CN
EN
王馨
电话:86-10-62796113
传真:86-10-62773461
E-mail:wangxinlj@tsinghua.edu.cn

【研究方向】

建筑热工

零碳建筑

可再生能源利用

 

【教育经历】

1996.09-2001.05  东南大学 动力工程系 热能工程专业 博士(直博)

1992.09-1996.07  东南大学 动力工程系 热能工程专业 学士

 

【工作履历】

副研究员(2004.12-今),清华大学建筑技术科学系

欧盟玛丽居里学者 (2014.08-2016.08),英国诺丁汉大学建筑与建成环境系

讲师(2003.06-2004.12),清华大学建筑技术科学系

博士后(2001.05-2003.05),清华大学建筑技术科学系

 

【科研项目】

1)   国家自然科学基金面上项目,基于平板重力热管相变房的耦合传热机理与协同匹配方法研究(52278113),2023-2026主持

2)   十三五国家重点研发项目子课题,近零能耗建筑基础性理论研究 (2017YFC0702601),2017-2021主持

3)   十三五国家重点研发项目子课题,系统主动调控与协调集成原理与方法(2016YFB0901405), 2016-2021主持

4)   国家自然科学基金面上项目, 建筑天然气分布式供能系统相变蓄能调控机理与耦合关联机制研究(51376098),2014-2017主持

5)   欧盟第七框架玛丽居里项目,低碳建筑太阳能集热与PCM围护结构研究, 2014-2016 中方主持

6)   十二五国家科技支撑项目子课题,高原气候适应性节能建筑关键技术研究与示范(2013BAJ03B04),2013-2015主持

7)   国家自然科学基金青年基金项目,基于理想节能建筑围护结构非线性热容传热反问题研究(50906045),2010-2012主持

8)   十一五国家科技支撑重点项目课题,新型建筑室内热湿负荷调节系统研究(2006BAA04B02),2006-2010主持

9)   十一五国家科技支撑项目子课题,建筑室内热湿环境改善材料开发 (2006BAJ02A09-5),2006-2010主持

10)  国家自然科学基金重点项目子课题,潜热型功能热流体制备调控方法与强化传热机理研究(50436020), 2005-2008主持

 

【荣誉和获奖】

1)   教育部新世纪优秀人才,2009

2)   欧盟第七框架玛丽居里项目(引进人才计划) 奖学金,2014-2016

3)   相变储能应用基础研究,教育部自然科学二等奖,4/11,2005

4)   青藏高原气候适应性节能建筑关键技术研究,四川省科技进步一等奖,6/9,2011

5)   可再生能源蓄能技术在低能耗建筑的应用研究,建设部华夏科学技术二等奖, 5/12,2015

6)   太阳能-相变蓄热结合用于建筑节能的关键问题研究,河北省自然科学二等奖,5/5,2017

7)   Applied Energy、Renewable and Sustainable Energy Reviews、Energy and Buildings, Energy and Environment、Applied Thermal Engineering等国际期刊杰出审稿人

8)   清华大学优秀班主任二等奖,2017

9)   清华大学优秀党支部书记,2017

10) 清华大学先进工作者,2021

 

【学术任职】

1)  SCI国际期刊Indoor and Built Environment编委

2)  中文核心期刊 《太阳能学报》编委

3)  中文核心期刊 《储能科学与技术》编委

 

【著作与论文】

1)      Xin Wang, Rui Yang, Saffa Riffat. Renewable Energy and Sustainable Technologies for Building and Environmental Applications,Chapter 1: Inverse Problem for Phase Change Materials and Preparation in Building Envelope, Springer International Publishing AG, 2016, 1-24.

2)      张兴祥、王馨、吴文健,相变材料胶囊制备与应用,化学工业出版社,2009

3)      张寅平、潘毅群、王馨,专业英语阅读与写作,中国建筑工业出版社,2005

4)      Fangcheng Kou, Qipeng Gong, Yu Zou, Jinhan Mo, Xin Wang*, Solar application potential and thermal property optimization of building integrated heat pipes, Energy and Buildings  2023, 279, 112688

5)      Fangcheng Kou, Shaohang Shi, Ning Zhu, Yehao Song, Yu Zou, Jinhan Mo, Xin Wang*. Improving the indoor thermal environment in lightweight buildings in winter by passive solar heating: An experimental study, Indoor and Built Environment, 2022, 31:2257-2273.

