首页|Energy modeling and optimization of building condenser water systems with all-variable speed pumps and tower fans:A case study

Energy modeling and optimization of building condenser water systems with all-variable speed pumps and tower fans:A case study

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The emergence of building condenser water systems with all-variable speed pumps and tower fans allows for increased efficiency and flexibility of chiller plants in partial load operation but also increases the control complexity of condenser water systems.This study aims to develop an integrated modeling technique for evaluating and optimizing the energy performance of such a condenser water system.The proposed system model is based on the semi-physical semi-empirical chiller,pump,and cooling tower models,with capabilities of fully considering the hydraulic and thermal interactions in the condenser water loop,being solved analytically and much faster than iterative solvers and supporting the explicit optimization of the pump and tower fan frequency.A mathematical approach,based on the system model and constrained optimization technique,is subsequently established to evaluate the energy performance of a typical dual setpoint-based variable speed strategy and find its energy-saving potential and most efficient operation by jointly optimizing pumps and tower fans.An all-variable speed chiller plant from Wuhan,China,is used for a case study to validate the system model's accuracy and explore its applicability.The results showed that the system model can accurately simulate the condenser water system's performance under various operating conditions.By optimizing the frequencies of pumps and tower fans,the total system energy consumption can be reduced by 12%-13%compared to the fixed dual setpoint-based strategy with range and approach setpoints of 4 ℃ and 2 ℃.In contrast,the energy-saving potential of optimizing the cooling tower sequencing is insignificant.A simple joint speed control method for optimizing the pumps and tower fans emerged,i.e.,the optimal pump and fan frequency are linearly correlated(if both are non-extremes)and depend on the chiller part load ratio only,irrespective of the ambient wet-bulb temperature and chilled water supply temperature.It was also found that the oversizing issue has further limited the energy-saving space of the studied system and results in the range and approach setpoints being inaccessible.The study's findings can serve as references to the operation optimization of all-variable speed condenser water systems in the future.

all-variable speed chiller plantmodel-based optimizationhydraulic and thermal couplinganalytical solutiondual setpoint-based variable speed controloptimal joint speed control

Yong Cao、Chuang Wang、Sheng Wang、Xiao Fu、Xinguo Ming

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School of Mechanical Engineering,Shanghai Jiao Tong University,Shanghai 200240,China

State Key Laboratory of Air-Conditioning Equipment and System Energy Conservation,Zhuhai 519070,China

GREE Electric Appliances,Inc.of Zhuhai,Zhuhai 519070,China

School of Environment and Energy Engineering,Beijing University of Civil Engineering and Architecture,Beijing 100044,China

Beijing Advanced Innovation Center for Future Urban Design,Beijing University of Civil Engineering and Architecture,Beijing 100044,China

State Key Laboratory of Air-conditioning Equipment and System Energy Conservation,Zhuhai 519070,China

Gree Electric Appliances Inc.of Zhuhai,Zhuhai 519070,China

School of Mechanical Engineering Shanghai Jiao Tong University,Shanghai 200240,China

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State Key Laboratory of Air-Conditioning Equipment and System Energy ConservationNational Natural Science Foundation of ChinaScientific Research Project of Beijing Municipal Education CommissionScientific Research Project of Beijing Municipal Education CommissionBeijing Advanced Innovation Center for Future Urban DesignPyramid Talent Training ProjectPost-Graduate Innovation Project of Beijing University of Civil Engineering and Architecture

ACSKL2019KT1351608297KM201910016009KZ202110016022UDC2019011121JDYC20220815PG2024077

2024

10.1007/s12273-024-1123-8

建筑模拟(英文版)

建筑模拟(英文版)

EI
ISSN:1996-3599
年,卷(期):2024.17(7)