Experimental Study on Heat Storage/Release Performances of Composite Phase Change Thermal Storage Heating Wallboards Based on Photovoltaic Electric-Thermal Systems

The rapid development of photovoltaic technology provides more possibilities for the efficient application of solar energy in buildings. This research proposed a phase change material (PCM) heat storage wall system with a “four-layer” structure. A performance test platform using low voltage DC was b...

Full description

Saved in:
Bibliographic Details
Published in:Energies (Basel) 2023-03, Vol.16 (6), p.2595
Main Authors: Mi, Xue, Chen, Chao, Fu, Haoqi, Li, Gongcheng, Jiao, Yongxiang, Han, Fengtao
Format: Article
Language:English
Subjects:
Air conditioning
Alternative energy sources
Buildings
Calorific value
Carbon fibers
comparative experiment
Composite materials
composite phase change thermal storage heating wallboard
Drywall
Efficiency
Electricity
electrothermal film
Energy consumption
Graphene
Greenhouses
Heat
Heat storage
heat storage/release performance
Heat transfer
Hydronic heating
Insulation
Latent heat
Low voltage
Phase change materials
Photovoltaic cells
photovoltaic electro-thermal system
Photovoltaics
Product development
Solar energy
Solar energy industry
Technology
Thermal energy
Thermal storage
Voltage
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The rapid development of photovoltaic technology provides more possibilities for the efficient application of solar energy in buildings. This research proposed a phase change material (PCM) heat storage wall system with a “four-layer” structure. A performance test platform using low voltage DC was built to study the mechanism of electric thermal conversion of the graphene electrothermal film and the heat transfer characteristics of the “four-layer” structure. As shown in the experimental results, under the voltages of 24 V, 32 V and 42 V, (1) with the increase in voltage, the temperature of the electrothermal film increases, while its electrothermal conversion efficiency decreases from 85% to 75%; (2) during the heat storage process, because of its latent heat storage characteristics, the temperature of the PCM wallboard is 3~5 °C lower than that of the cement wallboard, but the effective heat storage increases by 59~65%; (3) during the heat release process, the effective heat release of the PCM wallboard increases by 41–78%, and the maximum heat storage and release efficiency is 98%; and (4) at 32 V, the PCM can completely change phase. The theoretical calorific value of the electrothermal film is equivalent to the hourly power generation of 1.45 m2 of photovoltaic modules. The results provide basic data for the integration of photovoltaic and phase change technology and their efficient application in buildings.
ISSN:1996-1073
1996-1073
DOI:10.3390/en16062595