Development of black-ice removal system with latent heat thermal energy storage and solar thermal collectors

Black ice is a type of thin ice sheet that forms on roads and pavements forms easily generated in moist areas with subzero temperatures, especially in shade. In cold region, a high-efficiency black-ice removal system is required because of the environmental nature of easily generated black-ice. In t...

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Bibliographic Details
Published in:Energy (Oxford) 2022-04, Vol.244, p.122721, Article 122721
Main Authors: Kim, Sunuk, Oh, Han Jin, Han, Sang Ju, Ko, Han Seo, Shin, Youhwan, Shin, Dong Ho
Format: Article
Language:English
Subjects:
Ambient temperature
Black-ice
Concrete
Concrete pavements
Energy storage
Flow rates
Flow velocity
Heat
Heat pipes
Ice
Ice formation
Ice removal
Ice sheets
Latent heat
Latent heat thermal energy storage(LHTES)
Pavement
Phase-change material(PCM)
Pipes
Solar collectors
Solar energy
Solar heating
Solar thermal
Thermal energy
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Summary:Black ice is a type of thin ice sheet that forms on roads and pavements forms easily generated in moist areas with subzero temperatures, especially in shade. In cold region, a high-efficiency black-ice removal system is required because of the environmental nature of easily generated black-ice. In this study, a new type of black-ice removal system using latent heat thermal energy storage (LHTES) with a solar thermal collector is firstly introduced and was tested in the field. A concrete pavement was made for the test with a surface area of 0.4 m2 with heat pipes were embedded a depth of 0.05 m, with 0.15 m intervals. The solar thermal collector was used to store heat energy in the LHTES, which was dissipated through the concrete pavement by passing the embedded pipes. One centimeter of thin ice sheet, which was assumed to be black-ice, was formed on the surface of the concrete pavement. The LHTES charging and discharging flow rates were 5 and 7 L/min, respectively. The results were that the black-ice with 0.4 m2 area and a thickness of 1 cm at −15 °C ambient temperature was heated to 8 °C and completely melted in 2 h. •New type of black-ice removal system with LHTES and solar thermal collectors is introduced.•The black-ice removal field test was firstly investigated at sub-zero ambient temperature.•Rich performance comparison of charging and discharging flow rate in LHTES.•A black-ice at −15 °C was began to melt at 30 min and completely melted in 120 min.•A 5835 kJ of heat was used to remove 0.4 m2 area and 1 cm thickness of black-ice.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2021.122721