北科青年学者、北京科技大学优秀博士后、北京科技大学优秀共青团干部
9.北京青年优秀科技论文奖、全国能动类百篇优秀毕业论文指导教师
10.北京市三好学生、北京市优秀毕业生、博士研究生国家奖学金
11.北京科技大学“校长奖章”、北京科技大学研究生“十佳学术之星”
竞赛指导:
2024 第十七届全国大学生节能减排社会实践与科技竞赛 国家级一等奖
2021 第十四届全国大学生节能减排社会实践与科技竞赛 国家级三等奖
2024 中国国际大学生创新大赛 北京赛区主赛道 省部级二等奖
2024 中国国际大学生创新大赛 北京赛区产业赛道 省部级二等奖
2023 中国国际大学生创新大赛 产业命题主赛道 铜奖
2023 中国国际大学生创新大赛 北京赛区高教主赛道 省部级二等奖
2024 第三届“京彩大创”北京大学生创新创业大赛科技创新赛道 省部级二等奖
2024 第三届“京彩大创”北京大学生创新创业大赛健康赛道 省部级三等奖
2023 第二届“京彩大创”北京大学生创新创业大赛 省部级百强创业团队
2022 第四届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级二等奖
2021 第三届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级三等奖
2020 第二届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级一等奖
2023 中国青年报 KAB大学生微创业项目 微创之星
2022 中国青年报 KAB大学生微创业项目 科创之星
2021 第十五届中国制冷空调行业大学生科技竞赛 省部级三等奖
2020 第十四届中国制冷空调行业大学生科技竞赛 省部级三等奖
2024 二十五届摇篮杯创新创业竞赛 特等奖
2023 二十四届摇篮杯创新创业竞赛 特等奖
2023 全国大学生能源经济学术创意大赛 国家级二等奖
2023 第八届中国杭州大学生创业大赛 省部级优胜奖
2021 第四届中国可再生能源学会大学生优秀科技作品竞赛 省部级三等奖
1.中国科协青年人才托举工程
2.北京市科学技术协会青年人才托举工程
3.面向工业节能减排的余热高效利用与储存关键技术及应用, 中国商业联合会科技进步一等奖(R1)
4.长输直埋管网监测报警与安全防护关键技术研究及产业化, 中国发明协会发明二等奖(R1)
5.深部高应力地层灾源体智能判识与诱导释能关键技术, 中国职业安全健康协会科技进步一等奖(R3)
6.工业废渣低碳低成本复合储热技术及应用, 中国发明协会发明二等奖(R2)
7.全球健康长寿创新大赛三等奖(中国医学科学院,40万元)
8.北科青年学者、北京科技大学优秀博士后、北京科技大学优秀共青团干部
9.北京青年优秀科技论文奖、全国能动类百篇优秀毕业论文指导教师
10.北京市三好学生、北京市优秀毕业生、博士研究生国家奖学金
11.北京科技大学“校长奖章”、北京科技大学研究生“十佳学术之星”
竞赛指导:
2024 第十七届全国大学生节能减排社会实践与科技竞赛 国家级一等奖
2021 第十四届全国大学生节能减排社会实践与科技竞赛 国家级三等奖
2024 中国国际大学生创新大赛 北京赛区主赛道 省部级二等奖
2024 中国国际大学生创新大赛 北京赛区产业赛道 省部级二等奖
2023 中国国际大学生创新大赛 产业命题主赛道 铜奖
2023 中国国际大学生创新大赛 北京赛区高教主赛道 省部级二等奖
2024 第三届“京彩大创”北京大学生创新创业大赛科技创新赛道 省部级二等奖
2024 第三届“京彩大创”北京大学生创新创业大赛健康赛道 省部级三等奖
2023 第二届“京彩大创”北京大学生创新创业大赛 省部级百强创业团队
2022 第四届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级二等奖
