学习工作简历:
2005年9月-2009年7月,北京科技大学建筑环境与设备工程专业,学士
2009年9月-2014年7月,清华大学供热供燃气通风及空调工程专业,博士
2014年7月-2018年7月,北京科技大学土木与资源工程学院,讲师
2016年3月-2017年3月,马里兰大学(帕克分校),访问学者
2018年7月-2023年7月,北京科技大学土木与资源工程学院,副教授
2023年7月-至今,北京科技大学土木与资源工程学院,教授
主讲课程:
1.高等传热传质学(研究生专业必修课,32学时)
2.温湿度独立控制空调系统(本科生专业选修课,32学时)
个人荣誉
[1]北京制冷学会“2022-2024年度青年人才托举工程”被托举人
[2]北京科技大学“北科青年学者”
[3]北京科技大学第22届“我爱我师”称号
[4]北京科技大学第23届“我爱我师”称号
[5]第12届青年教师教学基本功比赛校三等奖
[6]2021-2023年3次获得“优秀硕士学位论文指导老师”
近五年主持和参与的科研项目
[1]企业科技项目,数据中心基础设施数据处理与分析关键技术研究(2021-0152),2021.10-2024.3,主持,结题。
[2]北京市自然科学基金面上项目,数据驱动的动态环境下中央空调系统负荷预测与智能调控(4212040),2021.01~2023.12,主要参与者,结题。
[3]国家自然科学基金青年项目,吸附式除湿装置温湿度场分布对其驱动温度影响机制研究(51706015),2018.1-2020.12,主持,结题。
[4]青年教师学科交叉研究培育项目, 知识和数据混合驱动下既有办公建筑空调系统的负荷动态预测与智能优化运行(FRF-IDRY-19-015),2020.01-2021.12,主持,结题。
[5]中央高校基本科研业务费项目, 固体吸附式空气取水流程关键技术研究(FRF-TP-18-014A3),2019.01-2020.12,主持,结题。
[6]中央高校基本科研业务费项目, 吸附同冷凝结合的太阳能驱动空气取水装置关键技术研究(FRF-GF-17-B35),2017.11-2018.12,主持,结题。
近五年内代表性学术成果
1.授权发明专利:
[1]涂壤,王璐,王朋飞.回收数据中心余热用于建筑采暖的系统设计参数优化方法, ZL 2024 1 0681804.6.
[2] 涂壤,王璐.一种冰箱湿度控制装置及方法,ZL202311771410.1.
[3] Rang Tu,Xu Yang,Xianzhong Chen,Jingjing Gao. HEATING DEVICE,美国,US011713887B2.
[4] 涂壤,张乔鑫.一种数据中心分布式精密空调机组优化运行参数估计方法, ZL202311322907.5.
[5]涂壤,葛羽瑶,陈贤忠.多末端供需匹配的数据中心冷源系统参数优化方法及装置, ZL202311311951.6.
[6]涂壤,马飞.多级转轮和制冷装置结合的空气取水装置及方法, ZL201710711661.9.
[7]涂壤,张乔鑫.一种基于动态负荷预测的电动汽车空调系统及控制方法,ZL202210833599.1.
[8] 涂壤,刘兰斌.一种锅炉烟气全热深度回收装置,ZL202210414069.3.(已转化)
[9] 涂壤,杨旭,陈贤忠,高晶晶.一种采暖装置, ZL202111496433.7.(已转化)
[10]涂壤,马飞.一种磁制冷和转轮除湿结合的温湿度独立控制空调系统, ZL201910426418.1.
2.主编专著:
[1].涂壤;刘兰斌.数据中心冷却系统智能运行与调控[M].北京,中国建筑工业出版社,2025.
[2] Rang Tu(涂壤); Lanbin Liu(刘兰斌).Atmospheric Water Harvesting System Assisted by Desiccant Wheels [M].(转轮辅助空气冷却取水技术).冶金工业出版社,2024.
[3] Rang Tu(涂壤); Lanbin Liu(刘兰斌).Dehumidification Technologies Using Desiccant Wheels[M].(转轮除湿技术).冶金工业出版社,2023.
3. 第一/通讯作者论文:
(1)数据中心冷却系统运行优化
[1] L.B. Liu , K. Li, R. Tu*, X. Yang. Optimal operation and cluster control of a centralised water-cooling system applied to data centre[J]. Applied Thermal Engineering, 2025, 280:128379.
[2] R. Tu, L. Wang, L.B. Liu*, X. Yang. Performance Analyses and Optimization Design of a Heat Recovery System Used Between Data Centers and Centralized Heating Systems [J]. Building Simulation,2025,18(10): 2559-2576.
[3]Rang Tu, Yuyao Ge, Xiaomin Chang, Lanbin Liu *, Xu Yang. Heat dissipation performances and optimized operation analyses of computational room air conditioners applied in data centers[J].Applied Thermal Engineering,2025,279(PA):127518-127518.
[4]Rang Tu, Yuyao Ge, Xiaomin Chang, Lanbin Liu *, Xu Yang. Performance Analyses of a novel operation strategy for data Centre’s centralized Water-Cooling system to match personalized cooling demands[J].Applied Thermal Engineering,2025,273126553-126553.
[5]R. Tu, L. Wang, L.B. Liu*. Performance and configuration optimization for a Grid-Connected PV power supply system with Demand-Supply matching in a data center’s centralized Water-Cooling system [J]. Solar Energy 276 (2024) 112667.
[6]Q.X. Zhang, R. Tu*, X. Yang. Optimization operation of data Center’s distributed air conditioning system based on supply-demand matching [J]. Energy 306 (2024) 132575.
[7]X.Z. Chen, R. Tu*, X. Yang. Parameter prediction optimization of data center’s heat dissipation system using machine learning algorithms [J]. Applied Thermal Engineering 232 (2023) 121047.
