何锁盈
Associate Professor
Visit:
Personal Information:
  • Name (Pinyin):
    hesuoying
  • Date of Employment:
    2015-09-01
  • School/Department:
    能源与动力工程学院
  • Education Level:
    With Certificate of Graduation for Doctorate Study
  • Business Address:
    东配楼415 (山东大学千佛山校区)
  • Gender:
    Male
  • Contact Information:
    0531-88399008 suoyinghe@hotmail.com; s.he@sdu.edu.cn
  • Degree:
    Doctoral Degree in Engineering
  • Status:
    Employed
  • Alma Mater:
    澳大利亚昆士兰大学
  • Supervisor of Master's Candidates
Biography

基本情况

   何锁盈,男,1987年生,陕西咸阳人,工学博士、副教授、硕士生导师

 

研究方向:

[1]      传热传质理论及其工程应用(蒸发冷却、喷嘴/填料蒸发冷却的工程应用);

[2]      高效能量转换理论与技术(冷却塔的节能优化、干湿联合冷却技术);

[3]      低碳能源及节能新技术(太阳能光伏组件冷却、光伏光热高效利用技术、空气源热泵技术)。

 

教育经历:

        2006-2010,中南大学,学士,建筑环境与设备工程

        2010-2011,中南大学,硕士,于2011年国家公派留学澳大利亚

        2011-2015,澳大利亚昆士兰大学,博士,热能工程 (导师: Prof. Hal Gurgenci, Dr. Zhiqiang Guan, Dr. Kamel Hooman)

 

工作经历:

         20159至今,山东大学能源与动力工程学院,副教授、硕士生导师

         201511—20189月,山东大学能源与动力工程学院,在职博士后

 

学术兼职:

[1]    Fluid Dynamics & Materials Processing期刊编委、Energies期刊Special Issue编委、Green Energy and Resources期刊青年编委、《中国电力》期刊青年编委

[2]    教育部学位中心硕士研究生学位论文,评审专家

[3]    山东省能源行业专家库专家

[4]    Renewable and Sustainable Energy Reviews, Energy Conversion and Management, Applied Thermal Engineering, International Journal of Thermal Science, International Journal of Heat and Mass Transfer, 中国电机工程学报,中南大学学报,流体机械等20余个期刊审稿人

[5]    全国大学生节能减排社会实践与科技竞赛网评专家

 

主讲课程:

[1]    本科生课程:《工程热力学》

[2]    研究生课程:《科技论文写作与发表(中英文)》,《Energy Conservation of Thermodynamic Systems and the Utilization of New Energy(全英文课程)》

 

获奖情况:

[1]    入选山东大学青年学者未来计划2016年度济南市杰出青年技术创新能手

[2]    先后获得中国轻工业联合会科学技术进步奖二等奖,河南省科学技术进步奖二等奖,河南省教育厅科技成果二等奖,山东省高等学校科学技术奖本科高校类一等奖,山东大学2019年暑期学校优秀项目,山东大学青年教师教学比赛三等奖,一带一路蒸发冷却空调关键技术与应用论坛优秀论文奖,1st ICSRAC国际会议优秀论文奖,山东省博士后新旧动能转换重大工程专题研究征文三等奖,Energy Conversion and ManagementApplied Thermal Engineering等期刊杰出审稿人

[3]    山东省研究生优秀成果奖二等奖(指导教师),指导学生参加《全国大学生节能减排社会实践与科技竞赛》获二等奖1项、三等奖4项;指导学生参加《2016年全国大学生物联网设计竞赛》获华东赛区一等奖

[4]    UQ Graduate School International Travel Award2011年国家公派研究生

 

承担项目:

[1]    高效干湿联合一体式换热站节水增效关键技术研究,山东省科技厅其他计划,在研;

[2]    智慧城市供热大脑关键技术研发,山东省科技厅其他计划,在研;

[3]   太阳能光伏板干湿联合冷却过程的能质传递强化机理研究,山东省自然科学基金面上项目,在研;

[4]    高效干湿联合一体式换热站节水增效关键技术研究,企事业单位委托项目,在研;

[5]    智慧空气源热泵系统仿真模拟,企事业单位委托项目,在研;

[6]    高位收水、节水除雾及噪声防治一体化的机力通风冷却塔数模物模试验研究,企事业单位委托项目,在研;

[7]    大型湿式冷却塔填料优化布置的数值模拟,企事业单位委托项目,在研;

[8]    变截面通道浮力驱动气-液两相流动与热质传递耦合机理,能源清洁利用国家重点实验室开放基金,已结题

[9]  进风预冷的空冷塔喷嘴布置和侧风的协同机理及最优匹配研究,山东省自然科学基金青年项目,已结题;

[10] 进风预冷的空冷塔喷嘴布置和塔内配风的协同机理研究,中国博士后科学基金第61批面上资助,已结题;

[11] 基于喷嘴与填料蒸发预冷原理的空冷塔增效机理研究,山东省博士后创新项目,已结题;

