裴德顺
个人简介
裴德顺,男,越南人,1981年5月生
工学博士,教授,博士研究生导师
主要研究方向
[1] 用于空气除湿和集水的先进材料和技术
[2] 先进的蒸发冷却系统
[3] 纳米材料的湿化学合成
指导研究生情况
协助指导博士研究生2人,硕士研究生2人
教学方面
本科课程:固态化学
研究生课程:高级空调系统
联系方式:
Email: 1000005420@ujs.edu.cn
Tel.: 0178-51770519
地址:江苏省镇江市学府路301号江苏大学机械工程学院,212013
参与的科研项目
No. |
名称 |
期间 |
授予单位/金额 |
1 |
Innovative Hybrid Super Absorbent-Indirect Evaporative Water-Based Cooling System for All-Weather Air-Conditioning Without Compressors and Chemical Refrigerants |
11/2018-11/2020 |
Singapore National Research Foundation |
2 |
Air-Conditioning Method without Compressor for all Weather Cooling: Hybrid Dehumidifier Cycle and Maisotsenko (M) Cycle for Cooling |
08/2015-07/2018 |
Singapore Energy Innovation Research Programme for Building Energy Efficiency |
3 |
Air Conditioning Systems Efficiency: A novel hybrid cogeneration-based istrict cooling to achieve 0.65±0.05 kW/Rton |
04/2013-12/2018 |
Singapore National Research Foundation- |
4 |
Energy efficient hydrogen production via a hybrid photocatalysis/electrolysis prototype |
01/2012-12/2012 |
Singapore National Research Foundation |
代表性成果
一、发表的部分学术论文
1. Experimental performance and energy efficiency investigation of composite superabsorbent polymer and potassium formate coated heat exchangers, P Vivekh, DT Bui, MR Islam, K Zaw, KJ Chua, Applied Energy 275, 2020, 115428.
2. Experimental performance evaluation of desiccant coated heat exchangers from a combined first and second law of thermodynamics perspective, P. Vivekh, D.T. Bui, MR. Islam, K. Zaw, K.J. Chua, Energy Conversion and Management 207, 2020, 112518
3. Theoretical performance analysis of silica gel and composite polymer desiccant coated heat exchangers based on a CFD approach, P. Vivekh, D.T. Bui, M. Kumja, MR. Islam, K.J. Chua, Energy Conversion and Management 187, 2019, 423-446.
4. Performance evaluation of PVA-LiCl coated heat exchangers for next-generation of energy-efficient dehumidification, P. Vivekh, D.T. Bui, Y. Wong, M. Kumja, K.J. Chua, Applied energy 237, 2019, 733-750.
5. On the exergy analysis of the counter-flow dew point evaporative cooler, J Lin, DT Bui, R Wang, KJ Chua, Energy 165, 2018, 958-971.
6. Recent developments in solid desiccant coated heat exchangers–A review, P Vivekh, M Kumja, DT Bui, KJ Chua, Applied Energy 229, 2018, 778-803.
7. On the fundamental heat and mass transfer analysis of the counter-flow dew point evaporative cooler, J. Lin, D.T. Bui, R.Z. Wang, K.J. Chua, Applied Energy 217, 2018, 126-142.
8. Investigation of dew point evaporative cooling with vacuum membrane dehumidification, J. Lin, D.T. Bui, R.Z. Wang, K.J. Chua, Energy Procedia 142, 2017, 3851-3856.
9. Comment on “Water harvesting from air with metal-organic frameworks powered by natural sunlight”, D.T. Bui, K.J. Chua, J.M. Gordon, Science, 358, 2017, eaao0791.
10. On the theoretical and experimental energy efficiency analyses of a vacuum-based dehumidification membrane, D.T. Bui, Y. Wong, I. Raisul, K.J. Chua, Journal of Membrane Science, 539, 2017, 76-87.
11. A thermodynamic perspective to study energy performance of vacuum-based membrane dehumidification, D.T. Bui, M Kum Ja, J.M. Gordon, K.C. Ng, K.J. Chua, Energy, 132, 2017, 106-115.
12. Unsteady-state analysis of a counter-flow dew point evaporative cooling system, J. Lin, K. Thu, D.T. Bui, R.Z. Wang, K.C. Ng, M. Kumja, K.J. Chua, Energy 113, 2016, 172-185.
13. Water vapor permeation and dehumidification performance of poly (vinyl alcohol)/lithium chloride composite membranes, D.T. Bui, A Nida, KC Ng, KJ Chua, Journal of Membrane Science 498, 2016, 254-262.
14. Study on dew point evaporative cooling system with counter-flow configuration, J. Lin, K. Thu, D.T. Bui, R.Z. Wang, K.C. Ng, K.J. Chua, Energy Conversion and Management 109, 2016, 153–165.
15. Evaluating Water Vapor Permeance Measurement Techniques for Highly Permeable Membranes, D.T. Bui, Y. Wong, K.C. Ng, K.J. Chua, Computers, Materials & Continua 47 (2), 2015, 89-105,
16. Isotope tracing study on oxidation of water on photoirradiated TiO2 particles, D.T. Bui, E. Yagi, T. Harada, S. Ikeda, M. Matsumura, Applied Catalysis, B 126, 2012, 86-89.
17. Two Routes for Mineralizing Benzene by TiO2-Photocatalyzed Reaction, D.T. Bui, A. Kimura, S. Higashida, S. Ikeda, M. Matsumura, Applied Catalysis, B 107, 2011, 119-127.
18. Determination of Oxygen Sources for Oxidation of Benzene on TiO2 Photocatalysts in Aqueous Solutions Containing Molecular Oxygen, D.T. Bui, A. Kimura, S. Ikeda, M. Matsumura, Journal of the American Chemical Society, 132, 2010, 8453–8458.
19. Lowering of Photocatalytic Activity of TiO2 Particles during Oxidative Decomposition of Benzene in Aerated Liquid, D.T. Bui, A. Kimura, S. Ikeda, M. Matsumura, Applied Catalysis, B 94, 2010, 186–191.
二、授权发明专利
1. 国家知识产权局,申请号:202111039497.4,申请日:2021-09-06
2. Intellectual Property Office of Singapore, Reference No. 10202103701W, Date of filling: 12 April 2021
3. International Application Published under the Patent Cooperation Treaty (PCT). International publication number: WO 2020/055326 A1. International Publication Date 19/03/2020
4. Intellectual Property Office of Singapore, Reference No. SP100015SG, Date of filling: 13/09/2018
5. International Application Published under the Patent Cooperation Treaty (PCT). International publication number: WO 2016/010486 Al. International Publication Date: 21/01/2016.
三、科研获奖
1. ASEAN Outstanding Engineering Achievement Awards 2018
2. Singapore IES Prestigious Engineering Achievement Award 2018
3. ASEAN Outstanding Engineering Achievement Awards 2015
4. Singapore IES Prestigious Engineering Achievement Award 2015
5. Singapore Minister for National Development’s R&D Award 2015 (Distinguished Award)