2021 第三届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级三等奖
2020 第二届北京市大学生节能节水低碳减排社会实践与科技竞赛 省部级一等奖
2023 中国青年报 KAB大学生微创业项目 微创之星
2022 中国青年报 KAB大学生微创业项目 科创之星
2021 第十五届中国制冷空调行业大学生科技竞赛 省部级三等奖
2020 第十四届中国制冷空调行业大学生科技竞赛 省部级三等奖
2024 二十五届摇篮杯创新创业竞赛 特等奖
2023 二十四届摇篮杯创新创业竞赛 特等奖
2023 全国大学生能源经济学术创意大赛 国家级二等奖
2023 第八届中国杭州大学生创业大赛 省部级优胜奖
2021 第四届中国可再生能源学会大学生优秀科技作品竞赛 省部级三等奖
代表性科研项目
1.微纳颗粒二元掺混两相流介尺度结构调控及热输运强化研究,国家自然科学基金面上基金,主持
2.相变微胶囊潜热型功能流体热输运过程多尺度结构调控及强化传热机制,国家自然科学基金青年基金,主持
3.锂离子电池正极材料制备工业过程的协同优化控制及应用,国家自然科学基金重点基金项目,合作单位负责人
4.AI辅助热流固多场仿生结直肠癌血运监测仪的研发,人社部高端外国专家引进计划,主持
5.热流固多场仿生模拟介入结直肠癌动脉切除血供系统动态响应及风险预测,广东省基础与应用基础研究地区培育项目(省优青),主持
6.工农二元固废复合相变材料孔网络结构调控及传热强化机制,广东省基础与应用基础研究面上基金项目,主持
7.相变微胶囊热输运过程边界层流动与质能传递机制研究,广东省基础与应用基础研究青年基金项目,主持
8.新型多相功能流体于高密度热流系统冷却技术的开发与应用,广东省科技成果转化特色创新研究项目,主持
9.相变微胶囊热输运过程质能传递机制及微观调控机理研究,博士后面上基金,主持
10.新型相变微胶囊潜热型功能流体于强化传热系统的关键技术研究,佛山人民政府产学研创新专项基金,主持
11.热流固多场仿生模拟介入结直肠癌动脉切除风险预测及科学治疗策略,中国医学科学院,主持
12.航空锂电液流热控多尺度结构特征及动态演变机制,民航局重点实验室项目,主持
13.赤泥资源化复合相变储能技术研发,教育部产学研合作协同育人项目,主持
14.热流固多场仿生模拟介入结直肠癌血运风险监测仪的研发,北京市海淀区产学研转化专项项目,主持
15.基于U-Net网络的多模态冠状动脉及斑块三维重构软件开发及验证,北京市通州区产学研转化专项项目,主持
16.临床结直肠癌血供响应机制热流固多场耦合数值研究,国际交流成长计划项目,主持
17.动力电池液流温控体系纳微掺杂固液两相介尺度结构协同调控机制,青年教师国际交流成长计划项目,主持
18.电池液冷温控体系多尺度界面调控机制,北京科技大学青年学者人才引进项目,主持
19.金属流体界面腐蚀规律与缓蚀剂组装机理研究,北京科技大学交叉研究项目,主持
20.基于复合相变储热材料的移动储热系统强化传热特性研究,中央高校基本科研业务项目,主持
21.基于相变蓄热的生活热水替代系统研究与示范设计服务,顺天地国际能源科技有限公司,主持
22.高温合金盘锻件热处理过程界面换热研究,钢铁研究总院,主持
23.新型功能流体于纺织印染强化冷却系统研究与示范设计,高新企业,主持
24.机房及数据中心热控系统研究与示范设计,高新企业,主持
25.高热流密度传热器件传输极限测试,高新企业,主持
26.钢铁-化产-建材多联产过程耦合节能减排系统构建与评价,国家科技部重点研发计划项目,骨干成员
27.钢铁行业烟气多污染物全过程控制耦合关键技术,国家科技部重点研发计划项目,骨干成员
28.新一代辐射管的研究开发,国家科技支撑计划课题,骨干成员
29.大烟气回流低氮燃烧U型辐射管整套技术开发与应用,鞍钢,骨干成员
30.大口径直埋热水管道的应力分析及试验研究,北京市热力集团科技部,骨干成员