[8]X.Z. Chen, R. Tu*, M. Li, X. Yang, Kun Jia. Hot Spot Temperature Prediction and Operating Parameter Estimation of Racks in Data Center Using Machine Learning Algorithms Based on Simulation Data [J]. Building Simulation, 2023. DOI:10.1007/s12273-023-1022-4.
[9]S.Q. Wang, R. Tu*, X.Z. Chen, X. Yang, K. Jia, Thermal performance analyses and optimization of data center centralized-cooling system [J]. Applied Thermal Engineering, 2023 (222): 119817.
[10]王朋飞,葛羽瑶,涂壤*.三种数据中心机房精密空调送风参数预测方法及结果分析[J].建筑科学,2025,41 (10): 167-173.
(2)供热系统优化调控
[1]Lanbin Liu, Chen Wang, Rang Tu *. Study of a multi-objective optimization model for load distribution strategy in A centralized heating system with multi-heat source. Applied Thermal Engineering 266 (2025) 125675.
[2]Lanbin Liu, Feiyang Zhu , Rang Tu *. Study on rapid judgment method and operation strategy selection of two types of prime movers for CCHP systems. Energy & Buildings 329 (2025) 115263.
[3]X.Z. Chen, R. Tu*, M. Li, X. Yang, Performance of a novel central heating system combined with personalized heating devices [J]. Applied Thermal Engineering, 2023 (225): 120166.
(3)储能系统
[1]Rang Tu, Zichen Guo, Lanbin Liu*, Siqi Wang, Xu Yang. Reviews of Photovoltaic and Energy Storage Systems in Buildings for Sustainable Power Generation and Utilization from Perspectives of System Integration and Optimization[J]. Energies, 2025, 18(11): 2683.
[2]R. Tu, J.Q. Li Y.H. Hwang*. Study of temperature uniformity and thermal storage performances of a shell-and-tube type phase change plate[J]. International Journal of Refrigeration. 2021,122:69-80.
[3]J.Q. Li, R. Tu*, M.D. Liu, S.Q. Wang. Exergy analysis of a novel multi-stage latent heat storage device based on uniformity of temperature differences fields[J].Energy. 2021, 221:119884.
(4)空气取水系统
[1]Q.X. Zhang, R. Tu*, M.D. Liu. Thermal and economical performances analyses of a desiccant wheels-assisted atmospheric water harvesting system used in humid climate regions. Journal of Water Process Engineering 56(2023), 104323.
[2]Q.X. Zhang, R. Tu*, M.D. Liu, Performance analyses and optimization studies of desiccant wheel assisted atmospheric water harvesting system under global ambient conditions, Energy, 2023, 128477.
[3]M.D. Liu, R. Tu*, Z.L. Wu, J. Zhu. Performance analyses of desiccant wheel-assisted atmospheric water harvesting system using renewable heating and cooling sources[J]. Energy Conversion and Management, 2022,252,115065.
[4]Tu R*, Liu MD, Wang SQ, Yang X. Performance analyses and optimizations of desiccant wheel-assisted atmospheric water harvesting systems based on ideal thermodynamic cycles[J]. Energy Conversion and Management. 2021;245;114540.
[5]R. Tu, Y.H. Hwang*. Reviews of atmospheric water harvesting technologies[J]. Energy. 2020, 201, 117630.
[6]R. Tu, Y.H. Hwang*. Performance analyses of a new system for water harvesting from moist air that combines multi-stage desiccant wheels and vapor compression cycles[J]. Energy Conversion and Management. 2019,198,111811.
[7]涂壤,刘孟丹,王思琪.转轮辅助空气取水流程优化及性能分析[J].上海交通大学学报,2021,55(11):1392-1400.
(5)高效空调系统及设备
[1]Q.X. Zhang, R. Tu*, X. Yang. Performance analyses of a novel free-cooling assisted air conditioning system applied to electrical vehicles [J]. Applied Thermal Engineering 238 (2024) 122003.
[2]M.D. Liu, R. Tu*, X.Z. Chen, Z.L. Wu, J. Zhu, X. Yang. Performance analyses of an advanced heat pump driven fresh air handling system using active and passive desiccant wheels under various weather conditions [J]. International Journal of Refrigeration, 2022 (141): 1-11.
[3]S.Q. Wang, R. Tu*, X.Z. Chen. Dynamic performance analyses and optimization studies on air dehumidifiers using multi-stage desiccant plates [J]. Applied Thermal Engineering, 2022 (212): 118546.
[4]X.Z. Chen, R. Tu*, M. Li, X. Yang, Prediction models of air outlet states of desiccant wheels using multiple regression and artificial neural network methods based on criterion numbers[J], Applied Thermal Engineering, 2022 (204): 117940.
[5]R. Tu, L.J. Huang, A.B. Jin*, M.F. Zhang, X. Hai. Characteristic studies of heat sources and performance analysis of free-cooling assisted air conditioning and ventilation systems for working faces of mineral mines[J]. Building Simulation, 2021, 1-12.
[6]R. Tu, J.Q. Li Y.H. Hwang*. Fresh air humidification in winter using desiccant wheels for cold and dry climate regions: Optimization study of humidification processes[J]. International Journal of Refrigeration. 2020, 118:121-130.
[7]R. Tu, J.Q. Li Y.H. Hwang*. Performance analysis of desiccant wheels assisted fresh air humidifiers in winter using natural gas boilers: Applied in cold and dry climate regions[J]. International Journal of Refrigeration. 2020, 119:24-36.
[8]刘兰斌,张清杰,张志杰,涂壤*.一种多级板式固体除湿机性能分析[J].太阳能学报,2021,42(11):137-143.
