Honeycomb filters made from mesoporous composite material for an open sorption thermal energy storage system to store low-temperature industrial waste heat

Today, a significant amount of low-temperature (< 100°C) industrial waste heat is directly discharged to the atmosphere. In this study, a new mesoporous composite material was developed as a sorption thermal energy storage material by utilizing its sorption and desorption properties. The composit...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2013-10, Vol.65, p.471-480
Main Authors: Liu, Hongzhi, Nagano, Katsunori, Sugiyama, Daichi, Togawa, Junya, Nakamura, Makoto
Format: Article
Language:English
Subjects:
Calcium chloride
Ceramics
Composite materials
Honeycomb
Honeycomb construction
Industrial wastes
Low-temperature industrial waste heat
Mesoporous material
Open sorption thermal energy storage
Regeneration
Sorption
Storage systems
Thermal energy
Water vapor sorption
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Summary:Today, a significant amount of low-temperature (< 100°C) industrial waste heat is directly discharged to the atmosphere. In this study, a new mesoporous composite material was developed as a sorption thermal energy storage material by utilizing its sorption and desorption properties. The composite material was formed by adding calcium chloride (CaCl2) to a mesoporous ceramic honeycomb filter. The main component of this ceramic is Wakkanai siliceous shale (WSS), which is found in northern Japan. The material test results demonstrated the following: (1) the composite material can sorb more water than the original ceramic material without dropping the CaCl2 solution; (2) it can be regenerated at around 100°C; and (3) after 25 repetitive regeneration/sorption cycles, no decomposition or cracks were observed. The sorption isotherm was also undamaged. An open sorption thermal energy storage system was proposed, and the experimental setup was constructed. A low regeneration temperature (80–100°C) of the storage medium was achieved with this open system. In the case of the 22.4 wt% CaCl2 supported with the honeycomb filter (926.2g; 2 L), air was heated to a temperature greater than 40°C for a duration of 432min by supplying air at 25°C at a flow rate of 3.0 m3/h when the regeneration temperature was 80°C. The volumetric heat storage density obtained was 272MJ/m3, and the coefficient of the heat extraction performance during the heat release process was 65%.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2013.06.021