Development of Corn-Oil Ester and Water Mixture Phase Change Materials for Low Temperature Refrigeration Applications

To strengthen the heat and mass transfer capacity and improve the temperature regulation rate, potential storage is taken as the research object in this research to study the heat energy storage of the battery in the low temperature environment. Lattice Boltzmann method is adopted to study the heat energy storage influence mechanism of the temperature regulation system of the low temperature phase-change materials. In addition, the influence of different physical parameters (thermal conductivity and latent heat of phase change) on the thermal insulation of the system in the process of temperature control is revealed. The results show that the mechanism of heat and mass transfer in the process of heat storage and temperature control is related to the different physical properties of phase change materials. The decrease of thermal conductivity and the increase of latent heat of phase change materials will greatly increase the effect of heat energy storage. Therefore, under the action of phase change latent heat, phase change material can effectively extend the holding time of the battery in the low temperature environment.

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Feasibility of using microencapsulated phase change materials as filler for improving low temperature performance of rubber sealing materials

Soft Matter ◽

10.1039/c7sm01623a ◽

2017 ◽

Vol 13 (42) ◽

pp. 7760-7770 ◽

Cited By ~ 2

Author(s):

Avinash Tiwari ◽

Sergey N. Shubin ◽

Ben Alcock ◽

Alexander B. Freidin ◽

Brede Thorkildsen ◽

...

Keyword(s):

Low Temperature ◽

Phase Change ◽

Phase Change Material ◽

Phase Change Materials ◽

Microencapsulated Phase Change Material ◽

Temperature Performance ◽

Sealing Material ◽

Microencapsulated Phase Change Materials ◽

Change Material ◽

Sealing Materials

The feasibility of microencapsulated phase change material (MEPCM) as filler in a rubber sealing material to improve sealing under transient cooling (in a so-called blowdown scenario) is investigated here.

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Thermal buffering performance of composite phase change materials applied in low-temperature protective garments

International Journal of Modern Physics B ◽

10.1142/s0217979217441021 ◽

2017 ◽

Vol 31 (16-19) ◽

pp. 1744102 ◽

Cited By ~ 1

Author(s):

Kai Yang ◽

Mingli Jiao ◽

Yuanyuan Yu ◽

Xueying Zhu ◽

Rangtong Liu ◽

...

Keyword(s):

Low Temperature ◽

Phase Change ◽

Phase Change Materials ◽

Buffering Capacity ◽

Climate Chamber ◽

Functional Textiles ◽

Composite Phase Change Materials ◽

Change Temperature ◽

Thermal Buffering ◽

Change Material

Phase change material (PCM) is increasingly being applied in the manufacturing of functional thermo-regulated textiles and garments. This paper investigated the thermal buffering performance of different composite PCMs which are suitable for the application in functional low-temperature protective garments. First, according to the criteria selecting PCM for functional textiles/garments, three kinds of pure PCM were selected as samples, which were [Formula: see text]-hexadecane, [Formula: see text]-octadecane and [Formula: see text]-eicosane. To get the adjustable phase change temperature range and higher phase change enthalpy, three kinds of composite PCM were prepared using the above pure PCM. To evaluate the thermal buffering performance of different composite PCM samples, the simulated low-temperature experiments were performed in the climate chamber, and the skin temperature variation curves in three different low temperature conditions were obtained. Finally composite PCM samples’ thermal buffering time, thermal buffering capacity and thermal buffering efficiency were calculated. Results show that the comprehensive thermal buffering performance of [Formula: see text]-octadecane and [Formula: see text]-eicosane composite PCM is the best.

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Erythritol Tetra Myristate and Erythritol Tetra Laurate as Novel Phase Change Materials for Low Temperature Thermal Energy Storage

Energy Sources Part A Recovery Utilization and Environmental Effects ◽

10.1080/15567036.2010.516323 ◽

2013 ◽

Vol 35 (14) ◽

pp. 1285-1295 ◽

Cited By ~ 15

Author(s):

A. Sari ◽

A. Karaipekli ◽

R. Eroğlu ◽

A. Biçer

Keyword(s):

Energy Storage ◽

Low Temperature ◽

Phase Change ◽

Thermal Energy ◽

Thermal Energy Storage ◽

Phase Change Materials

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Performance Evaluation of a Solar PV/T Water Heater Integrated with Inorganic Salt Based Energy Storage Medium

Journal of New Materials for Electrochemical Systems ◽

10.14447/jnmes.v23i3.a09 ◽

2020 ◽

Vol 23 (3) ◽

pp. 213-220

Author(s):

R Prakash ◽

B Meenakshipriya ◽

S Vijayan ◽

R Kumaravelan

Keyword(s):

Energy Storage ◽

Phase Change ◽

Phase Change Materials ◽

Electrical Energy ◽

Electrical Performance ◽

Back Side ◽

Solar Pv ◽

Storage Medium ◽

Pv Module ◽

Mixture Phase

Thermal and Electrical performance of solar PV/T hybrid water heating system using salt mixture phase change materials in storage tank is analyzed in this study. Compare to all conventional type heaters, the solar PV/T hybrid module collector has ability to produces both electrical energy from PV module and utilizes incident solar energy to heat the water. The sheet and tube type absorber is used to heat up the tube which is attached at the back side of PV module and transfer the heat to flowing water and the electrical energy is tested by connecting the DC load on the PV terminals under glazed and unglazed modes respectively. To enhance the thermal performance, energy storage medium is used as phase change materials at good proportion in the tank. The thermo physical properties of PCM are analyzed by Differential Scanning Calorimetry. This experimental testing is conducted from 8.00 to 17.00 IST in various sunny days and results are compared for glazed and unglazed conditions. The results shows that the average water temperature easily reaches 38-45°C and the final temperature of water never dropped below 34°, the temperature of PCM is 45.6oC, which is 5oC higher than outlet. The amount of heat stored using PCM in tank is 16.86% greater than no-PCM in the tank for constant 0.01 kg/s mass flow rate. The daily average electrical efficiency is 6.4% under glazed mode and 8.8% under unglazed conditions.

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