邱羽

个人信息Personal Information

特聘副教授

硕士生导师

教师英文名称:Yu Qiu

教师拼音名称:qiuyu

所在单位:能源科学与工程学院

办公地点:能源楼113

联系方式:yu.qiu@csu.edu.cn

其他任职:中国工程热物理学会传热传质分会青年委员会委员、Green Energy and Resources青年编委、Topic Editor of Energies, CRES Member, ASME Member

毕业院校:西安交通大学

学科:动力工程及工程热物理

个人简介Personal Profile

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  邱羽,博士,四川绵阳三台人,现任中南大学能源科学与工程学院特聘副教授。从事高温/超高温光热发电技术、高密度储能技术、太阳能驱动界面蒸发技术中的工程热物理问题研究。实验室名为"SeeU Lab", 即Solar Energy Efficient Utilization Laboratory (太阳能高效利用实验室)。主持国家自然科学基金青年项目1项、湖南省自然科学基金青年项目1项、长沙市自然科学基金重点项目1项、中南大学特聘副教授科研项目1项;参与国家自然科学基金重点项目、国家自然科学基金重大项目、国家自然科学基金面上项目、横向合作项目等的研究。
  研究成果获省部级自然科学一等奖1项、2017年中国工程热物理学会传热传质分会“王补宣-过增元青年优秀论文奖”、2016年国家光热联盟优秀论文奖。截至目前,已发表学术论文60余篇,其中SCI论文40余篇,4篇一作论文入选ESI高被引论文(Top1%),2篇一作论文入选ESI热点论文(Top1‰)。已获授权发明专利7项,软件著作权2项。
  现为中国工程热物理学会传热传质分会青年委员会委员、国际期刊《Green Energy and Resources》青年编委、《Energies》主题编辑(Topic Editor)、中国可再生能源学会会员(CRES Member)、美国机械工程师协会会员(ASME Member)。担任Applied Energy Symposium 2020: Low carbon cities and urban energy systems (CUE2020)分会场主席、2017 Thermal and Fluids Engineering Conference分会场主席。担任国家自然科学基金、广东省自然科学基金、湖南省自然科学基金评阅人,Applied Energy、Energy Conversion and Management、Renewable Energy、Solar Energy、Journal of Solar Energy Engineering-T ASME、Frontiers in Energy、Ceramics International 、Energies、International Journal of Hydrogen Energy等期刊的审稿人。


更多信息

☆ E-mail: yu.qiu@csu.edu.cn

☆ Google Scholar: https://scholar.google.com/citations?user=fhJci2QAAAAJ&hl=zh-CN&oi=sra

☆ ASME Profile: community.asme.org/members/yuqiu680/default.aspx 

☆ ResearchGate: www.researchgate.net/profile/Yu_Qiu44

☆ ORCID iD: 0000-0001-9836-036X

☆ WOS ResearcherID: AAY-9339-2021

Scopus Author ID: 56335712600


授课信息

(1)秋季学期:太阳能电池原理与制造技术(前32学时)

(2)春季学期:太阳能热利用原理与技术(光热发电部分8学时)


学术论文

(1)期刊论文

[48] Li Qing, E Erqi, Qiu Yu*, Wang Jikang, Zhang Yuanting. Conceptual design of novel He-SCO2 Brayton cycles for ultra-high-temperature concentrating solar power[J]. Energy Conversion and Management, 2022, 260: 115618. (IF=11.533)

[47] Xu Mingpan, Guo Lin, Zhang Pengfei, Qiu Yu*, Li Qing*, Wang Jikang. Near-perfect spectrally-selective metasurface solar absorber based on tungsten octagonal prism array[J]. RSC Advances, 2022, 12(26), 16823-16834. (IF=4.036)

[46] Zhang Yuanting, Qiu Yu*, Li Qing, Asegun Henry*. Optical-thermal-mechanical characteristics of an ultra-high-temperature graphite receiver designed for concentrating solar power[J]. Applied Energy, 2022, 307: 118228.  (IF=11.446)

[45] Qiu Yu, Pengfei Zhang, Li Qing, Yuanting Zhang, Weihong Li. A perfect selective metamaterial absorber for high-temperature solar energy harvesting[J]. Solar Energy, 2021, 230:1165-1174. (IF=7.188)