31.二氧化碳相变致裂切顶卸压技术研究与示范,华晋焦煤有限责任公司,骨干成员
32.工作面停采线定向长钻孔区域压裂卸压技术研究,华晋焦煤有限责任公司,骨干成员
33.细粒级粉矿无热源延续还原装置及预热系统研究,甘肃酒钢集团宏兴钢铁股份有限公司,骨干成员
34.大型板带加热炉节能量测量和验证标准研究,国家科技支撑计划课题,骨干成员
35.板坯加热质量及节能降耗测试分析研究,吉林建龙钢铁有限责任公司,骨干成员
2.相变微胶囊潜热型功能流体热输运过程多尺度结构调控及强化传热机制,国家自然科学基金青年基金,主持
3.锂离子电池正极材料制备工业过程的协同优化控制及应用,国家自然科学基金重点基金项目,合作单位负责人
4.AI辅助热流固多场仿生结直肠癌血运监测仪的研发,人社部高端外国专家引进计划,主持
5.热流固多场仿生模拟介入结直肠癌动脉切除血供系统动态响应及风险预测,广东省基础与应用基础研究地区培育项目(省优青),主持
6.工农二元固废复合相变材料孔网络结构调控及传热强化机制,广东省基础与应用基础研究面上基金项目,主持
7.相变微胶囊热输运过程边界层流动与质能传递机制研究,广东省基础与应用基础研究青年基金项目,主持
8.新型多相功能流体于高密度热流系统冷却技术的开发与应用,广东省科技成果转化特色创新研究项目,主持
9.相变微胶囊热输运过程质能传递机制及微观调控机理研究,博士后面上基金,主持
10.新型相变微胶囊潜热型功能流体于强化传热系统的关键技术研究,佛山人民政府产学研创新专项基金,主持
11.热流固多场仿生模拟介入结直肠癌动脉切除风险预测及科学治疗策略,中国医学科学院,主持
12.航空锂电液流热控多尺度结构特征及动态演变机制,民航局重点实验室项目,主持
13.赤泥资源化复合相变储能技术研发,教育部产学研合作协同育人项目,主持
14.热流固多场仿生模拟介入结直肠癌血运风险监测仪的研发,北京市海淀区产学研转化专项项目,主持
15.基于U-Net网络的多模态冠状动脉及斑块三维重构软件开发及验证,北京市通州区产学研转化专项项目,主持
16.临床结直肠癌血供响应机制热流固多场耦合数值研究,国际交流成长计划项目,主持
17.动力电池液流温控体系纳微掺杂固液两相介尺度结构协同调控机制,青年教师国际交流成长计划项目,主持
18.电池液冷温控体系多尺度界面调控机制,北京科技大学青年学者人才引进项目,主持
19.金属流体界面腐蚀规律与缓蚀剂组装机理研究,北京科技大学交叉研究项目,主持
20.基于复合相变储热材料的移动储热系统强化传热特性研究,中央高校基本科研业务项目,主持
21.基于相变蓄热的生活热水替代系统研究与示范设计服务,顺天地国际能源科技有限公司,主持
22.高温合金盘锻件热处理过程界面换热研究,钢铁研究总院,主持
23.新型功能流体于纺织印染强化冷却系统研究与示范设计,高新企业,主持
24.机房及数据中心热控系统研究与示范设计,高新企业,主持
25.高热流密度传热器件传输极限测试,高新企业,主持
26.钢铁-化产-建材多联产过程耦合节能减排系统构建与评价,国家科技部重点研发计划项目,骨干成员
27.钢铁行业烟气多污染物全过程控制耦合关键技术,国家科技部重点研发计划项目,骨干成员
28.新一代辐射管的研究开发,国家科技支撑计划课题,骨干成员
29.大烟气回流低氮燃烧U型辐射管整套技术开发与应用,鞍钢,骨干成员
30.大口径直埋热水管道的应力分析及试验研究,北京市热力集团科技部,骨干成员
31.二氧化碳相变致裂切顶卸压技术研究与示范,华晋焦煤有限责任公司,骨干成员
32.工作面停采线定向长钻孔区域压裂卸压技术研究,华晋焦煤有限责任公司,骨干成员
33.细粒级粉矿无热源延续还原装置及预热系统研究,甘肃酒钢集团宏兴钢铁股份有限公司,骨干成员
34.大型板带加热炉节能量测量和验证标准研究,国家科技支撑计划课题,骨干成员
35.板坯加热质量及节能降耗测试分析研究,吉林建龙钢铁有限责任公司,骨干成员