[12] 超大型高位收水冷却塔集水装置风阻特性的实验研究,企事业单位委托项目,已结题;

[13] 环境气象条件与进塔水温及水量对大型逆流式冷却塔热力特性的影响规律研究,企事业单位委托项目,已结题;

      参与:国家自然科学基金面上项目、国家自然科学基金青年项目、山东省重点研发计划等项目。

 

代表论文、著作、专利:

以第一/通讯作者发表论文40余篇,授权专利7项,参编教材1部,代表性成果如下:

[33]   Qi Zhang, Suoying He*, Tianyi Song, Mingwei Wang, Zhilan Liu, Jifang Zhao, Qi Gao, Xiang Huang, Kuihua Han, Jianhui Qi, Ming Gao, Yuetao Shi. Modeling of a PV system by a back-mounted spray cooling section for performance improvement. Applied Energy, 332 (2023) 120532.

[32]   Huimin Pang, Chunrong Zhao, Shen Cheng, Mingwei Wang, Qi Gao, Suoying He*, Gengsheng Sun, Guangxu Jiang, Qinggang Sun, Zhilan Liu, Zhe Geng, Shuzhen Zhang, Ming Gao. Investigation on feasible zone of nozzle spray for pre-cooling the inlet air of natural draft dry cooling tower. Thermal Science and Engineering Progress, 38 (2023) 101650.

[31]    Suoying He*, Yang Li, Mingwei Wang, Aiping Wang, Abdullah M. Alkhedhair, Hongjun Guan, Xuehong Wu, Yuetao Shi*, Ming Gao. Investigation on the control mechanism of spray pre-cooling the inlet air of natural draft dry cooling tower. Applied Thermal Engineering, 217 (2022) 119186.

[30]    Qi Zhang, Suoying He*, Jun Cheng, Bin Zhao, Xuehong Wu, Mingxuan Yan, Ming Gao, Zhe Geng, Shuzhen Zhang. Numerical simulation of evaporative cooling process in a medium-gap-medium arrangement. International Journal of Thermal Sciences, 179 (2022) 107700.

[29]    Mengfei Xu, Suoying He*, Jun Cheng, Ming Gao, Yuanshen Lu, Kamel Hooman, Yi Xu, Zhe Geng, Shuzhen Zhang. Investigation on heat exchanger arrangement in solar enhanced natural draft dry cooling towers under various crosswind conditions. Case Studies in Thermal Engineering, 28 (2021) 101505.

[28]    Jiayu Miao, Suoying He*, Yuanwei Lu, Yuting Wu, Xuehong Wu, Guanhong Zhang, Ming Gao, Zhe Geng, Shuzhen Zhang. Comparison on cooling performance of pre-cooled natural draft dry cooling towers using nozzles spray and wet medium. Case Studies in Thermal Engineering, 27 (2021) 101274.

[27]    Mingxuan Yan, Suoying He*, Na Li, Xiang Huang, Ming Gao, Mengfei Xu, Jiayu Miao, Yuanshen Lu, Kamel Hooman, Jianjun Che, Zhe Geng, Shuzhen Zhang. Experimental investigation on a novel arrangement of wet medium for evaporative cooling of air. International Journal of Refrigeration, 124 (2021) 64–74.

[26]    Mingxuan Yan, Suoying He*, Ming Gao, Mengfei Xu, Jiayu Miao, Xiang Huang, Kamel Hooman. Comparative study on the cooling performance of evaporative cooling systems using seawater and freshwater. International Journal of Refrigeration, 121 (2021) 23–32.

[25]    Zhiyu Zhang, Suoying He*, Mingxuan Yan, Ming Gao, Yuetao Shi, Yuanshen Lu, Jiayou Liu, Cong Guo. Numerical study on the performance of a two-nozzle spray cooling system under different conditions. International Journal of Thermal Sciences, 152 (2020) 106291.

[24]    S. He, F. Sabri, Kamel Hooman. Transient natural convection: scale analysis of dry cooling towers. Journal of Thermal Analysis and Calorimetry, 139 (2020) 2891−2897.

[23]    Suoying He*, Zhiyu Zhang, Ming Gao, Fengzhong Sun, Manuel Lucas, Kamel Hooman. Experimental study on the air-side flow resistance of different water collecting devices for wet cooling tower applications. Journal of Wind Engineering & Industrial Aerodynamics, 190 (2019) 53−60.

[22] Suoying He*, Guanhong Zhang, Ming Gao, Fengzhong Sun, Xiang Huang. Wind tunnel test on the flow resistance of U-type water collecting devices for natural draft wet cooling towers. Journal of Wind Engineering & Industrial Aerodynamics, 186 (2019) 234−240.

[21] Suoying He*, Yi Xu, Guanhong Zhang, Kamel Hooman, Ming Gao, Fengzhong Sun. Selection of wetted media for pre-cooling of air entering natural draft dry cooling towers. Applied Thermal Engineering, 114 (2016) 857−863.

