Incorporation technology of bio-based phase change materials for building envelope: A review

Li, Dehong; Zhuang, Biaorong; Chen, Yu‐Chen; Li, Bin; Landry, Véronic; Kaboorani, Alireza; Wu, Zhenzeng; Wang, Xiaodong Alice

doi:10.1016/j.enbuild.2022.111920

Cited by 28 publications

(6 citation statements)

References 98 publications

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“…Li et al described the criteria for an ideal PCM in terms of economic, kinetic, chemical, environmental, and thermo‐physical properties. An ideal PCM should be having an effective cost and commercially available 25 . Despite the high cost of paraffin‐based organic PCMs, they dominate the market 26 .…”

Section: Introductionmentioning

confidence: 99%

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Bio‐based lamb tail fat phase change material with enhanced thermal properties by incorporation of cyclophosphazene additives

Duyar,

Yalcin,

Kup Aylikci

et al. 2024

Energy Storage

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Among organic phase‐change materials (PCM), paraffin is commonly used, but it is not environmentally friendly due to its petrochemical origin. For efficient utilization of solar or thermal energy, new PCM are needed, or it is necessary to improve the thermal properties of existing materials. Therefore, the utilization of renewable alternatives such as lamb's tail fat as a latent heat storage material is of particular importance for the evaluation of bio‐based waste oils. In this study, new PCM were developed by using different concentrations of cyclophosphazene derivatives as an additive to the starting lamb tail fat (LTF) material. According to the results, doping the LTF with 1% and 2% hexa(N,N‐dibutyl‐4‐aminophenoxy)cyclotriphosphazene (HBACP) the heat of fusion is significantly improved, while the 1% hexa(2‐ethylhexyloxy)cyclotriphosphazene (HEHCP) doping decreased the heat of fusion. In a comparison of various doped PCM, it was found that the tail fat doped with 1% HBACP had a heat of fusion of 166.6 kJ/kg, but a lower specific heat capacity and thermal conductivity than that doped with 2% HBACP. On the other hand, 1% HEHCP had the lowest thermal conductivity but a higher specific heat capacity than 1% HBACP. In addition, it was found that the PCM developed by incorporating HBACP could be operated as a cooling fluid for photovoltaic modules or as a working fluid in concentrated solar energy systems due to the higher heat of fusion value of 1% HBACP and the higher specific heat capacity of 2% HBACP, which consists of lamb's tail fat.

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Section: Introductionmentioning

confidence: 99%

“…An ideal PCM should be having an effective cost and commercially available. 25 Despite the high cost of paraffin-based organic PCMs, they dominate the market. 26 Therefore, there is a need to develop new PCMs that are sustainable, biodegradable, and have excellent chemical and thermo-physical properties.…”

mentioning

confidence: 99%

Bio‐based lamb tail fat phase change material with enhanced thermal properties by incorporation of cyclophosphazene additives

Duyar,

Yalcin,

Kup Aylikci

et al. 2024

Energy Storage

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“…Biodegradability must be researched for each type of bio-based PCM, even though it is generally assumed. Generally benign, biobased PCMs can be employed in low to high temperatures (−80 to 275 °C) [ 42 ].…”

Section: Introductionmentioning

confidence: 99%

A comprehensive review of critical analysis of biodegradable waste PCM for thermal energy storage systems using machine learning and deep learning to predict dynamic behavior

Sharma,

Singh,

Makki

et al. 2024

Heliyon

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“…Solar energy, as the most inexhaustible, renewable, and clean energy resource, has drawn widespread concerns in recent decades due to growing depletion of fossil energy and deteriorating environmental pollution. − Solar-thermal conversion, where solar irradiation is captured and converted to thermal directly, is considered the most fascinating approach to exploit solar energy because of its superior energy conversion efficiency, straightforward operation, and cost effectiveness. , However, broad application of solar-thermal utilization is severely limited by the intermittency and volatility nature of solar irradiation. − Phase-change materials (PCMs) are efficient thermal storage materials that can spontaneously absorb and release plentiful latent heat with little temperature alteration through phase transitions. − Incorporating PCMs into the solar-thermal utilization system is regarded as one of the most prospective approaches to overcome the intermittency of solar irradiation and improve solar-thermal utilization efficiency. − Among numerous PCMs, n -alkanes are recognized as the most advisable PCMs on account of their superior properties, such as superior energy storage capacity, excellent chemical stability, suitable operating temperature, and noncorrosiveness. − Nevertheless, the application prospect of n -alkanes for efficient thermal storage is extremely restricted due to their leakage issues of molten liquid during solid–liquid phase transformation. , …”

Section: Introductionmentioning

confidence: 99%

Flame-Retardant and Form-Stable Phase-Change Composites Based on Phytic Acid/ZnO-Decorated Surface-Carbonized Delignified Wood with Superior Solar-Thermal Conversion Efficiency and Improved Thermal Conductivity

Yue

Wang

et al. 2023

ACS Appl. Mater. Interfaces

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In order to efficiently exploit solar-thermal energy, it is essential to develop form-stable phase-change material (PCM) composites simultaneously with superior solar-thermal storage efficiency, excellent flame retardancy, and improved thermal conductivity. Herein, phytic acid (PA)-modified, zinc oxide-deposited, and surface-carbonized delignified woods (PZCDWs) were constructed by alkaline boiling, PA modification, ZnO deposition, and surface carbonization. Then, novel form-stable PCMs (PZPCMs) with superior solar-thermal storage efficiency, excellent flame retardancy, and improved thermal conductivity were fabricated by impregnating n-docosane into PZCDWs under vacuum. The PZCDW aerogels can well support the n-docosane and overcome liquid leakage owing to their superior surface tension and strong capillary force. Differential scanning calorimetry results showed that PZPCMs possessed superior n-docosane encapsulation yield and high phase-change enthalpy (185.2–213.1 J/g). Decorating delignified wood by surface carbonization and ZnO deposition significantly improved the solar-thermal conversion efficiency (up to 86.2%) and thermal conductivity (193.3% increased) of PCM composites. Furthermore, with the introduction of PA into PZPCMs, the peak heat release rate and total heat release of the PCM composites decreased considerably, indicating the enhanced flame retardancy of PZPCMs. In conclusion, the novel renewable wood-based PCM composites demonstrate promising potential in solar energy harnessing and thermal modulation technologies.

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Incorporation technology of bio-based phase change materials for building envelope: A review

Cited by 28 publications

References 98 publications

Bio‐based lamb tail fat phase change material with enhanced thermal properties by incorporation of cyclophosphazene additives

Bio‐based lamb tail fat phase change material with enhanced thermal properties by incorporation of cyclophosphazene additives

A comprehensive review of critical analysis of biodegradable waste PCM for thermal energy storage systems using machine learning and deep learning to predict dynamic behavior

Flame-Retardant and Form-Stable Phase-Change Composites Based on Phytic Acid/ZnO-Decorated Surface-Carbonized Delignified Wood with Superior Solar-Thermal Conversion Efficiency and Improved Thermal Conductivity

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