[44] Li Qing, Wang Jikang, Qiu Yu*, Xu Mingpan, Wei Xiudong. A modified indirect flux mapping system for high-flux solar simulators[J]. Energy, 2021, 235: 121311. (IF=8.857)

[43] Qiu Yu, Xu Mingpan,Li Qing, Huang Rongzong, Wang Jikang. A high-temperature near-perfect solar selective absorber combining tungsten nanohole and nanoshuriken arrays[J]. ES Energy & Environment, 2021, 13:77-90. (Best paper award of the Publisher)

[42] Qiu Yu, Xu Yucong, Li Qing, Wang Jikang, Wang Qiliang, Liu Bin. Efficiency enhancement of a solar trough collector by combining solar and hot mirrors[J]. Applied Energy, 2021, 299: 117290. (IF=11.446)

[41] Qiu Yu, Xu Mingpan, Li Qing, Xu Yucong, Wang Jikang. A novel evacuated receiver improved by a spectral-selective glass cover and rabbit-ear mirrors for parabolic trough collector[J]. Energy Conversion and Management, 2021, 227: 113589. (IF=11.533)

[40] Wang Jikang, Qiu Yu*, Li Qing*, Xu Mingpan, Wei Xiudong. Design and experimental study of a 30 kWe adjustable solar simulator delivering high and uniform flux[J]. Applied Thermal Engineering, 2021, 195: 117215. (IF=6.465)

[39] Lv Yigao, Wen Zhexi, Li Qing, Qiu Yu. Numerical investigation on thermal hydraulic performance of hybrid wavy channels in a supercritical CO2 precooler [J]. International Journal of Heat and Mass Transfer, 2021, 181, 121891. (IF=5.431)

[38] Yu Yue, Li Qing, Qiu Yu , Huang Rongzong. Bubble dynamics and dry spot formation during boiling on a hierarchical structured surface: A lattice Boltzmann study[J]. Physics of Fluids, 2021, 33: 083306. (IF=4.980)

[37] Tang Shi,  Li Qing, Yu Yue, Qiu Yu. Enhancing dropwise condensation on downward-facing surfaces through the synergistic effects of surface structure and mixed wettability[J]. Physics of Fluids, 2021, 33: 083301. (IF=4.980)

[36]  Wang Qiliang, Yao Yao, Hu Mingke, Cao Jingyu, Qiu Yu, Yang Hongxing. An air curtain surrounding the solar tower receiver for effective reduction of convective heat loss[J]. Sustainable Cities and Society, 2021, 71: 103007. (IF=10.696)

[35]  Dong Jiamin, Liu Renjing, Qiu Yu, Crossan Mary. Should knowledge be distorted? Managers' knowledge distortion strategies and organizational learning in different environments[J]. The Leadership Quarterly, 2021, 32(3):101477. (IF=10.517)

[34] Qiu Yu, Zhang Yuanting, Li Qing, Xu Yucong, Wen Zhe-Xi. A novel parabolic trough receiver enhanced by integrating a transparent aerogel and wing-like mirrors[J]. Applied Energy, 2020, 279: 115810. (IF=11.446, 被AEii国际应用能源报道)

[33] Li Qing, Zhang Yuanting, Wen Zhexi, Qiu Yu*. An evacuated receiver partially insulated by a solar transparent aerogel for parabolic trough collector[J]. Energy Conversion and Management, 2020, 214: 112911. (IF=11.533)

[32] He Ya-Ling, Qiu Yu, Wang Kun, Yuan Fan, Wang Wenqi, Li Ming-Jia, Guo Jia-Qi. Perspective of concentrating solar power[J]. Energy, 2020: 117373.(IF=8.857, ESI高被引论文、入选主编推荐论文Editor's Choice)

[31] Qiu Yu, He Ya-Ling, Cheng Zedong, Wang Kun. Study on optical and thermal performance of a linear Fresnel solar reflector using molten salt as HTF with MCRT and FVM methods[J]. Applied Energy, 2015, 146: 162-173. (IF=11.446ESI高被引论文)

