New Thermochemical Salt Hydrate System for Energy Storage in Buildings

This paper introduces an innovative design for an “inorganic salt-expanded graphite” composite thermochemical system. The storage unit is made of a perforated, compressed, expanded graphite block impregnated with molten CaCl2∙6H2O; the humid air passes through the holes that allow the moisture to di...

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Bibliographic Details
Published in:Energies (Basel) 2024-10, Vol.17 (20), p.5228
Main Authors: Galazutdinova, Yana, Clark, Ruby-Jean, Al-Hallaj, Said, Kaur, Sumanjeet, Farid, Mohammed
Format: Article
Language:English
Subjects:
calcium chloride
Cement
Composite materials
Composite materials industry
Design
energy density
Energy efficiency
Energy management systems
Energy storage
Evaluation
expanded graphite
Graphite
Heat conductivity
Humidity
HVAC
Hydration
Permeability
Polyethylene glycol
Reactors
salt hydrate
Temperature
thermal efficiency
thermochemical energy storage
Thermogravimetric analysis
Zeolites
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Summary:This paper introduces an innovative design for an “inorganic salt-expanded graphite” composite thermochemical system. The storage unit is made of a perforated, compressed, expanded graphite block impregnated with molten CaCl2∙6H2O; the humid air passes through the holes that allow the moisture to diffuse and react with the salt. The prepared block underwent 90 hydration-dehydration cycles. Although most of the performed cycles were carried out with salt overhydration and deliquescence, the treated samples have remained mechanically and thermally stable with no drop in energy density. The volumetric energy density of the composite ranged from 135.5 to 277.6 kWh/m3, depending on airflow rate and absolute humidity. To ensure composite material cycling stability, the energy density of the block was measured during hydration at similar conditions of absolute humidity, inlet temperature, and airflow rate (0.01 kgwater/kgair, 20 °C, 400 l/min). The average energy density at these conditions was sustained at 219 kWh/m3. The block integrity was monitored by visual inspection after removing it from the reactor chamber every few cycles. Both the composite material and its manufacturing process are simple and easy to scale up for future commercialization.
ISSN:1996-1073
1996-1073
DOI:10.3390/en17205228