Development of the inorganic composite phase change materials for passive thermal management of Li-ion batteries: Application

Galazutdinova, Yana; Ushak, Svetlana; Farid, Mohammed; Al‐Hallaj, Said; Grágeda, Mario

doi:10.1016/j.jpowsour.2021.229624

Cited by 53 publications

(6 citation statements)

References 17 publications

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“…Experimental result shows the heating of lithium-ion battery at a rate of 7.5°C min −1 . Composite PCM with expanded graphite impregnated over the surface of salt hydrate with a mixture of MgCl 2 ·6H 2 O and Mg(NO 3 ) 2 ·6H 2 O at 41.3:58.7 wt-% were used to perform an elaborative study on electrical cycling and thermal runway penetration of lithium-ion batteries [197]. Salt hydrates PCM were filled into the battery pack for enhanced thermal management.…”

Section: Application Of Composite Additives For Tesmentioning

confidence: 99%

Nano additive enhanced salt hydrate phase change materials for thermal energy storage

Kalidasan

Pandey

Saidur

et al. 2022

International Materials Reviews

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Energy storage plays a vital role in sustainable development. Focus on energy storage using phase change materials (PCMs) are of current research hotspot due to high latent heat value. Nevertheless, poor thermal conductivity, supercooling, phase separation, corrosive nature of salt hydrate is of great concern. Distress related to properties of PCM is resolved using nano additives. Major research focus on the dispersion of nano additive with PCM depends on (a) technique of preparing a novel composite PCM; (b) improvement of their thermophysical characteristic; and (c) advanced application for human comfort without polluting the environment. This article presents a critical review of hybridization techniques of metal, carbon and polymer additives on salt hydrate PCMs. To facilitate researchers, the significant variation on thermophysical properties of salt hydrate with nano additives are vitally compared, analysed and critically reviewed. This review article also includes the advanced application of nano additivesbased salt hydrate PCMs.

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Section: Application Of Composite Additives For Tesmentioning

confidence: 99%

Nano additive enhanced salt hydrate phase change materials for thermal energy storage

Kalidasan

Pandey

Saidur

et al. 2022

International Materials Reviews

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“…In addition to the organic PCMs, inorganic PCMs have recently obtained extensive development and significant breakthrough in the field of heat storage due to their low cost, wide phase change temperature, higher thermal conductivity, and latent heat compared to paraffin. 19,20 They have been used in solar heating, household hot water system, commercial heating, and other industries. 21,22 However, there is little discussion about applying this method to the field of battery thermal management until now.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of aluminum nitride/carbon fiber‐modified composite phase change materials for battery thermal management

Tang

Chen

Shao

et al. 2022

Intl J of Energy Research

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The phase change material is currently being regarded as an effective cooling media to be applied in the thermal management of lithium batteries-powered vehicles, in which the inorganic hydrate phase change material is desirable and widely investigated due to the high thermal conductivity, latent heat value, and low cost. However, when applied to thermal energy storage applications, supercooling and phase separation are problematic. To effectively circumvent this issue, this work considers utilizing the disodium hydrogen phosphate dodecahydrate as the matrix of the composite phase change material, as the phase transition temperature is suitable for the battery's operating temperature range. Meanwhile, the nucleating agent sodium metasilicate nonahydrate with similar lattice parameters and the thickener carboxymethyl cellulose are used to suppress the supercooling and eliminate the phase separation, respectively. Effects of nucleating agent, surface modified aluminum nitride, and short-cut carbon fiber on the supercooling degree, and thermal conductivity and curing performance in the phase change material are evaluated and discussed in detail to determine the optimal preparation scheme for Na 2 HPO 4 Á12H 2 O/modified AlN/CF inorganic composite phase change materials. Experimental results show that the addition of 4 wt% Na 2 SiO 3 Á9H 2 O, 4 wt% CMC, 12 wt% modified AlN, and 6 wt% CF reduces the supercooling

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“…Inorganic PCMs have been widely developed and have contributed to significant progress in the field of thermal storage. 31,32 Commercial heating, home hot water systems, solar heating, and other industries have all used inorganic PCMs. 33−35 However, inescapable issues such as phase separation and subcooling still restrict the application and development of inorganic hydrated salt compounds, 36 which are the two focal points of inorganic PCM research at this stage.…”

Section: Introductionmentioning

confidence: 99%

“…Compared with paraffins, inorganic PCMs have higher latent heat value and lower cost, a wider phase change temperature range, and high thermal conductivity. Inorganic PCMs have been widely developed and have contributed to significant progress in the field of thermal storage. , Commercial heating, home hot water systems, solar heating, and other industries have all used inorganic PCMs. − However, inescapable issues such as phase separation and subcooling still restrict the application and development of inorganic hydrated salt compounds, which are the two focal points of inorganic PCM research at this stage. Thickening agents are typically added to hydrated salts to improve the phase separation phenomenon and prevent the particles from sinking .…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of a Battery Thermal Management Device Based on a Composite Phase Change Material Coupled with a Double Helix Liquid Cooling Plate

Tang

Chen

et al. 2022

Energy Fuels

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Phase change materials (PCMs) are considered the most promising cooling technology due to their high latent heat, good reversibility, and low cost. However, in practical applications, PCMs encounter problems such as a sharp temperature increase after full melting and low thermal conductivity. To solve these problems, a new double helix-type liquid cooling plate is developed and coupled with a hydrated salt composite PCM (CPCM) for battery pack cooling. The modified CPCM has a high latent heat (249 J/g), suitable phase change temperature (35 °C), improved thermal conductivity to 1.86 W/(m·K), and reduced subcooling to 1.9 °C. The design of the liquid cooling plate structure can make the average water temperature on both sides of each cell approximate, thereby ensuring the temperature uniformity for the battery pack. A battery module system test rig is constructed and the heat dissipation effect for the battery module is compared with four cooling methods. The results reveal that the CPCM/liquid coupled cooling method is the most effective for cooling the battery pack. At a low coolant flow rate of 0.5 L/min, the maximum temperature difference for the coupled battery module is retained at 1.88 °C, and the average temperature is found to increase by only 9.6 °C. In addition, different coolant flow rates and control strategies of the coupled heat sink system are tested and compared. An optimal strategy is selected for the cyclic charge/discharge test of the coupled cooling module. The system is found to maintain good cooling performance and temperature uniformity after four charge/discharge cycles, and the highest temperature peak for the battery pack is only 40.3 °C, which is within the normal operating temperature range.

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Development of the inorganic composite phase change materials for passive thermal management of Li-ion batteries: Application

Cited by 53 publications

References 17 publications

Nano additive enhanced salt hydrate phase change materials for thermal energy storage

Nano additive enhanced salt hydrate phase change materials for thermal energy storage

Experimental investigation of aluminum nitride/carbon fiber‐modified composite phase change materials for battery thermal management

Experimental Investigation of a Battery Thermal Management Device Based on a Composite Phase Change Material Coupled with a Double Helix Liquid Cooling Plate

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