[30] Qiu Yu, He Ya-Ling, Li Peiwen, Du Baocun. A comprehensive model for analysis of real-time optical performance of a solar power tower with a multi-tube cavity receiver[J]. Applied Energy, 2017, 185: 589-603. (IF=11.446ESI高被引论文、热点论文)

[29] Qiu Yu, He Ya-Ling, Wu Ming, Zheng Zhangjing. A comprehensive model for optical and thermal characterization of a linear Fresnel solar reflector with a trapezoidal cavity receiver[J]. Renewable Energy, 2016, 97:129-144. (IF=8.001, ESI高被引论文、热点论文)

[28] Qiu Yu, Li Mingjia, He Ya-Ling, Tao Wen-Quan. Thermal performance analysis of a parabolic trough solar collector using supercritical CO2 as heat transfer fluid under non-uniform solar flux[J]. Applied Thermal Engineering, 2017, 115:1255-1265. (IF=6.465ESI高被引论文)

[27] Qiu Yu, Li Mingjia, Wang Kun, Liu Zhanbin, Xue Xiaodai. Aiming strategy optimization for uniform flux distribution in the receiver of a linear Fresnel solar reflector using a multi-objective genetic algorithm[J]. Applied Energy, 2017, 205: 1394-1407. (IF=11.446)

[26] Qiu Yu, Li Mingjia, Wang Wenqi, Du Baocun, Wang Kun. An experimental study on the heat transfer performance of a prototype molten-salt rod baffle heat exchanger for concentrated solar power[J]. Energy, 2018, 156: 63-72. (IF=6.082)

[25] Qiu Yu, Li Mingjia, Li Meng-Jie, Zhang Honghu, Ning Bo. Numerical and experimental study on heat transfer and flow features of representative molten salts for energy applications in turbulent tube flow[J]. International Journal of Heat and Mass Transfer, 2019, 135: 732-745. (IF=5.584)

[24] Wang Wenqi#, Qiu Yu# (co-first author), Li Mingjia, Cao Feng, Liu Zhanbin. Optical efficiency improvement of solar power tower by employing and optimizing novel fin-like receivers[J]. Energy Conversion and Management, 2019, 184: 219-234. (IF=11.533)

[23] 邱羽, 何雅玲, 程泽东. 线性菲涅尔太阳能系统光学性能研究与优化[J]. 工程热物理学报, 2015,36 (12):2551-2556.

[22] 邱羽, 何雅玲, 梁奇, 程泽东. 线性菲涅尔太阳能系统光热耦合模拟方法研究[J]. 工程热物理学报, 2016,37(10):2142-2149.

[21] Wang Wen-Qi, Qiu Yu, Li Ming-Jia, He Ya-Ling, Cheng Ze-Dong. Coupled optical and thermal performance of a fin-like molten salt receiver for the next-generation solar power tower[J]. Applied Energy, 2020, 272:115079.

[20] Wang wen-Qi, Qiu Yu, He Ya-Ling, Shi Hong-Yuan. Experimental study on the heat transfer performance of a molten-salt printed circuit heat exchanger with airfoil fins for concentrating solar power[J]. International Journal of Heat and Mass Transfer, 2019, 135: 837-846.

[19] Li Meng-Jie, Qiu Yu, Li Ming-Jia. Cyclic thermal performance analysis of a traditional single-layered and of a novel multi-layered packed-bed molten salt thermocline tank[J]. Renewable Energy, 2018, 118: 565-578.

[18] Du Bao-Cun, Qiu Yu, He Ya-Ling, Xue Xiao-Dai. Study on heat transfer and stress characteristics of the pressurized volumetric receiver in solar power tower system[J]. Applied Thermal Engineering, 2018, 133: 341-350.

[17] He Ya-Ling, Wang Kun, Qiu Yu, Du Bao-Cun, Liang Qi, Du Shen. Review of the solar flux distribution in concentrated solar power: non-uniform features, challenges, and solutions[J]. Applied Thermal Engineering, 2019,149:448-474.(ESI高被引论文)

[16] Yuan Fan, Li Ming-Jia, Qiu Yu, Li Meng-Jie. Specific heat capacity improvement of molten salt for solar energy applications using charged single-walled carbon nanotubes[J]. Applied Energy, 2019, 250: 1481-1490.