[20] Suoying He*, Hal Gurgenci, Zhiqiang Guan, Kamel Hooman, Zheng Zou, Fengzhong Sun. Comparative study on the performance of natural draft dry, pre-cooled and wet cooling towers. Applied Thermal Engineering, 99 (2016) 103−113.

[19] Suoying He*, Hal Gurgenci, Zhiqiang Guan, Xiang Huang, Manuel Lucas. A review of wetted media with potential application in the pre-cooling of natural draft dry cooling towers. Renewable and Sustainable Energy Reviews, 44 (2015) 407−422.

[18] Suoying He*, Zhiqiang Guan, Hal Gurgenci, Kamel Hooman, Yuanshen Lu, Abdullah M.Alkhedhair. Experimental study of the application of two trickle media for inlet air pre-cooling of natural draft dry cooling towers. Energy Conversion and Management, 89 (2015) 644−654.

[17] Suoying He*, Zhiqiang Guan, Hal Gurgenci, Kamel Hooman, Yuanshen Lu, Abdullah M.Alkhedhair. Experimental study of film media used for evaporative pre-cooling of air. Energy Conversion and Management, 87 (2014) 874−884.

[16] Suoying He*, Zhiqiang Guan, Hal Gurgenci, Ingo Jahn, Yuanshen Lu, Abdullah M.Alkhedhair. Influence of ambient conditions and water flow on the performance of pre-cooled natural draft dry cooling towers. Applied Thermal Engineering, 66 (2014) 621−631.

[15] Suoying He*, Hal Gurgenci, Zhiqiang Guan, Abdullah M.Alkhedhair. Pre-cooling with Munters media to improve the performance of Natural Draft Dry Cooling Towers. Applied Thermal Engineering, 53 (2013) 67−77.

[14] 何锁盈, 孙奉仲*, 高明, 赵元宾. 基于填料蒸发预冷原理的自然通风干式冷却塔夏天运行效率的优化. 太阳能学报, 38 (11) (2017) 3022-3028.

[13] 刘严雪,何锁盈*,张治愚,闫明暄,王蕊,高明,孙奉仲. 双喷嘴布置间距对蒸发冷却性能影响的数值模拟. 中国电机工程学报, 40 (15) (2020) 4910-4918.

[12] 何锁盈*,王蕊,张治愚,闫明暄,刘严雪,高明. 蓄热层形状对太阳能增效空冷塔换热性能的影响研究. 天津大学学报(自然科学与工程技术版), 54 (4) (2021) 405-410.

[11] 赵斌,谭恒,何锁盈*,曲宏伟,白珍,周腊吾. 高原高寒地区光伏组件背板冷却对输出功率影响的实验研究. 太阳能学报, 43(8) (2022) 122-129.

[10] 何锁盈,苗佳雨,赵斌,吴学红,耿哲,酆烽,张淑贞,高明. 太阳能电池板自然通风冷却系统流动与传热的数值模拟. 中国电机工程学报, 2022.06.28网络首发.

[9] 何锁盈*,刘天天,张齐,苗佳雨,张志远,高明. 自然风冷与预喷淋冷却对光伏组件的冷却效果. 西安工程大学学报, 36(04) (2022) 1-9.

[8] 何锁盈*,高明,史月涛,徐梦菲,孙奉仲. 国际能源转型趋势下大学生节能减排创新训练新模式的探索. 西部素质教育,2020(4)197-198.

[7] 何锁盈*,高明,徐梦菲,苗佳雨. 新能源技术课程国际化建设的探索与思考. 高教学刊,2021年第1期,74-77.

[6] 何锁盈, 高明, 史月涛, 孙奉仲, 王妮妮, 赵元宾. 连续填料布置的干湿混合大型冷却塔、冷却系统及方法. 发明专利, 专利号:ZL201611233385.1.

[5] 何锁盈,张贯虹,高明, 史月涛, 孙奉仲. 一种填料双层布置的蒸发预冷进风空冷塔及其工作方法. 发明专利, 专利号:ZL201810617107.9.

[4] 何锁盈,张治愚, 史月涛, 高明, 孙奉仲. 一种喷嘴蒸发预冷的自然通风空冷塔及冷却方法. 发明专利, 专利号:ZL201810614093.5.

[3] 何锁盈, 李娜, 苗佳雨, 徐梦菲, 高明, 史月涛. 一种浮力驱动的光伏板预喷淋冷却系统及冷却方法, 发明专利, 专利号:ZL202010273281.3.

[2] 何锁盈,刘天天,高明, 史月涛. 一种双面进风间接蒸发冷却冷水机组及冷却系统. 实用新型专利,专利号:ZL202220912826.5.

[1] 黄翔,邵双全、吴学渊,何锁盈. 绿色数据中心高效适用制冷技术及应用. 北京:机械工业出版社,2021.05. 21世纪高等教育建筑环境与能源应用工程系列教材,ISBN978-7-111-68088-8.

