Enhanced Operation of Ice Storage System for Peak Load Management in Shopping Malls across Diverse Climate Zones

There exists a notable research gap concerning the application of ice storage systems in shopping mall settings at the urban scale. The characteristics of large pedestrian flow, high energy consumption, and high peak loads in shopping malls make their advantages in energy conservation. This study re...

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Bibliographic Details
Published in:Sustainability 2023-10, Vol.15 (20), p.14759
Main Authors: Su, Fanghan, Wang, Zhiyuan, Yuan, Yue, Song, Chengcheng, Zeng, Kejun, Chen, Yixing, Zhang, Rongpeng
Format: Article
Language:English
Subjects:
Air conditioning
Analysis
Carbon
Chilled water systems
China
Control algorithms
Cooling
Cost control
Design
Efficiency
Electricity
Electricity distribution
Emission standards
Emissions
Energy conservation
Energy consumption
Energy modeling
Energy storage
Force and energy
Green buildings
Heat transfer
HVAC
Indoor air quality
Linear programming
Marketing research
Optimization techniques
Prices
Shopping centers
Shopping malls
Sustainability
Thermal energy
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Summary:There exists a notable research gap concerning the application of ice storage systems in shopping mall settings at the urban scale. The characteristics of large pedestrian flow, high energy consumption, and high peak loads in shopping malls make their advantages in energy conservation. This study researches sustainable cooling solutions by undertaking an economic analysis of the ice storage systems within shopping malls across 11 distinct cities, each system operating under varied electricity pricing frameworks. The methodology begins with creating baseline mall models using AutoBPS and refining them with OpenStudio. Before starting to adjust the model, measured data were used to verify the accuracy of the baseline model, the coefficient of variation of the root mean square error (CVRMSE) and normalized mean bias error (NMBE) metrics were calculated for the model energy consumption, with CVRMSE values of 8.6% and NMBE values of 1.57% for the electricity consumption, while the metrics for the gas consumption were 12.9% and 1.24%, respectively. The study extends its inquiry to encompass comprehensive economic evaluations based on the unique electricity pricing of each city. This rigorous assessment discerns the relationship between capacity, operational strategies, and economic performance. Particularly striking are the so-called peak-shaving and valley-filling effects verified in regions characterized by lower latitudes and substantial cooling loads. The interaction between ice storage capacity and operational schedules significantly influences both economic viability and cooling efficiency. Based on the temporal dynamics of time-of-use (TOU) power pricing, a finely calibrated operational schedule for the ice storage system is proposed. This operational strategy entails charging during periods of reduced electricity pricing to undertake cooling loads during peak electricity pricing intervals, culminating in substantial reductions in electricity charges of buildings. Moreover, the strategic reallocation of energy, characterized by a reduced chiller capacity and a corresponding elevation in ice storage system capacity, augments cooling efficiency and diminishes cooling-related electricity expenses. This study offers valuable insights for optimizing and deploying ice storage systems in diverse climatic regions, particularly for shopping malls. As a guiding reference, this paper provides stakeholders with a framework to reasonably apply and adjust ice storage s
ISSN:2071-1050
2071-1050
DOI:10.3390/su152014759