[15] Du Bao-Cun, He Ya-Ling, Qiu Yu, Liang Qi, Zhou Yipeng. Investigation on heat transfer characteristics of molten salt in a shell-and-tube heat exchanger[J]. International Communications in Heat and Mass Transfer, 2018, 96: 61-68.

[14] Zhou Yipeng, He Ya-Ling, Qiu Yu, Xie Tao. Multi-scale investigation on the absorbed irradiance distribution of the nanostructured front surface of the concentrated PV-TE device by a MC-FDTD coupled method[J]. Applied energy, 2017, 207: 18-26.

[13] Wen Zhe-Xi, He Ya-Ling, Qiu Yu, Cao Xue-Wei, Yan Chao. Feasibility study of different cooling techniques in a ground fast cooling simulation device[J]. International Journal of Heat and Mass Transfer, 2016, 101: 336-340.

[12] Wang Kun, He Ya-Ling, Qiu Yu, Zhang Yuwen. A novel integrated simulation approach couples MCRT and Gebhart methods to simulate solar radiation transfer in a solar power tower system with a cavity receiver[J]. Renewable Energy, 2016, 89: 93-107.

[11] Cheng Ze-Dong, He Ya-Ling, Qiu Yu. A detailed nonuniform thermal model of a parabolic trough solar receiver with two halves and two inactive ends [J]. Renewable Energy, 2015, 74: 139-147.

[10] Shi Hongyuan, Li Ming-Jia, Wang Wen-Qi, Qiu Yu, Tao Wen-Quan. Heat transfer and friction of molten salt and supercritical CO2 flowing in an airfoil channel of a printed circuit heat exchanger[J]. International Journal of Heat and Mass Transfer, 2020, 150: 119006.

[9]   Cheng Ze-Dong, Zhao Xue-Ru, He Ya-Ling, Qiu Yu. A novel optical optimization model for linear Fresnel reflector concentrators[J]. Renewable Energy, 2018, 129: 486-499.

[8]   He Ya-Ling, Zheng Zhang-Jing, Du Bao-Cun, Wang Kun, Qiu Yu. Experimental investigation on turbulent heat transfer characteristics of molten salt in a shell-and-tube heat exchanger [J]. Applied Thermal Engineering, 2016, 108: 1206-1213.

[7]   Zhou Yipeng, Qiu Yu, He Ya-Ling, Xie Tao. Multi-scale investigation on the optical performance of a concentrated photovoltaic thermoelectric hybrid system by a MC-FDTD coupled method[J]. Energy Procedia, 2017, 105: 473-479.

[6]   李梦杰, 邱羽, 何雅玲. 一种新型单罐多层填充床蓄热器蓄热性能研究[J]. 太阳能学报, 2018, 39(8):2226-2233.

[5]   何雅玲, 王文奇, 邱羽, 郑章靖, 杜保存, 王坤, 时红远. 熔盐在复杂换热结构内的对流换热特性实验研究及进展[J]. 科学通报, 2019,64(Z2):3007-3019.

[4]   王坤, 何雅玲, 邱羽, 程泽东. 塔式太阳能熔盐腔式吸热器一体化光热耦合模拟研究[J]. 科学通报, 2016, 15: 005.

[3]   时红远, 刘华, 熊建国, 邱羽, 何雅玲. 丁胞与翼型肋片相结合的印刷电路板式换热器流动与换热特性的研究[J].工程热物理学报,2019,40(4):857-862.

[2]   何雅玲, 杜保存, 王坤, 邱羽, 刘占斌. 太阳能腔式熔盐吸热器随时空变化的光-热-力耦合一体化方法, 机理分析及其失效准则研究[J]. 科学通报, 2017 (36): 4308-4321.

[1]   何雅玲, 王坤, 杜保存, 邱羽, 郑章靖, 梁奇. 聚光型太阳能热发电系统非均匀辐射能流特性及解决方法的研究进展[J]. 科学通报, 2016 (30): 3208-3237.

 

(2)会议论文/报告

[17] 额尔奇, 邱羽*, 李庆, 张元婷, 王济康. 超高温He-SCO2梯级布雷顿循环多目标优化研究[C]. 2021年中国工程热物理学会工程热力学与能源利用分会, 长沙(线上): 2022,4.9-4.10. (报告)

[16] 王济康, 邱羽*, 李庆, 张元婷, 徐明攀, 额尔奇. 超高温塔式太阳能吸热器光热性能研究[C]. 2021年中国工程热物理学会传热传质分会, 上海.