 

招生信息:招收能源动力类、建环、环境及化工等专业背景的全日制和非全日制硕士研究生。

 

毕业生去向:浪潮、比亚迪、美的、海信、海尔、中广核、读博、出国留学等。

 

联系方式:

      E-mail: suoyinghe@hotmail.coms.he@sdu.edu.cn

      Tel: 0531-88399008

      Room: 东配楼415 (山东大学千佛山校区)

 

 

>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> 

Dr. Suoying He, PhD

Associate Professor at School of Energy and Power Engineering, Shandong University

Research Interests

Heat and mass transfer enhancement (Wet media/spray cooling, evaporative cooling R&D)

Cooling tower performance optimization (Dry/Wet/Hybrid cooling)

Low-carbon energy and new technologies for energy conservation (Solar PV/thermal system simulation and optimization, air source heat pump)

Qualifications

Doctor of Philosophy (Thermal Eng.), University of Queensland, 2011−2015

Bachelor of Engineering (HVAC Eng.), Central South University, 2006-2010

Available projects

(1) Design and optimization of nozzle spray cooling

(2) Flow field optimization of hybrid cooling towers

(3) Solar PV/thermal system simulation and optimization

Research Websites

Linkedin: www.linkedin.com/in/suoyinghe2015

ResearchGate: www.researchgate.net/profile/Suoying_He

Contact information

E-mail: suoyinghe@hotmail.com, s.he@sdu.edu.cn

Tel: 0531-88399008

Address: 17923 Jingshi Rd, Jinan 250061, P.R. China


Publication
Research direction

No contents

Papers

1. 王友昊. Numerical Analysis of Flow-Induced Vibration and Noise Generation in a Variable Cross-Section Channel .Fluid Dynamics & Materials Processing.2023 (19)

2. 杨继冲. Synergistic optimization of partition water distribution, non-equidistant fillings and dry-wet hybrid rain zone for wet cooling towers .Applied Thermal Engineering.2023 (231)

3. 王友昊. Numerical simulation on the enhancement of heat transfer performance by deflector plates for the mechanical draft cooling towers .Energy .2023 (283)

4. 王宇航. Dynamic analysis and control optimization of hydrogen supply for the proton exchange membrane fuel cell and metal hydride coupling system with a hydrogen buffer tank .Energy Conversion and Management.2023 (291)

5. 王友昊. Vibration characteristics and strength analysis of two-stage variable-pitch axial-flow fan based on fluid-solid coupling method .Energy .2023 (284)

6. 杨继冲. Influence of three different pitches fillings on the cooling performance of wet cooling towers under crosswind .Applied thermal engineering.2023,220

7. 吕斐然. Numerical simulation of structure-borne noise in a T-shaped tee considering fluid-structure interaction .PHYSICS OF FLUIDS.2023,35 (1)

8. 齐建荟. Design space analysis for supercritical CO2 radial inflow turbine stators .THERMAL SCIENCE AND ENGINEERING PROGRESS.2023,38

9. 杨岳鸣. Effect of CO2-based binary mixtures on the performance of radial-inflow turbines for the supercritical CO2 cycles .Energy .2023,266

10. 杨岳鸣. Effect of CO2-based Binary Mixtures on the Performance of Radial-Inflow Turbines for the Supercritical CO2 Cycles .ENERGY.2023,266 (1):126429

11. 冯慧敏. Influence of environmental parameters on the cold-end and thermal system of coal-fired power plant based on Ebsilon simulation .THERMAL SCIENCE AND ENGINEERING PROGRESS.2022 (32)

12. 吕斐然. Numerical simulation of structure-borne noise in a T-shaped tee considering fluid-structure interaction .PHYSICS OF FLUIDS.2023,35 (1)

13. 冯慧敏. Numerical simulation on thermal stratification performance in thermocline water storage tank with multi-stage middle perforated obstacles .THERMAL SCIENCE AND ENGINEERING PROGRESS.2022 (35)

14. 张慧颖. 质子交换膜燃料电池冷启动堆栈温度预测模型 .化工学报.2022 (2022)

15. 陈瑞. 侧风下填料非等片距布置对超大冷却塔性能影响的数值模拟 .中国电机工程学报.2022,42 (9)

16. 李浩天. Effect of inner-tube spacing on charging and discharging performance of latent energy storage heat exchangers .APPLIED THERMAL ENGINEERING.2022 (216)

17. 张政清. 超大型湿式冷却塔干湿混合雨区正交优化研究 .中国电机工程学报.2022 (2022)

18. 杨继冲. Influence of three different pitches fillings on the cooling performance of wet cooling towers under crosswind .Applied Thermal Engineering.2023 (119760)

19. 何锁盈. Investigation on the control mechanism of spray pre-cooling the inlet air of natural draft dry cooling tower .Applied thermal engineering.2022 (217)

20. 何锁盈. 自然风冷与预喷淋冷却对光伏组件的冷却效果 .西安工程大学学报.2022,36 (4):1

21. 张齐. Numerical simulation of evaporative cooling process in a medium-gap-medium arrangement .International Journal of Thermal Sciences.2022,179

22. 高明. Thermodynamic and exergy analysis of a novel PEMFC-ORC-MH combined integrated energy system .Energy Conversion and Management.2022 (264)

