Performance analysis of absorption thermal energy storage for distributed energy systems

Lingshi Wang, Fu Xiao, Borui Cui, Maomao Hu, Tao Lu

Research output: Contribution to journalConference articlepeer-review

4 Scopus citations

Abstract

In recent years, distributed energy systems (DES) have attracted worldwide attention. Distributed generation unit (DG) in DES usually works under part load during night, which results in low efficiency and the waste heat of DG cannot be fully utilized. This study proposes a novel absorption thermal energy storage system together with electric energy storage for distributed energy systems. The proposed absorption thermal energy storage system which is a combination of absorption chiller and liquid storage tanks, has a higher energy storage density. During off-peak hours, the extra electricity of DG can be used by electric chillers (EC) and the extra waste heat of DG is stored by the proposed absorption thermal energy storage system. The stored thermal energy is released in peak hours to meet the cooling loads of buildings. A case study of DES in a campus under cooling-dominated climate is conducted to evaluate the performance of the proposed system. The results in a typical summer day indicate that the DG utilization rate increases from 80% to 92.9%, meanwhile the required capacities of electric chillers can be obviously reduced. The operating cost of DES also reduces by 12.9% compared with the DES without energy storage. Through appropriate operation strategy, off-the-grid operation for DES can be achieved without energy waste by applying the proposed energy storage method.

Original languageEnglish
Pages (from-to)3152-3157
Number of pages6
JournalEnergy Procedia
Volume158
DOIs
StatePublished - 2019
Event10th International Conference on Applied Energy, ICAE 2018 - Hong Kong, China
Duration: Aug 22 2018Aug 25 2018

Funding

The work reported herein is supported by National Natural Science Foundation of China (No. 51306157) and the Central Research Grant (G-YBTB) from the Hong Kong Polytechnic University. The support is gratefully acknowledged.

FundersFunder number
National Natural Science Foundation of China51306157, G-YBTB
Hong Kong Polytechnic University
Central Drug Research Institute

    Keywords

    • Absorption thermal energy storage
    • Distributed energy system
    • Peak load shifting
    • Self-sufficient micro grid
    • Waste heat

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