[15] Qiu Yu, Zhang Yuanting, He Ya-Ling*, Wang Jikang, Li Xiao-Yue, Li Qing. An optical-thermal coupled model for performance analysis of a molten-salt solar power tower[C]. International Conference on Applied Energy 2021, Bangkok, Thailand (Online), Nov. 29-Dec. 5, 2021.

[14] 邱羽. 太阳能高温光热发电系统聚光吸热机理研究[C]. 第七届热力学与能源利用青年学术论坛暨高效热力循环及能量综合利用研讨会, 天津: 2021.5.14-16. (报告)

[13] 邱羽. 高温聚光太阳能系统聚光吸热机理与性能优化调控研究[C]. 2021年传热传质青年学术论坛, 北京: 2021.4.16-18. (报告)

[12] Wang Jikang, Qiu Yu*, Li Qing*, Xu Yucong, Xu Mingpan, Zhang Yuanting. Efficiency enhancement of the parabolic trough receiver by employing hot mirrors for urban energy supply[C]. Applied Energy Symposium 2020: Low carbon cities and urban energy systems (CUE2020). Tokyo, Japan (Online), Oct. 10-17, 2020.

[11] Qiu Yu, Li Ming-Jia, He Ya-Ling, Cheng Ze-Dong. Optical performance analysis of a porous open volumetric air receiver in a solar power tower[C]. 2nd Thermal and Fluids Engineering Conference and 4th International Workshop on Heat Transfer (TFEC/IWHT 2017). Las Vegas, NV, USA, April 2-5, 2017.

[10]  Qiu Yu, Cheng Ze-Dong, Li Ming-Jia, He Ya-Ling, Tao Wen-Quan. Numerical study of a parabolic trough solar collector using s-CO2 as heat transfer fluid by coupling FVM and MCRT Method[C]. 2015 Asian Symposium on Computational Heat Transfer and Fluid Flow (ASCHT2015). Pusan, South Korea, Nov. 22-26, 2015.

[9]  Zhou Yi-Peng, Qiu Yu, He Ya-Ling, Xie Tao. Multi-scale investigation on the optical performance of a concentrated photovoltaic thermoelectric hybrid system by a MC-FDTD coupled method[C]. 2016 The 8th International Conference on Applied Energy(ICAE2016). Beijing, China, Oct. 8-11, 2016.

[8] 邱羽李梦杰何雅玲均匀与非均匀热流条件下的熔盐管内对流传热与阻力特性研究[C]. 2017中国工程热物理学术年会传热传质分会,苏州,2017,10.27-10.30.

[7] 邱羽何雅玲塔式聚光太阳能系统中太阳辐射传播过程的统一建模[C]. 第六届国家太阳能光热产业技术创新战略联盟研究生论坛西安,2016,9.22-23.

[6] 邱羽,何雅玲,梁奇,程泽东线性菲涅尔太阳能系统光热耦合模拟方法研究[C]. 2015中国工程热物理学术年会传热传质分会,大连,2015,10.30-11.2.

[5] 邱羽,何雅玲,程泽东.  线性菲涅尔太阳能系统光学性能研究与优化[C]. 2014中国工程热物理学术年会,西安,2014, 10.31-11.2.

[4] 邱羽,何雅玲,程泽东,郑章靖.  线性菲涅尔太阳能集热管三维数值模拟研究[C]. 2013中国工程热物理学会传热传质学术会议,重庆,2013, 10.25-28.

[3] 李梦杰, 邱羽何雅玲单罐填充床斜温层蓄热器蓄热性能研究. 2016年中国工程热物理学会传热传质学术会议中国北京, 2016, 10.21-24.

[2] 王坤何雅玲, 邱羽程泽东全镜场条件下塔式太阳能熔盐腔体吸热器光热耦合模拟研究[C]. 2015中国工程热物理学术年会传热传质分会,大连,2015,10.30-11.2.

[1] 李梦杰, 邱羽何雅玲太阳能热发电站中单罐填充床蓄热器蓄热性能研究第六届国家太阳能光热产业技术创新战略联盟研究生论坛西安,2016,9.22-23.