23. 高明. Effect of forced ventilation on the thermal performance of wet cooling towers .CASE STUDIES IN THERMAL ENGINEERING.2022 (35)

24. 高明. 侧风下分区配水对冷却塔性能的影响研究 .《热力发电》.2021 (1)

25. 郑智睿. Numerical simulation on influence of noise barrier on thermal performance for natural draft wet cooling towers .Case Studies in Thermal Engineering.2021,28

26. 李浩天. Simulation study on the effect of fins on the heat transfer performance of horizontal dual-inner-tube latent thermal energy storage heat exchangers .JOURNAL OF ENERGY STORAGE.2022,49

27. 王宇航. Simulation study on the PEMFC oxygen starvation based on the coupling algorithm of model predictive control and PID .Energy Conversion and Management.2021,249

28. 孙丽慧. Effect of the rotor blade installation angle on the structure-borne noise generated by adjustable-blade axial-flow fans .PHYSICS OF FLUIDS.2021,33 (9)

29. 张德英. Numerical simulation on synergetic optimization of non-equidistant fillings and non-uniform water distribution for wet cooling towers .INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER.2021,179

30. 王友昊. Research on noise reduction characteristic of sound barrier on natural draft wet cooling towers .《INTERNATIONAL JOURNAL OF REFRIGERATION-REVUE INTERNATIONALE DU FROID》.2022,133 :73

31. 张政清. Influences of dry-wet hybrid rain zone on the heat and mass transfer characteristics of wet cooling towers: A case study .Case Studies in Thermal Engineering.2022,30

32. 姜磊. Influence of noise barrier and louver on ventilation and thermal performance of wet cooling towers under crosswind conditions .国际热科学.2022,173

33. 闫明暄. Comparative study on the cooling performance of evaporative cooling systems using seawater and freshwater .《INTERNATIONAL JOURNAL OF REFRIGERATION-REVUE INTERNATIONALE DU FROID》.2021,121 :23

34. 何锁盈. 蓄热层形状对太阳能增效空冷塔换热性能的影响研究 .天津大学学报(自然科学与工程技术版).2021 (54):3022

35. 何锁盈. Experimental investigation on a novel arrangement of wet medium for evaporative cooling of air .《INTERNATIONAL JOURNAL OF REFRIGERATION-REVUE INTERNATIONALE DU FROID》.2021 (124):64

36. 何锁盈. Investigation on heat exchanger arrangement in solar enhanced natural draft dry cooling towers under various crosswind conditions . Case Studies in Thermal Engineering.2021 (28)

37. 苗佳雨. Comparison on cooling performance of pre-cooled natural draft dry cooling towers using nozzles spray and wet medium .CASE STUDIES IN THERMAL ENGINEERING.2021,27

38. 孙丽慧. Numerical simulation regarding flow-induced noise in variable cross-section pipelines based on large eddy simulations and Ffowcs Williams-Hawkings methods .2021,11 (6)

39. 陈瑞. Numerical study regarding cooling capacity for non-equidistant fillings in large-scale wet cooling towers .2021,26

40. 张德英. Crosswind influence on heat and mass transfer performance for wet cooling tower equipped with an axial fan .2021,27

41. 高明. An exploratory research on performance improvement of super-large natural draft wet cooling tower base d on the reconstructe d dry-wet hybrid rain zone, part 2 Crosswind effects .International journal of heat and mass transfer.2020 (160):1

42. 高明. The effect of engineering improvement on the cooling capacity in three zones of wet cooling towers .Heat Transfer Research.2020,51 (15)

43. 高明. 动叶可调轴流风机进出口气动噪声的数值模拟 .声学技术.2019,38 (5)

44. 高明. Numerical simulation on near-field aerodynamic noise of an adjustable-blade axial-flow fan .AIP Advances.2020,10 (9)

45. 高明. Theoretical calculation model and variable condition analysis research on the water splashing noise for natural draft wet cooling towers .NOISE CONTROL ENGINEERING JOURNAL.2020,68 (2)

46. 张治愚. Numerical study on the performance of a two-nozzle spray cooling system under different conditions .International Journal of Thermal Sciences.2020 (152)

47. 刘严雪. 双喷嘴布置间距对蒸发冷却性能影响的数值模拟 .《中国电机工程学报》.2020 (40):4910

48. 王蕊. Effect of Inlet Air Turbulence on the Cooling Performance of Solar Enhanced Dry Cooling Towers .2019

49. 何锁盈. Transient natural convection: scale analysis of dry cooling tower .Journal of Thermal Analysis and Calorimetry.2020 (139):2891

50. 高明. The effects of water droplet diameter distribution in the rain zone on the cooling capacity and water-splashing noise for natural draft wet cooling towers .International Journal of Thermal Sciences.2021 (164(2021))

51. 高明. Numerical Simulation of Axial Inflow Characteristics and Aerodynamic Noise in a Large-Scale Adjustable-Blade Fan .Fluid Dynamics and Materials Processing.2020 (16(3))

