Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
6534381 | Solar Energy Materials and Solar Cells | 2018 | 9 Pages |
Abstract
Microencapsulated composite material using Na2SO4 as core and SiO2 as shell for high temperature thermal energy storage is prepared. The effects of silica mass percentages within the Na2SO4@SiO2 PCM composites on thermal conductivity, thermal stability, melting temperature, and latent heat are investigated. No new phases are formed during the encapsulation process. The spherical silica nanoparticles with diameters at around 300â¯nm are well decorated on the surface of Na2SO4. The PCM composite with 5.4% silica addition is determined as the optimal sample due to its excellent comprehensive properties. The inhibition of liquid leakage during melting can be effectively realized. The thermal conductivity of Na2SO4@SiO2 PCM under high temperatures (600-800â¯Â°C) can be increased to 0.59â¯W/(mâ¯K), 0.62â¯W/(mâ¯K), and 0.87â¯W/(mâ¯K), respectively. The initial and peak melting temperatures of the Na2SO4@SiO2 are tested at 885.20â¯Â°C and 887.91â¯Â°C, respectively. The latent heat is determined as high as 170.6â¯J/(gâ¯K), and the total heat storage density including latent and sensible heat with a temperature span of 100â¯Â°C is 390.6â¯J/g, and the mass loss is observed < 1% under 1000â¯Â°C. In addition, the latent heat loss percentage after 50 thermal cycle tests is ⤠4.3%.
Related Topics
Physical Sciences and Engineering
Chemical Engineering
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Authors
Xiaodong Wu, Maohong Fan, Sheng Cui, Gang Tan, Xiaodong Shen,