专利与软件

[13] 胡佐新, 李庆, 邱羽, 徐明攀, 王济康. 一种适用于宽温度范围的高性能太阳能光谱选择性吸热器[P]. 中国发明专利, 申请号: 2022101551913.

[12] 李庆冯海翔李云旗邱羽. 一种基于热转移强化的太阳能驱动界面蒸发器[P]. 中国发明专利, 申请号: 2022100913796.

[11] 邱羽, 徐明攀, 李庆, 张鹏飞, 王济康, 张元婷. 一种基于等离激元共振的高温太阳光谱选择性吸收器及其制备方法[P].中国发明专利 申请号: 2022100697439.

[10] 邱羽, 额尔奇, 李庆, 王济康, 张元婷, 张伟琛. 一种超高温氦气-超临界二氧化碳联合布雷顿循环系统[P]. 中国发明专利, 申请号: 2022100332374.

[9] 王傲, 胡子涵, 李云旗, 冯海翔, 邱羽, 李庆. 一种基于松树形仿生结构设计的太阳能界面蒸发器[P]. 中国发明专利, 专利号:ZL202111612334.0.

[8] 邱羽, 李庆. 一种组合式抛物面型太阳能聚光器设计方法[P]. 中国发明专利, 专利号: ZL202011402484.4

[7] 邱羽, 张鹏飞, 李庆. 一种用于太阳能水气化的光谱选择性吸光结构[P]. 中国发明专利, 专利号: ZL202110030092.8

[6] 邱羽, 张鹏飞, 李庆. 一种金属与电介质复合的耐高温太阳光谱选择性吸收结构[P]. 中国发明专利, 专利号: ZL202110029745.0

[5] 何雅玲邱羽李明佳吴明王坤.一种槽式聚光太阳能集热系统设计方法[P]. 中国发明专利专利号: ZL201610703030.8, 授权日期: 2018.05.18.

[4] 何雅玲李梦杰邱羽一种单罐多层填充床蓄热器设计方法[P]. 中国发明专利专利号: ZL201611236467.1, 授权日期: 2019.01.18.

[3] 何雅玲郑章靖王坤杜保存邱羽周一鹏梁奇吴明一种熔盐换热/储热设备性能测试装置[P]. 中国发明专利专利号: ZL201510918131.2, 授权日期: 2018.04.17. 

[2] 何雅玲邱羽王坤程泽东谢涛塔式聚光太阳能系统光学性能分析与设计软件(SPTOPTIC)V1.0[CP]. 软件著作权登记号: 2015SR219383, 登记日期: 2015.11.11.

[1] 程泽东,何雅玲,邱羽线性菲涅尔反射式太阳能聚光系统光学性能分析与设计软件V1.0[CP]. 软件著作权,登记号:2014SR173439 (证书号:软著登字第00579121号).


荣誉与奖励

[10]  何雅玲, 陶于兵, 程泽东, 邱羽, 李明佳, 席奂. 2019年陕西省自然科学一等奖. 陕西省人民政府, 获奖日期: 2020.4.6

[9]  邱羽. 2017王补宣-过增元青年优秀论文奖”, 授奖日期: 2017.10.29.

[8]  邱羽. 2016国家光热联盟优秀论文奖授奖日期: 2016.09.23.

[7]  邱羽西安交通大学2019优秀毕业研究生(博士)授奖年月: 2019.7.

[9]  邱羽. 2018博士研究生国家奖学金中华人民共和国教育部授奖日期: 2018.11.20.

[5]  邱羽. 2017博士研究生国家奖学金中华人民共和国教育部授奖日期: 2017.11.20.

[4]  邱羽. 2017中国大学生自强之星提名奖”. 共青团中央、全国学联授奖日期: 2018.5.29.

[3]  邱羽. 2017陕西省大学生自强之星陕西共青团、陕西省学联授奖日期: 2018.5.29.

[2]  邱羽. 2015西门子中国奖学金西门子中国授奖日期: 2016.12.28.

[1]  邱羽西安交通大学2013优秀毕业生(本科)授奖年月: 2013.7.

 

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  • 工作经历Work Experience