52. 高明. Numerical simulation on the three kinds of water droplet diameter treatments in rain zone of wet cooling towers .International journal of heat and mass transfer.2021 (170(2021))

53. 张政清. An exploratory research on performance improvement of super-large natural draft wet cooling tower based on the reconstructed dry-wet hybrid rain zone, part 2: Crosswind effects .International journal of heat and mass transfer.2020,160

54. 徐一丹. THE EFFECT OF ENGINEERING IMPROVEMENT ON THE COOLING CAPACITY IN THREE ZONES OF WET COOLING TOWERS .Heat Transfer Research.2020,51 (15):1429

55. 董晓明. Power transfer limit calculation for multi-area interconnected power networks .International Journal of Electrical Power and Energy Systems.2020,120

56. wangmengxia , Chengfu Wang  and Xiaoming Dong. Power transfer limit calculation for multi-area interconnected power networks .International Journal of Electrical Power and Energy Systems.2020 (120)

57. 陈曦. Optimal Operation of Integrated Energy System Considering Dynamic Heat-gas Characteristics and Uncertain Wind Power .Energy.2020,198 :1

58. 郭畅. The effect of blade outlet angle on the acoustic field distribution characteristics of a centrifugal pump based on Powell vortex sound theory .Applied Acoustics.2019,155 :297

59. 周扬. Case study: Theoretical calculation model and variable condition analysis research on the water-splashing noise for natural draft wet cooling towers .NOISE CONTROL ENGINEERING JOURNAL.2020,68 (2):137

60. 郭畅. A Review of the Flow-Induced Noise Study for Centrifugal Pumps .Applied Sciences.2020,10 (3)

61. 张政清. An exploratory research on performance improvement of super-large natural draft wet cooling tower based on the reconstructed dry-wet hybrid rain zone .International journal of heat and mass transfer.2019,142

62. hesuoying , sunfengzhong , gaoming  and 邹健. Field test on ventilation performance for high level water collecting wet cooling tower under crosswind conditions .Applied Thermal Engineering.2018,25 :439

63. gaoming , hesuoying , sunfengzhong  and 高明. Thermal performance analysis for high level water collecting wet cooling tower under crosswind conditions .Applied Thermal Engineering.2018,29 :568

64. hesuoying , gaoming  and sunfengzhong. Experimental study on the air-side flow resistance of different water collecting devices for wet cooling tower applications .Journal of Wind Engineering and Industrial Aerodynamics.2019 (190):53

65. hesuoying , sunfengzhong , gaoming  and zhaoyuanbin. 基于填料蒸发预冷原理的自然通风干式冷却塔夏天运行效率的优化 .《太阳能学报》.2017,38 (44):3022

66. hesuoying  and sunfengzhong. The inlet air pre-cooling of natural draft dry cooling towers-wetted medium issue .2017

67. hesuoying  and gaoming. Selection of wetted media for pre-cooling of air entering natural draft dry cooling towers .Applied thermal engineering.2017 (114):857

68. gaoming , shiyuetao , hesuoying  and 高明. Numerical Simulation on Heat Transfer Performance Enhancement of Cooling Water Jacket used in Carbon Industry .Journal of Enhanced Heat Transfer.2019,26 (3):235

69. hesuoying  and Xiaoxiao Li. Simulation of the UQ Gatton natural draft dry cooling tower .Applied thermal engineering.2016

70. gaoming , hesuoying , sunfengzhong  and 高明. Experimental study on the drag characteristic and thermal performance of non-uniform fillings for wet cooling towers under crosswind conditions .Applied thermal engineering.2018

71. hesuoying  and 张贯虹. Economic Analyses of Natural Draft Dry Cooling Towers Pre-cooled Using Wetted Media .10TH INTERNATIONAL SYMPOSIUM ON HEATING, VENTILATION AND AIR CONDITIONING, ISHVAC2017.2017,205 :423

72. hesuoying  and Lu, Wanpeng. Energy Conservation Analysis and System Optimization of Extended Air Preheater .10TH INTERNATIONAL SYMPOSIUM ON HEATING, VENTILATION AND AIR CONDITIONING, ISHVAC2017.2017,205 :3903

73. hesuoying , sunfengzhong , gaoming  and 邹健. Field test on ventilation performance for high level water collecting wet cooling tower under crosswind conditions .Applied thermal engineering.2018,133 :439

74. gaoming , hesuoying , sunfengzhong  and 高明. Thermal performance analysis for high level water collecting wet cooling tower under crosswind conditions .Applied thermal engineering.2018,136 :568

75. Chengfu Wang , zhangfeng , hesuoying  and Xiaoming Dong. Optimal sizing of energy storage considering the spatial-temporal correlation of wind power forecast errors .IET RENEWABLE POWER GENERATION.2019,13 (4):530

76. hesuoying  and sunfengzhong. Comparative study on the performance of natural draft dry, pre-cooled and wet cooling towers .Applied thermal engineering.2016,99 :103

77. hesuoying  and Xiaoxiao Li. Simulation of the UQ Gatton natural draft dry cooling tower .Applied thermal engineering.2016

