Do encapsulated heat storage materials really retain their original thermal properties?

Chaiyasat, Preeyaporn; Noppalit, Sayrung; Okubo, Masayoshi; Chaiyasat, Amorn

doi:10.1039/c4cp03458a

Cited by 46 publications

(35 citation statements)

References 55 publications

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“…The enhancement in working efficiency was found to be remarkable due to the thermal physical properties of energy storage materials and the addition of high-conductivity PCM (phase change materials). Chaiyasat et al 11 proved the validity of the idea that the thermal properties strongly depend on the kind of polymer shell using uncross-linked microcapsules. Tan et al 10 investigated experimentally the PCM inside a spherical capsule.…”

Section: Introductionmentioning

confidence: 99%

“…Tan et al 10 investigated experimentally the PCM inside a spherical capsule. Chaiyasat et al 11 proved the validity of the idea that the thermal properties strongly depend on the kind of polymer shell using uncross-linked microcapsules. Narasimhan et al 12 investigated numerically the performance of an encapsulated latent heat thermal storage unit containing a PCM dispersed with high-conductivity particles.…”

Section: Introductionmentioning

confidence: 99%

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Preparation and performance study of cordierite/mullite composite ceramics for solar thermal energy storage

Zhang

et al. 2016

Int J Applied Ceramic Tech

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The employment of solar energy in recent years has reached a remarkable edge. It has become even more popular as the cost of fossil fuel continues to rise. Energy storage system improves an adjustability and marketability of solar thermal and allowing it to produce electricity in demand. This study attempted to prepare cordierite/mullite composite ceramics used as solar thermal storage material from calcined bauxite, talcum, soda feldspar, potassium feldspar, quartz, and mullite. The thermal physical performances were evaluated and characterized by XRD, SEM, EPMA, and EDS. It was found that the optimum sintering temperature was 1280°C for preparing, and the corresponding water adsorption was 11.25%, apparent porosity was 23.59%, bulk density was 2.10 mg·cm−3, bending strength was 88.52 MPa. The residual bending strength of specimen sintered at 1280°C after thermal shock of 30 times decreased to be 57 MPa that was 36% lower than that before. The thermal conductivity of samples sintered at 1280°C was tested to be 2.20 W·(m·K)−1 (26°C), and after wrapped a PCM (phase change materials) of K2SO4, the thermal storage density was 933 kJ·kg−1 with the temperature difference (ΔT) ranged in 0‐800°C. The prepared cordierite/mullite composite ceramic was proved to be a promising material for solar thermal energy storage.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Preparation and performance study of cordierite/mullite composite ceramics for solar thermal energy storage

Zhang

et al. 2016

Int J Applied Ceramic Tech

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“…In our previous works, the core-shell particles were formed for PMMA [31] and PDVB [18][19][20][21]26,28,31,32] shells whereas most of the obtained PS [31] microcapsule were broken after washing with 2-propanol. The capsule shapes were quite different between PDVB/RT27 and PMMA/RT27 where the nonspherical with a dent and multiple dents were observed for PDVB and PMMA shells, respectively.…”

Section: Resultsmentioning

confidence: 99%

Latent Heat Enhancement of Paraffin Wax in Poly(divinylbenzene-co-methyl methacrylate) Microcapsule

Namwong

Noppalit

Okubo

et al. 2015

Polymer-Plastics Technology and Engineering

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The preparation of divinylbenzene (DVB)-methyl methacrylate (MMA) copolymer microcapsule encapsulated Rubitherm27 (RT27) P(DVB-co-MMA)/RT27 used as heat storage material by the microsuspension polymerization was studied to improve the latent heats of the encapsulated RT27 with sufficient polymer shell strength. Percent loading of RT27 and DVB:MMA ratio were optimized. The optimal condition was 30% loading of RT27 and 30:70 (% w/w) of DVB:MMA ratio. The nonspherical microcapsules with a dent having core-shell morphology were obtained. The thermal properties of the encapsulated RT27 in the P(DVB-co-MMA)/RT27 capsules were measured by thermogravimetric analyzer and differential scanning calorimeter. The heats of melting (DH m ; 153 J/g-RT27) and crystallization (DH c ; 164 J/g-RT27) of the encapsulated RT27 in the prepared copolymer capsules were higher than those in PDVB and closed to those of bulk RT27 (162 and 168 J/g-RT27 for DH m and DH c , respectively).

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“…For example, the interfacial polymerization of polyurea microcapsules containing essential oils, phase inversion precipitation of polysulfone microcapsule encapsulated vanillin microcapsules and in situ polymerization of melamine resin microcapsules containing fragrant oil have been reported. One of the most famous techniques for microcapsule preparation is an environmentally friendly technique − suspension polymerization . The core − shell particles obtained could be prepared via an internal phase separation mechanism.…”

Section: Introductionmentioning

confidence: 99%

Innovative and high performance synthesis of microcapsules containing methyl anthranilate by microsuspension iodine transfer polymerization

Pansuwan

Chaiyasat

2017

Polym. Int.

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In this research, preparations of polymer microcapsule encapsulated methyl anthranilate (MA) as an essential oil model by both microsuspension conventional radical polymerization (ms CRP) and microsuspension iodine transfer polymerization (ms ITP)using methyl methacrylate (MMA) and ethylene glycol dimethacrylate (EGDMA) copolymer as the polymer shell were studied. In the case of ms CRP, a large amount of free polymer particles nucleated in aqueous medium were obtained. Using ms ITP, the free polymer particle formation was significantly depressed. Iodoform (CHI 3 ) as a chain transfer agent with 0.8 wt% relative to the monomer, such a phenomenon was not observed. Various emulsifiers (oleic acid, Span 80 and PEG 30 dipolyhydroxystearate (DPHS)) with low hydrophile-lipophile balance value were used to retain MA in the monomer droplets or polymerizing particles. DPHS is the most effective emulsifier to retain MA in microcapsules giving 58% encapsulation at 20 wt% of DPHS relative to MA. In addition, from the controlled release study, only 55 wt% of the encapsulated MA was released by 90 days. Polymer microcapsule encapsulated MA using an MMA-EGDMA copolymer shell with a high percentage of encapsulation and without free polymer particles was successfully prepared for the first time. Based on slow release of the encapsulated MA, the prepared microcapsules could be used in various applications.

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Do encapsulated heat storage materials really retain their original thermal properties?

Cited by 46 publications

References 55 publications

Preparation and performance study of cordierite/mullite composite ceramics for solar thermal energy storage

Preparation and performance study of cordierite/mullite composite ceramics for solar thermal energy storage

Latent Heat Enhancement of Paraffin Wax in Poly(divinylbenzene-co-methyl methacrylate) Microcapsule

Innovative and high performance synthesis of microcapsules containing methyl anthranilate by microsuspension iodine transfer polymerization

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