6)      He Yi, Kou Fangcheng, Wang Xin, Zhu Ning, Song Yehao, Chu Yingnan, Shi Shaohang, Liu Mengjia, Chen Xinxing. Hybrid model combining multivariate regression and machine learning for rapid predicting interior temperature affected by thermal diode and solar cavity, Building and Environment, 2022, 211, 108723

7)      Qipeng Gong, Fangcheng Kou, Xiaoyu Sun, Yu Zou, Jinhan Mo, Xin Wang*. Towards zero energy buildings: a novel passive solar house integrated with flat gravity-assisted heat pipes, Applied Energy, 2022, 306 (A), 117981

8)      Ling Xu, Linchuan Dai, Linzhi Yin, Xiaoyu Sun, Wei Xu, Rui Yang*, Xin Wang*, Yinping Zhang. Research on the climate response of variable thermo-physical property building envelopes: A literature review. Energy and Buildings, 2020, 226 (11): 1-22.

9)      Pengfei Si, Yuexia Lv, Xiangyang Rong*, Lijun Shi, Jinyue Yan, Xin Wang*. An innovative building envelope with variable thermal performance for passive heating systems. Applied Energy, 2020, 269 (7): 1-11.

10)    Zhang Yin , Zhang Yinping, Wang Xin, Inverse problem method to optimize cascade heat exchange network in central heating system, International Journal of Energy Optimization and Engineering, 2020, 9(3): 62-82.

11)    Zhang Yin, Wang Xin*, Zhang Yinping, Optimal phase change temperature for building cooling heating and power system with PCM-TES based on energy storage effectiveness, Thermal Science, 2019, 23 (2):1085-1093

12)    Xin Wang*, Xiaoyu Sun, Chuck W. F. Yu. Building envelope with variable thermal performance: Opportunities and challenges, Indoor and Built Environment, 2018, 27(6), 729-733.

13)    Zhang Yin, Wang Xin, Wei Zhiyuan, Zhang Yinping, Feng Ya, Sodium acetate–urea composite phase change material used in building envelopes for thermal insulation, Building Services Engineering Research and Technology, 2018, 39(4), 475-491.

14)    ZhangYin, Wang Xin, Hu E, Optimization of night mechanical ventilation strategy in summer for cooling energy saving based on inverse problem method, Proceedings of the Institution of Mechanical Engineers Part A-Journal of Power and Energy, 2018, 232(8), 1093-1102.  

15)    Zhang Y, Si PF, Feng Y, Rong XY, Wang X*, Zhang YP. Operation strategy optimization of BCHP system with thermal energy storage: a case study for airport terminal in Qingdao, China. Energy and Buildings, 2017,154, 465–478

16)    Zhang Y, Zhang YP, Shi WX, Wang X. Application of concept of heat adaptor: Determining an ideal central heating system using industrial waste heat. Applied Thermal Engineering, 2017, 111, 1387-1393

17)    Zhang Y, Wei ZY, Zhang YP, Wang X, Inverse problem and variation method to optimize cascade heat exchange network in central heating system, Journal of Thermal Science, 2017, 26 (6), 545-551

18)    Zhang Y, Wang X*, Zhang YP, Zhuo SW. A simplified model to study the location impact of latent thermal energy storage in building cooling heating and power system. Energy, 2016, 114: 885-894.

19)    Zhang Y, Wang X*, Zhuo SW, Zhang YP. Pre-feasibility of building cooling heating and power system with thermal energy storage considering energy supply-demand mismatch. Applied Energy, 2016, 167: 125-134.