78. hesuoying. 基于填料蒸发预冷原理的自然通风干式冷却塔天运行效率的优化 .《太阳能学报》.2017,38 (11):3022

79. Chengfu Wang , Yang Ming , hesuoying , Xiaoming Dong  and liangjun. Impact of Power-to-Gas Cost Characteristics on Power-Gas-Heating Integrated System Scheduling .IEEE Access .2019,7 :17654

80. hesuoying , gaoming  and sunfengzhong. Wind tunnel test on the flow resistance of U-type water collecting devices for natural draft wet cooling towers .Journal of Wind Engineering and Industrial Aerodynamics.2019,186 :234

81. gaoming , hesuoying , sunfengzhong  and 周扬. Experimental study on the drag characteristic and non-uniform fillings for wet cooling towers under thermal performance of crosswind conditions .Applied thermal engineering.2018,140 :398

82. hesuoying  and Xiaoxiao Li. Simulation of the UQ Gatton natural draft dry cooling tower .Applied thermal engineering.2016

83. zhangfeng , hesuoying , Xiaoming Dong  and Chengfu Wang. Optimal sizing of energy storage considering the spatial-temporal correlation of wind power forecast errors .IET RENEWABLE POWER GENERATION.2019,13 (4):530

84. Yang Ming , hesuoying , Xiaoming Dong , liangjun  and Chengfu Wang. Impact of Power-to-Gas Cost Characteristics on Power-Gas-Heating Integrated System Scheduling .IEEE Access .2019,7 :17654

85. gaoming , sunfengzhong  and hesuoying. Wind tunnel test on the flow resistance of U-type water collecting devices for natural draft wet cooling towers .Journal of Wind Engineering and Industrial Aerodynamics.2019,186 :234

86. gaoming , hesuoying , sunfengzhong  and 周扬. Experimental study on the drag characteristic and non-uniform fillings for wet cooling towers under thermal performance of crosswind conditions .Applied thermal engineering.2018,140 :398

87. hesuoying , sunfengzhong  and 高明. Experimental study on the drag characteristic and thermal performance of non-uniform fillings for wet cooling towers under crosswind conditions .Applied thermal engineering.2018

88. hesuoying , sunfengzhong  and 高明. Thermal performance analysis for high level water collecting wet cooling tower under crosswind conditions .Applied thermal engineering.2018,136 :568

89. hesuoying  and 张贯虹. Economic Analyses of Natural Draft Dry Cooling Towers Pre-cooled Using Wetted Media .10TH INTERNATIONAL SYMPOSIUM ON HEATING, VENTILATION AND AIR CONDITIONING, ISHVAC2017.2017,205 :423

90. hesuoying  and Xiaoxiao Li. Simulation of the UQ Gatton natural draft dry cooling tower .Applied thermal engineering.2016

91. hesuoying  and Lu, Wanpeng. Energy Conservation Analysis and System Optimization of Extended Air Preheater .10TH INTERNATIONAL SYMPOSIUM ON HEATING, VENTILATION AND AIR CONDITIONING, ISHVAC2017.2017,205 :3903

92. hesuoying , sunfengzhong , gaoming  and 邹健. Field test on ventilation performance for high level water collecting wet cooling tower under crosswind conditions .Applied thermal engineering.2018,133 :439

93. sunfengzhong  and hesuoying. Comparative study on the performance of natural draft dry, pre-cooled and wet cooling towers .Applied thermal engineering.2016,99 :103

