Mechanical design and performance evaluation of active thermosiphon beam terminal units
The active chilled beam (ACB) system has evolved for more than twenty years, but its limitations in chilled water temperature control, initial cost and condensation stand as the major obstacles for applications especially in tropical regions. Therefore, a novel air-water configuration active thermos...
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sg-ntu-dr.10356-1511402021-06-24T10:18:45Z Mechanical design and performance evaluation of active thermosiphon beam terminal units Ji, Ke Cai, Wenjian Wu, Bingjie Ou, Xianhua School of Electrical and Electronic Engineering Centre for system intelligence and efficiency (EXQUISITUS) Centre for E-City Engineering::Electrical and electronic engineering Active Thermosiphon Beam Air Conditioning and Mechanical Ventilation The active chilled beam (ACB) system has evolved for more than twenty years, but its limitations in chilled water temperature control, initial cost and condensation stand as the major obstacles for applications especially in tropical regions. Therefore, a novel air-water configuration active thermosiphon beam (ATB) terminal unit, which combines air entrainment effect and thermosiphon effect, is proposed in this study. The mechanical design and working principles of the ATB are introduced. The experimental comparisons of the ATB are conducted under a wide range of operating conditions to estimate its thermodynamic and hydrodynamic performances. Meanwhile, the operating characteristics and efficiency of the terminal unit are evaluated under four sets of criteria: total cooling capacity, entrainment ratio (ER), sensible heat ratio and heat transfer effectiveness. The experimental results show that the cooling capacity of the ATB is around 50% higher than the ACB under nominal conditions. Moreover, the sensible heat ratio (SHR) and heat transfer effectiveness of ATB can reach 42% and 27.3 respectively which validate the feasibility of the proposed terminal unit. The experimental findings provide a guideline for the design and operation of the ATB system. National Research Foundation (NRF) The work is supported by the research project New Generation ACMV Systems – Total Energy Efficiency Solutions. The project is funded by the National Research Foundation of Singapore (NRF2011 NRF-CRP001- 090). 2021-06-24T10:18:45Z 2021-06-24T10:18:45Z 2019 Journal Article Ji, K., Cai, W., Wu, B. & Ou, X. (2019). Mechanical design and performance evaluation of active thermosiphon beam terminal units. Building and Environment, 153, 241-252. https://dx.doi.org/10.1016/j.buildenv.2019.02.033 0360-1323 https://hdl.handle.net/10356/151140 10.1016/j.buildenv.2019.02.033 2-s2.0-85062462692 153 241 252 en NRF2011 NRF-CRP001- 090 Building and Environment © 2019 Elsevier Ltd. All rights reserved. |
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Engineering::Electrical and electronic engineering Active Thermosiphon Beam Air Conditioning and Mechanical Ventilation Ji, Ke Cai, Wenjian Wu, Bingjie Ou, Xianhua Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| description |
The active chilled beam (ACB) system has evolved for more than twenty years, but its limitations in chilled water temperature control, initial cost and condensation stand as the major obstacles for applications especially in tropical regions. Therefore, a novel air-water configuration active thermosiphon beam (ATB) terminal unit, which combines air entrainment effect and thermosiphon effect, is proposed in this study. The mechanical design and working principles of the ATB are introduced. The experimental comparisons of the ATB are conducted under a wide range of operating conditions to estimate its thermodynamic and hydrodynamic performances. Meanwhile, the operating characteristics and efficiency of the terminal unit are evaluated under four sets of criteria: total cooling capacity, entrainment ratio (ER), sensible heat ratio and heat transfer effectiveness. The experimental results show that the cooling capacity of the ATB is around 50% higher than the ACB under nominal conditions. Moreover, the sensible heat ratio (SHR) and heat transfer effectiveness of ATB can reach 42% and 27.3 respectively which validate the feasibility of the proposed terminal unit. The experimental findings provide a guideline for the design and operation of the ATB system. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Ji, Ke Cai, Wenjian Wu, Bingjie Ou, Xianhua |
| format |
Article |
| author |
Ji, Ke Cai, Wenjian Wu, Bingjie Ou, Xianhua |
| author_sort |
Ji, Ke |
| title |
Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| title_short |
Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| title_full |
Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| title_fullStr |
Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| title_full_unstemmed |
Mechanical design and performance evaluation of active thermosiphon beam terminal units |
| title_sort |
mechanical design and performance evaluation of active thermosiphon beam terminal units |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151140 |
| _version_ |
1703971256136630272 |