20)    Zhang YP, Zhang Y, Shi WX, Shang R, Cheng R, Wang X. A new approach, based on the inverse problem and variation method, for solving building energy and environment problems: Preliminary study and illustrative examples. Building and Environment, 2015, 91, 204-218

21)    Hua J, Fan HM, Wang X, Zhang YP. A novel concept to determine the optimal heating mode of residential rooms based on the inverse problem method, Building and Environment, 2015, 85, 73-84.

22)    Ma T, Y HX, Zhang YP, Lu L, Wang X. Using phase change materials in photovoltaic systems for thermal regulation and electrical efficiency improvement: A review and outlook, Renewable and Sustainable Energy Reviews,2015, 43, 1273–1284

23)    Wang X, Cheng R, Zeng RL, Zhang YP. Ideal thermal physical properties of building wall in an active room, Indoor and Built Environment, 2014, 23(6), 839–853     

24)    Teng XG, Wang X*, Chen YL, Shi WX. A simple method to determine the optimal gas turbine capacity and operating strategy in building cooling, heating and power system, Energy and Buildings, 2014, 80, 623-630  

25)    Cheng R, Wang X, Zhang YP. Analytical optimization of the transient thermal performance of building wall by using thermal impedance based on thermal-electric analogy, Energy and Buildings, 2014, 80, 598-612

26)    Cheng R, Wang X, Zhang YP, Energy-efficient building envelopes with phase-change materials: new understanding and related research, Heat Transfer Engineering, 2014,35(11–12):970-984.

27)    Zhang Y, Chen Q, Zhang YP, Wang X. Exploring building’s secrets: the ideal thermophysical properties of a building’s wall for energy conservation, International Journal of Heat and Mass Transfer, 2013, 65, 265-273.

28)    Zhang Y, Zhang YP, Wang X, Chen Q. Ideal thermal conductivity of a passive Building wall: Determination method and understanding, Applied Energy, 2013,112, 967-974.

29)    Cheng R, Pomianowski M, Wang X*, Heiselberg P, Zhang YP. A new method to determine thermophysical properties of PCM-concrete brick, Applied Energy, 2013, 112, 988-998.

30)    Jiang F, Wang X*, Zhang YP. Analytical optimization of specific heat for building internal envelope, Energy Conversion and Management, 2012, 63, 239–244.

31)    Jiang F, Wang X*, Zhang YP. A new method to estimate optimal phase change material characteristic in a passive solar room, Energy Conversion and Management, 2011,52, 2437–2441.

32)    Zeng RL, Wang X, Di HF, Jiang F, Zhang YP. New concepts and approach for developing energy efficient buildings: Ideal specific heat for building internal thermal mass, Energy and Buildings, 2011, 43, 1081–1090. 

33)    Zhou GB, Yang YP, Wang X, Cheng JM. Thermal characteristics of shape-stabilized phase change material wallboard with periodical outside temperature waves. Applied Energy, 2010, 87(8), 2666-2672. 

34)    Wang X, Zhang YP, Xiao W, Zeng RL, Zhang QL, Di HF. Review on thermal performance of phase change energy storage building envelope, Chinese Science Bulletin, 2009, 54(6), 920-928.

35)    Zeng RL, Wang X*, Chen BJ, Zhang YP, Niu JL, Di HF. Heat transfer characteristics of microencapsulated phase change material slurry in laminar flow under constant heat flux, Applied Energy, 2009, 86(12), 2661-2670.

36)    Xiao W, Wang X*, Zhang YP. Analytical optimization of interior PCM for energy storage in a lightweight passive solar room, Applied Energy, 2009, 86 (10), 2013-2018.

37)    Yang R, Zhang Y, Wang X, Zhang YP, Zhang QW. Preparation of n-tetradecane-containing microcapsules with different shell materials by phase separation method, Solar Energy Materials and Solar Cells, 2009, 93, 1817-1822.

38)    Zhou GB, Yang YP, Wang X, Zhou SX. Numerical analysis of effect of shape-stabilized phase change material plates in a building combined with night ventilation. Applied Energy, 2009, 86(1), 52-59.

39)    Wang Y, Guo BH, Wan X, Xu J, Wang X, Zhang YP. Janus-like polymer particles prepared via internal phase separation from emulsified polymer/oil droplets, Polymer, 2009, 50, 3361-3369.