94. hesuoying. 基于填料蒸发预冷原理的自然通风干式冷却塔天运行效率的优化 .《太阳能学报》.2017,38 (11):3022

Patens

1. 一种用于CFD仿真大压比径流式透平跨音速定叶喷管的计算网格自动生成方法及生成器

2. 一种内管可移动的新型管壳式相变储热装置及工作方法

3. 煤富氧燃烧下超临界CO2再压缩布雷顿循环耦合碳捕集新型组合系统及仿真方法

4. 一种利用太阳能的燃料电池冷启动和保温系统及方法

5. 一种带有防风板与进风喷淋的自然通风空冷塔

6. 一种基于相变储热的金属氢化物储氢罐及固-气耦合储氢系统

7. 一种基于间接蒸发冷却填料预冷进风的闭式冷却塔

8. 一种双面进风间接蒸发冷却冷水机组及冷却系统

9. 一种基于有机朗肯循环的燃料电池余热发电系统

10. 一种基于氢气蒸发气的燃料电池余热发电系统

11. 一种光伏板冷却系统

12. 利用雨区淋水势能调节干区覆盖面积的干湿雨区冷却塔

13. 一种流固耦合作用下轴流风机噪声仿真预测方法及装置

14. 一种主动式调节干区覆盖面积的超大型干湿雨区冷却塔

15. 一种基于燃料电池的热电耦合节能与储能系统和方法

16. 一种浮力驱动的光伏板预喷淋冷却系统及冷却方法

17. 一种湿式冷却塔塔内性能参数监测系统及其方法

18. 一种高位集水冷却塔收水装置阻力特性的在线监测系统

19. 一种高位集水冷却塔热力性能在线监测系统

20. 高位集水冷却塔的塔内性能参数采集测点布设及测试方法

21. 一种二氧化碳和乳酸菌独立发生器及便携蚊虫捕杀装置

22. 201826277 基于蚊子生理生化特性的新型高效便携除蚊杯

23. 一种雨区采用干湿混合冷却模式的超大型湿式冷却塔

24. 201826277 基于蚊子生理生化特性的新型高效便携除蚊杯

25. 一种离心泵流动噪声的测量方法

26. 一种自然通风的湿干联合冷却塔

27. 花瓣状填料布置的干湿混合大型冷却塔、冷却系统及方法

Research project

1. 光伏-空气源热泵互补的近零排放供能系统关键技术研发, 2024/03/01-2025/12/31

2. 集中供热管网水力仿真与优化调控策略研发, 2024/03/01-2027/01/30

3. 基于相变储热的固态储氢系统研发, 2023/12/01-2025/12/31

4. 燃机电站职工技能提升体系研究与应用, 2023/10/25-2023/12/31

5. 轮胎硫化装备传热过程的数值仿真程序开发, 2023/08/01-2024/12/31

6. 高效干湿联合一体式换热站节水增效关键技术研究, 2023/07/01-2025/07/31

7. 大型湿式冷却塔性能优化的热态模型实验及现场测试, 2022/12/23-2025/01/31

8. 人工智能辅助锅炉尾部设备空气预热器系统的智能分析指导系统研究, 2022/10/20-2023/12/31

9. (包干项目)太阳能光伏板干湿联合冷却过程的能质传递强化机理研究, 2022/11/01-2025/12/30

10. 智慧城市供热大脑关键技术研发, 2022/11/01-2024/11/30

11. 基于发电厂余汽、裕汽降低厂用电率的仿真研究, 2022/06/14-2024/12/31

12. 闭式冷却塔节能增效关键技术研究, 2022/10/01-2023/10/31

13. 云南省工业节能减碳和增强特色经济林木碳汇能力的路径与对策研究, 2021/10/01-2023/03/01

14. 高效干湿联合一体式换热站节水增效关键技术研究, 2022/08/18-2025/07/31

15. 新型轮胎硫化装备的热量传递关键技术研究, 2022/08/22-2024/07/31

16. (包干项目)应用于废气再循环系统的泡沫金属换热器污垢沉积的建模及减缓机理的研究, 2021/12/23-2024/12/31

17. 山东海科新源材料科技股份有限公司能耗核查, 2021/10/15-2022/12/31

18. 《智慧空气源热泵系统仿真模拟》, 2021/12/01-2023/06/30

19. 山东海科新源材料科技股份有限公司能耗核查和能效诊断报告, 2021/10/15-2022/12/31

20. 火电机组余热利用系统经济性优化技术研究, 2021/01/15-2022/12/31

21. 姜秸秆干燥及高值化利用关键技术, 2021/07/13-2024/06/20

22. 大型湿式冷却塔填料优化布置的数值模拟, 2021/01/01-2022/12/31

23. 锅炉烟风余热综合利用系统设计及节能技术服务, 2021/03/03-2022/12/31

24. 高位收水、节水除雾及噪声防治一体化的机力通风冷却塔数模物模试验研究, 2021/02/24-2023/02/24

25. 火电机组余热利用系统经济性评价通用准则及优化技术研究, 2021/01/15-2022/12/31

26. 火电厂风机及烟风道的流场、噪音的模拟与计算, 2020/07/30-2021/10/30

27. 热电机组供热经济性的变工况分析, 2019/10/25-2020/10/24

28. 联机供热Ebsilon软件建模与计算分析, 2019/10/25-2020/10/24

29. 胜利发电厂多工况供热运行方式经济性核算, 2019/10/25-2020/10/24

30. 基于雨区干湿混合冷却的超大型湿式冷却塔高效节能技术研发, 2019/07/08-2021/12/31

31. 侧风下超大型湿式冷却塔利用雨区淋水势能增效的机理研究, 2016/10/29-2019/06/30

32. 高位集水大型冷却塔的三维热态物模试验及实塔三维热力性能测试与验证(一), 2016/01/01-2019/01/31

33. 环境风中冷却三角单元空气流场的多尺度演化及其气侧传热强化机制, 2016/08/17-2019/12/31

34. 课题分账:高位集水大型冷却塔的三维热态物模试验及实塔三维热力性能测试与验证(三), 2016/01/01-2019/01/31

35. 进风预冷的空冷塔喷嘴布置和侧风的协同机理及最优匹配研究, 2017/08/01-2019/12/31

36. 课题分账:大型逆流式冷却塔环境风干扰效应的三维模式试验及实塔三维热力性能测试(四), 2016/09/22-2018/12/31

37. 课题分账:高位集水大型冷却塔的三维热态物模试验及实塔三维热力性能测试与验证(四), 2016/01/01-2019/01/31

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