Hydrophilic substance assisted low temperature LiOH·H2O based composite thermochemical materials for thermal energy storage

Li, Shijie; Huang, Hongyu; Yang, Xixian; Bai, Yu; Li, Jun; Kobayashi, Noriyuki; Kubota, Mitsuhiro

doi:10.1016/j.applthermaleng.2017.09.050

Cited by 51 publications

(22 citation statements)

References 29 publications

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“…Salt hydrates such as MgCl 2 $6H 2 O, 14,15 LiOH$H 2 O, 16 and metal sulfates 15,[17][18][19] have been used as CHS materials in the temperature range of 100-250 C. Mg(OH) 2 , [20][21][22][23][24][25][26][27][28][29][30][31][32][33][34] Ca(OH) 2 , 28,[35][36][37] and MgCO 3 (ref. 38) can be used to store energy in the temperature range of 200-500 C. These materials exhibit high energy density and the property of reversibility.…”

Section: Introductionmentioning

confidence: 99%

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

2021

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Section: Introductionmentioning

confidence: 99%

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

2021

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“…13 Large numbers of materials could thus be researched for use in thermochemical heat storage over a wide range of working temperatures. [12][13][14][15][16][17][18][19] Kubota et al 9,20 composed a porous carbon and hygroscopic material with lithium hydroxide (LiOH) for low-temperature energy storage and the heat storage performance was obviously improved. This research proves that additive materials could enhance the performance and the heat and mass transfer property of the materials.…”

Section: Introductionmentioning

confidence: 99%

Hygroscopic additive-modified magnesium sulfate thermochemical material construction and heat transfer numerical simulation for low temperature energy storage

Yang

Deng³

et al. 2022

RSC Adv.

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“…Among all the reaction systems, the inorganic hydrate lithium hydroxide monohydrate (LiOH•H 2 O) due to its high energy density (1440 kJ kg À1 ) and mild reaction process was selected as the promising candidate for low-temperature (below 373 K) heat storage. [31] The reversible chemical reaction is as follows LiOH ⋅ H 2 OðsÞ ↔ LiOHðsÞ þ H 2 OðgÞ ΔH ¼ AE1440 kJ kg À1 (1)…”

Section: Introductionmentioning

confidence: 99%

Comparative Analysis of 3D Graphene–LiOH·H₂O Composites by Modification with Phytic Acid and Ascorbic Acid for Low‐Grade Thermal Energy Storages

Zeng

et al. 2021

Energy Tech

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3D Graphene (3D‐GF) modified with different additive concentrations (phytic acid [PA] and ascorbic acid [AA]) is developed and then combined with different LiOH contents by the hydrothermal method to obtain composite materials. It can be found that the addition of PA and AA will not destroy the carbon skeleton structure of 3D‐GF. With increasing additive content, the thermal conductivities of modified 3D‐GF first increase and reach their maximum values at 8 mg mL−1. The modified 3D‐GF with the highest thermal conductivity is selected to be combined with different LiOH contents. The addition of PA and AA can broaden the charging temperature range from 60–110 to 30–200 °C and improve the LiOH hydration rate and heat storage density. Compared with the PA‐modified composite, the AA‐modified composite shows smaller (about 7.6 nm) and more uniform LiOH·H2O particles (the particles size standard deviation of 3D‐GF‐AA‐LiOH·H2O is 1.1503), a larger specific surface area (119 m2 g−1), higher heat storage density (the highest value of 2763 kJ kg−1 for LiOH⋅H2O, which can be about 4.2 times of pure LiOH), and less influenced by the change of LiOH content (the thermal conductivity standard deviation of 3D‐GF‐AA‐LiOH·H2O is 0.123).

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Hydrophilic substance assisted low temperature LiOH·H2O based composite thermochemical materials for thermal energy storage

Cited by 51 publications

References 29 publications

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

Hygroscopic additive-modified magnesium sulfate thermochemical material construction and heat transfer numerical simulation for low temperature energy storage

Comparative Analysis of 3D Graphene–LiOH·H₂O Composites by Modification with Phytic Acid and Ascorbic Acid for Low‐Grade Thermal Energy Storages

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Hydrophilic substance assisted low temperature LiOH·H2O based composite thermochemical materials for thermal energy storage

Cited by 51 publications

References 29 publications

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

Fourier-transform infrared and X-ray diffraction analyses of the hydration reaction of pure magnesium oxide and chemically modified magnesium oxide

Hygroscopic additive-modified magnesium sulfate thermochemical material construction and heat transfer numerical simulation for low temperature energy storage

Comparative Analysis of 3D Graphene–LiOH·H2O Composites by Modification with Phytic Acid and Ascorbic Acid for Low‐Grade Thermal Energy Storages

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Comparative Analysis of 3D Graphene–LiOH·H₂O Composites by Modification with Phytic Acid and Ascorbic Acid for Low‐Grade Thermal Energy Storages