Evaluation of a cooling system integrated with
            <scp>different</scp>
            phase change material
            <scp>s</scp>
            and its effect on peak load shaving

Riahi, Alireza; Kavian, Soheil; Mosleh, Hassan Jafari; Shafii, Mohammad Behshad

doi:10.1002/er.6530

Cited by 7 publications

(4 citation statements)

References 45 publications

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“…9 The energy storage characteristics make microencapsulated PCM the material of choice in various sectors such as textiles, 10 construction and buildings, 11 thermal storage 12 and cold energy storage. 13 The polymer shell material for microencapsulation can be polymethyl methacrylate, 14 polystyrene, 15 melamine-formaldehyde, 16 a biodegradable polymer such as gum arabic 17 etc. The porous structure of the foam has been demonstrated in several studies to be a cause of PCM leakage, which is a crucial disadvantage of PU foam integrated PCM composite material.…”

Section: Introductionmentioning

confidence: 99%

Development of rigid polyurethane foam incorporating phase change material for a low‐temperature thermal energy storage application

Mahajan

Emmanuel²,

Rao³

et al. 2023

Polymer International

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Polyurethane (PU) foam is most commonly used in thermal insulation in cold storage applications but it lacks thermal energy storage characteristics. In the present work, a phase change material (PCM) n‐tetradecane is microencapsulated with poly(methyl methacrylate‐co‐methacrylic acid) using oil‐in‐water emulsion polymerization followed by incorporation into the PU foam formulation to fabricate composite foam. The purpose of the study was to combine thermal insulation along with thermal energy storage characteristics into PU foam. The phase change enthalpy of PU foam was improved from 22.43 to 55.46 J g−1 by changing the microcapsule loading fraction from 10% to 30%. The composite PU foam exhibits good thermal reliability even after 100 thermal cycling tests. The morphological observation confirms a decrease in cell size while increasing the microcapsule content. It is found that microcapsule addition has no effect on the thermal stability of PU foam. A prototype has been fabricated and tested, showing an enhancement in the thermal energy storage capacity of PU composite foam. This performance makes this PU‐PCM system feasible for cold energy storage applications. © 2022 Society of Industrial Chemistry.

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Section: Introductionmentioning

confidence: 99%

Development of rigid polyurethane foam incorporating phase change material for a low‐temperature thermal energy storage application

Mahajan

Emmanuel²,

Rao³

et al. 2023

Polymer International

View full text Add to dashboard Cite

show abstract

“…These facile use characteristics of these materials have attracted interest from numerous sectors, such as solar energy, 16,17 energy-saving building, 18,19 thermoregulated textiles, 20 thermal storage, 21,22 and cold energy storage. 23 The polymeric shell materials comprise polymethyl methacrylate, 13 polystyrene, 24 ureaformaldehyde, 25 melamine-formaldehyde, 26,27 and biodegradable polymers such as Gum Arabic, 28 and so on. MF polymer shell is used in several research studies because of its thermochemical stability.…”

Section: Introductionmentioning

confidence: 99%

“…Microencapsulation can be achieved using various methods, including physical and chemical processes such as spray drying, 9 fluidized bed, 10 coacervation, 11 emulsion polymerization, 12 suspension polymerization, 13 in‐situ polymerization, 14 and interfacial polymerization, 15 respectively. These facile use characteristics of these materials have attracted interest from numerous sectors, such as solar energy, 16,17 energy‐saving building, 18,19 thermoregulated textiles, 20 thermal storage, 21,22 and cold energy storage 23 . The polymeric shell materials comprise polymethyl methacrylate, 13 polystyrene, 24 urea‐formaldehyde, 25 melamine‐formaldehyde, 26,27 and biodegradable polymers such as Gum Arabic, 28 and so on.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and experimental investigation of microencapsulated eutectic phase change material‐integrated polyurethane sandwich tin panel composite for thermal energy storage in buildings

Naikwadi

Samui

Mahanwar

2021

Intl J of Energy Research

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“…Latent heat thermal energy storage (LHTES) is capable of storing and releasing enormous thermal energy, based on the phase transition of employed phase change materials (PCMs). [1][2][3] It is increasingly believed that LHTES can be an effective alternative to address the mismatch between energy supply and demand in time and space dimensions and can practically eliminate the existing energy crisis and atmospheric pollution, when applied in extensive occasions, such as solar thermal utilization, waste heat recovery, building energy saving, electronic device cooling, etc. [4][5][6][7] The charging and discharging performances of LHTES have been evaluated in feasible literatures and it is found that the thermal performance of LHTES is inseparable from thermophysical properties of PCMs.…”

Section: Introductionmentioning

confidence: 99%

Investigations on transient thermal performance of phase change materials embedded in metal foams for latent heat thermal energy storage

Zhang

Yuan

et al. 2021

Intl J of Energy Research

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A feasibly numerical model based on enthalpy-porosity and local thermal nonequilibrium is proposed to explore the transient heat transfer characteristics of phase change materials (PCMs) embedded in metal foams during charging process. Parametric analysis elaborates effects of various parameters on thermal performance of PCMs. Heat transfer and storage performances are further conducted from the perspectives of transient temperature. Results indicate that metal foams are capable of boosting melting rate of PCMs and phase change heat transfer is dominated through thermal conduction with obviously weakened natural convection. Metal foams with less thermal conductivity lead to lower temperature differences between metal foams and PCMs and more uniform temperature distributions of PCMs embedded in metal foams are developed over pure PCMs case. The complete melting times of PCMs can be shorten by approximately of 55.03%, 54.75% and 49.58%, when incorporated in metal foams and superiorities are even more obvious under lower porosity, larger pore density or higher heat flux. Greatest results in profiles and contours of temperature difference correspond well to mushy zones of phase transitions. Thermal energy is primarily reserved in PCMs in the form of latent heat. In conclusion, this paper is expected to be explicitly beneficial to broaden phase change energy storage applications.

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Evaluation of a cooling system integrated with different phase change material s and its effect on peak load shaving

Cited by 7 publications

References 45 publications

Development of rigid polyurethane foam incorporating phase change material for a low‐temperature thermal energy storage application

Development of rigid polyurethane foam incorporating phase change material for a low‐temperature thermal energy storage application

Fabrication and experimental investigation of microencapsulated eutectic phase change material‐integrated polyurethane sandwich tin panel composite for thermal energy storage in buildings

Investigations on transient thermal performance of phase change materials embedded in metal foams for latent heat thermal energy storage

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