Phase Change Materials Effect on The Thermal Radius and Energy Storage Capacity of Energy Piles: Experimental and Numerical study

Phase change materials (PCM) with their high latent heat capacity have a great ability to store energy during their phase change process. The PCM are renowned for their applications in solar and thermal energy storage systems for the purpose of heating and cooling. However, one of the major drawbacks of PCM is their low thermal conductivity due to which their charging and discharging time reduces along with the reduction in energy storage capacity. This reduction in the energy storage capacity of PCM can be improved by producing organic-inorganic hybrid form-stable PCM, with the combination of two or more PCM together to increase their energy storage capacity. Nanoparticles that possess high thermal conductivity are also doped with these hybrid PCM (HPCM)to improve the effectiveness of thermal conductivity. This paper presents a short review on the applications of HPCM in energy storage and building application. Apart from this a short section of applications of composite PCM (CPCM) is also reviewed with discussions made at the end of each section. Results from the past literature depicted that the application of these HPCM and CPCM enhanced the energy storage capacity and thermal conductivity of the base PCM and selection of a proper hybrid material plays an essential role in their stability. It is presumed that this study will provide a sagacity, to the readers, to investigate their thermophysical properties and other essential applications.

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A novel enhancement of shape/thermal stability and energy-storage capacity of phase change materials through the formation of composites with 3D porous (3,6)-connected metal–organic framework

Chemical Engineering Journal ◽

10.1016/j.cej.2020.124430 ◽

2020 ◽

Vol 389 ◽

pp. 124430 ◽

Cited By ~ 14

Author(s):

Dimberu G. Atinafu ◽

Seong Jin Chang ◽

Ki-Hyun Kim ◽

Wenjun Dong ◽

Sumin Kim

Keyword(s):

Thermal Stability ◽

Energy Storage ◽

Phase Change ◽

Phase Change Materials ◽

Storage Capacity ◽

Metal Organic Framework ◽

Energy Storage Capacity ◽

Metal Organic ◽

Organic Framework

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Using the Analytic Hierarchy Process to Prioritize and Select Phase Change Materials for Comfort Application in Buildings

Mathematical Modelling in Civil Engineering ◽

10.2478/mmce-2014-0003 ◽

2014 ◽

Vol 10 (1) ◽

pp. 21-28 ◽

Cited By ~ 1

Author(s):

Lavinia Gabriela Socaciu ◽

Paula Veronica Unguresan

Keyword(s):

Energy Storage ◽

Phase Change ◽

Thermal Energy ◽

Thermal Energy Storage ◽

Phase Change Materials ◽

Storage Capacity ◽

Heat Storage ◽

Analytic Hierarchy ◽

Energy Storage Capacity ◽

Hierarchy Process

Abstract Phase change materials (PCMs) selection and prioritization for comfort application in buildings have a significant contribution to the improvement of latent heat storage systems. PCMs have a relatively large thermal energy storage capacity in a temperature range close to their switch point. PCMs absorb energy during the heating process as phase change takes place and release energy to the environment in the phase change range during a reverse cooling process. Thermal energy storage systems using PCMs as storage medium offer advantages such as: high heat storage capacity and store/release thermal energy at a nearly constant temperature, relative low weight, small unit size and isothermal behaviour during charging and discharging when compared to the sensible thermal energy storage. PCMs are valuable only in the range of temperature close to their phase change point, since their main thermal energy storage capacity depend on their mass and on their latent heat of fusion. Selection of the proper PCMs is a challenging task because there are lots of different materials with different characteristics. In this research paper the principles and techniques of the Analytic Hierarchy Process (AHP) are presented, discussed and applied in order to prioritize and select the proper PCMs for comfort application in buildings. The AHP method is used for solving complex decisional problems and allows the decision maker to take the most suitable decisions for the problem studied. The results obtained reveal that the AHP method can be successfully applied when we want to choose a PCM for comfort application in buildings.

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Enhancement of the thermal energy storage capacity of a parabolic dish concentrated solar receiver using phase change materials

Journal of Energy Storage ◽

10.1016/j.est.2019.100841 ◽

2019 ◽

Vol 25 ◽

pp. 100841 ◽

Cited By ~ 20

Author(s):

R. Senthil ◽

M. Cheralathan

Keyword(s):

Energy Storage ◽

Phase Change ◽

Thermal Energy ◽

Thermal Energy Storage ◽

Phase Change Materials ◽

Storage Capacity ◽

Energy Storage Capacity ◽

Parabolic Dish ◽

Solar Receiver

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In-situ derived graphene from solid sodium acetate for enhanced photothermal conversion, thermal conductivity, and energy storage capacity of phase change materials

Solar Energy Materials and Solar Cells ◽

10.1016/j.solmat.2019.110269 ◽

2020 ◽

Vol 205 ◽

pp. 110269 ◽

Cited By ~ 5

Author(s):

Dimberu G. Atinafu ◽

Chen Wang ◽

Wenjun Dong ◽

Xiao Chen ◽

Minggang Du ◽

...

Keyword(s):

Thermal Conductivity ◽

Energy Storage ◽

Phase Change ◽

Sodium Acetate ◽

Phase Change Materials ◽

Storage Capacity ◽

Photothermal Conversion ◽

Energy Storage Capacity

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Numerical Investigation and Nondimensional Analysis of the Dynamic Performance of a Thermal Energy Storage System Containing Phase Change Materials and Liquid Water

Journal of Solar Energy Engineering ◽

10.1115/1.4034642 ◽

2016 ◽

Vol 139 (2) ◽

Cited By ~ 2

Author(s):

Hebat-Allah M. Teamah ◽

Marilyn F. Lightstone ◽

James S. Cotton

Keyword(s):

Energy Storage ◽

Phase Change ◽

Thermal Energy ◽

Thermal Energy Storage ◽

Phase Change Materials ◽

Storage Capacity ◽

Dynamic Performance ◽

Water System ◽

Heat Transfer Fluid ◽

Energy Storage Capacity

The dynamic performance of a thermal energy storage tank containing phase change material (PCM) cylinders is investigated computationally. Water flowing along the length of the cylinders is used as the heat transfer fluid. A numerical model based on the enthalpy-porosity method is developed and validated against experimental data from the literature. The performance of this hybrid PCM/water system was assessed based on the gain in energy storage capacity compared to a sensible only system. Gains can reach as high as 179% by using 50% packing ratio and 10 °C operating temperature range in water tanks. Gains are highly affected by the choice of PCM module diameter; they are almost halved as diameter increases four times. They are also affected by the mass flow rate nonlinearly. A nondimensional analysis of the energy storage capacity gains as a function of the key nondimensional parameters (Stefan, Fourier, and Reynolds numbers) as well as PCM melting temperature was performed. The simulations covered ranges of 0.1 < Stẽ < 0.4, 0 < Fo < 600, 20 < Re < 4000, 0.2<(ρCP)*<0.8, and 0.2<θm<0.8.

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