40)    Xu J, Wan X, Zhang BQ, Wang Y, Guo BH, Zhang YP, Wang X. Preparation of phase change material wax/p(MMA-co-AA) core-shell microcapsules, Acta Polymerica Sinica, 2009. 20(11), 1154-1156. 

41)    Chen BJ, Wang X*, Zeng RL, Zhang YP, Wang XC, Niu JL, Li Y, Di HF. An experimental study of convective heat transfer with microencapsulated phase change material suspension: laminar flow in a circular tube under constant heat flux, Experimental Thermal and Fluid Science, 2008, 32, 1638-1646.

42)    Wang XC, Niu JL, Li Y, Zhang YP, Wang X, Chen BJ, Zeng RL, Song QW. Heat transfer of microencapsulated PCM slurry flow in a circular tube, AIChE Journal, 2008, 54(4), 1110-1120.

43)    Zhou GB, Zhang YP, Wang X, Lin KP, Xiao W. An assessment of mixed type PCM-gypsum and shape-stabilized PCM plates in a building for passive solar heating, Solar Energy, 2007, 84(10), 1351-1360.

44)    Wang XC, Niu JL, Li Y, Wang X, Chen BJ, Zeng RL, Song QW, Zhang YP. Flow and heat transfer behaviors of phase change material slurries in a horizontal circular tube, International Journal of Heat and Mass Transfer, 2007, 50, 2480-2491.

45)    Wang X, Liu J, Zhang YP, Di HF, Jiang Y. Experimental research on a kind of novel high-temperature phase change storage heater, Energy Conversion and Management, 2006, 47, 2211-2222.

46)    Chen BJ, Wang X*, Zhang YP, Xu H, Yang R. Experimental research on laminar flow performance of phase change emulsion. Applied Thermal Engineering, 2006, 26(11-12), 1238-1245.

47)    Zhang YP, Ding JH, Wang X, Yang R, Lin KP. Influence of additives on thermal conductivity of shape-stabilized phase change material, Solar Energy Materials and Solar Cells, 2006, 90(11), 1692-1702.

48)    Xu H, Yang R, Zhang YP, Huang Z, Lin J, Wang X. Thermal physical properties and key influence factors of phase change emulsion, Chinese Science Bulletin, 2005, 50(1), 88-93.

49)    Wang X, Zhang YP, Hu XX. Turbulent heat transfer enhancement of microencapsulated phase change material slurries with constant wall heat flux, Journal of Enhanced Heat Transfer, 2004, 11(1), 13-22.

50)    Shi MH, Wang X. Investigation on moisture transfer mechanism in porous media during rapid drying process, Drying Technology, 2004, 22(1-2), 111-122.

51)    Zhang YP, Hu XX, Wang X. Theoretical analysis of convection heat transfer enhancement of microencapsulated phase change material slurries, Heat and Mass Transfer, 2003, 40 (1-2), 59-66.

52)    Zhang YP, Hu XX, Hao Q, Wang X. Convective heat transfer enhancement of laminar flow of latent functionally thermal fluid in a circular tube with constant heat flux: internal heat source model and its application, Science in China, 2003, 46(2),131-140.

53)    Wang X, Zhang YP. Solid-liquid phase change heat transfer enhancement analysis in cylindrical and spherical walls,Journal of Enhanced Heat Transfer, 2002, 9(3), 109-115.

54)    Zhang YP, Wang X. Analysis of solid-liquid phase change heat transfer enhancement, Science in China, 2002, 45(6), 569-575.

 

【标准】

《建筑墙体热阻现场快速测试方法标准》T/CECS 857-2021,主编

《蓄热型电加热装置》GB/T 39288-2020,参编

《无内置热源相变蓄热装置》T/CECS 10023-2019,参编

《建筑用相变材料热可靠性测试方法》JG/T 534-2018,参编

《建筑材料吸放湿性能测试方法》JC/T 2002-2009,参编

《建筑门窗玻璃幕墙热工计算规程》JGJ/T 151-2008,参编

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