Your search keyword '"CHANGE MATERIALS PCMS"' showing total 4 results

1. Phase change materials for life science applications

Author

Zare, Mina, Mikkonen, Kirsi S., Department of Food and Nutrition, Helsinki Institute of Sustainability Science (HELSUS), and Food Materials Science Research Group

Subjects

CHANGE MATERIALS PCMS, THERMAL-ENERGY STORAGE, CHANGE MICROCAPSULES, 416 Food Science, CHALLENGES, POLYETHYLENE-GLYCOL, 216 Materials engineering, FABRICATION, PROTECTION, 221 Nano-technology, SOLID LIPID NANOPARTICLES, TEMPERATURE, SYSTEM

Abstract

Phase change materials (PCMs) are a class of thermo-responsive materials that can be utilized to trigger a phase transition which gives them thermal energy storage capacity. Any material with a high heat of fusion is referred to as a PCM that is able to provide cutting-edge thermal storage. PCMs are commercially used in many applications like textile industry, coating, and cold storage typically for heat control. These intriguing substances have recently been rediscovered and employed in a broad range of life science applications, including biological, human body, biomedical, pharmaceutical, food, and agricultural applications. Benefiting from the changes in physicochemical properties during the phase transition makes PCMs also functional for barcoding, detection, and storage. Paraffin wax and polyethylene glycol are the most commonly studied PCMs due to their low toxicity, biocompatibility, high thermal stability, high latent enthalpy, relatively wide transition temperature range, and ease of chemical modification. Current challenges in employing PCMs for life science applications include biosafety and/or engineering difficulties. The focus of this review article is on the life science applications, evaluation, and safety aspects of PCMs. Herein, the advances and the potential of employing PCMs as a versatile platform for various types of life science applications are highlighted.

Published

2023

2. Estimating the state of charge in a latent thermal energy storage heat exchanger based on inlet/outlet and surface measurements

Author

Ilya T'Jollyn, Kenny Couvreur, Michel De Paepe, Wim Beyne, and Steven Lecompte

Subjects

NUMERICAL-ANALYSIS, Technology and Engineering, Materials science, Energy Engineering and Power Technology, Thermal energy storage, Industrial and Manufacturing Engineering, Energy storage, Numerical model, Heat exchanger, PHASE-CHANGE MATERIALS, CONDUCTIVITY, geography, geography.geographical_feature_category, BUILDINGS, State of charge, Estimator, Mechanics, Inlet, Phase-change material, PORE-SCALE, EFFECTIVENESS-NTU TECHNIQUE, CHANGE MATERIALS PCMS, TUBE, Latent thermal energy storage, State of charge estimators, SYSTEM, BEHAVIOR, Energy (signal processing)

Abstract

The performance of latent thermal energy storage (LTES) heat exchangers is related to the stored energy (i.e. state of charge) during the (dis)charging of the energy storage system. Therefore, measuring the stored energy is crucial to understand the behavior of LTES systems. However, technical considerations often oppose the measurability of the stored energy. The present article presents a case where only measurements at the in- and outlet of the heat transfer fluid and on the outer surface of the heat exchanger were possible. Based on this sparse set of measurements, estimators for the stored energy are developed. To test these estimators, a finite volume model of the LTES heat exchanger is made. The finite volume model is fitted by comparing the predicted heat transfer fluid outlet temperature for 36 experiments. The energy estimators are compared to simulation results. The estimators for the stored energy in the heat transfer fluid, metal and phase change material obtain an average deviation of respectively 0.5 %, 3.9 % and 0.6 % with the stored energy predicted by the finite volume model. The estimator for the stored energy in the heat transfer fluid should be applicable to all LTES heat exchangers while the applicability of the estimators for stored energy in the metal and phase change material depend on small temperature differences between surface and interior of the metal and negligible heat losses.

Published

2022

3. Experimental investigation of solidification in metal foam enhanced phase change material

Author

J Danneels, Özer Bağcı, Wim Beyne, Dieter Daenens, Hugo Canière, M. De Paepe, and Henk Huisseune

Subjects

Materials science, Technology and Engineering, 020209 energy, LATENT-HEAT STORAGE, 02 engineering and technology, Metal foam, Conductivity, 021001 nanoscience & nanotechnology, Thermal energy storage, Phase-change material, Coolant, Phase change materials (PCM), CHANGE MATERIALS PCMS, Thermal conductivity, THERMAL-ENERGY STORAGE, FOOD, PERFORMANCE ENHANCEMENT, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Composite material, 0210 nano-technology, Porosity, CONDUCTIVITY, SYSTEM

Abstract

A major challenge for the use of phase change materials (PCMs) in thermal energy storage (TES) is overcoming the low thermal conductivity of PCM’s. The low conductivity gives rise to limited power during charging and discharging TES. Impregnating metal foam with PCM, however, has been found to enhance the heat transfer. On the other hand, the effect of foam parameters such as porosity, pore size and material type has remained unclear. In this paper, the effect of these foam parameters on the solidification time is investigated. Different samples of PCM-impregnated metal foam were experimentally tested and compared to one without metal foam. The samples varied with respect to choice of material, porosity and pore size. They were placed in a rectangular cavity and cooled from one side using a coolant flowing through a cold plate. The other sides of the rectangular cavity were Polymethyl Methacrylate (PM) walls exposed to ambient. The temperature on the exterior walls of the cavity was monitored as well as the coolant flow rate and its temperature. The metal foam inserts reduced the solidification times by at least 25 %. However, the difference between the best performing and worst performing metal foam is about 28 %. This shows a large potential for future research. This study has received funding from European Union’s Horizon 2020 research and innovation programme under grant agreement Nº 657466 (INPATH-TES).

Published

2017

4. Organic Phase Change Materials And Their Textile Applications: An Overview

Author

Önder, Emel, SARIER, NİHAL, TR114920, and TR10598

Subjects

Latent Isı Depolama, Diferansiyel Tarama Kalorimetrisi, Textile, Change Materials Pcms, Tekstil, Poly(ethylene oxide) Fractions, Yüksek Yoğunluklu Polietilen, Microencapsulation, Termal Enerji Depolama, Thermal-Energy Storage, Supercooling, Differential Scanning Calorimetry, Shape-Stabilized Pcm, Latent-Heat Storage, In-Situ Polymerization, Poli (etilen oksit) Kısımlar, Termal İletkenlik, İn-situ Polimerizasyon, Thermal Conductivity, Fatty-acid Esters, Yağ Asidi Esterleri, Microencapsulated n-octadecane, Dinamik Isı Depolama, Mikrokapsüllü n-oktadekan, Değişim Materyalleri, PCM, Aşırı Soğuma, Dynamic Heat Storage, Mikrokapsülleme, High-Density Polyethylene

Abstract

An organic phase change material (PCM) possesses the ability to absorb and release large quantity of latent heat during a phase change process over a certain temperature range. The use of PCMs in energy storage and thermal insulation has been tested scientifically and industrially in many applications. The broad based research and development studies concentrating on the characteristics of known organic PCMs and new materials as PCM candidates, the storage methods of PCMs, as well as the resolution of specific phase change problems, such as low thermal conductivity and supercooling have been reviewed. The potential industrial applications of PCMs in textiles and clothing systems, the methods of PCM integration into textiles and the methods of evaluating their thermal properties are also presented in this study. (C) 2012 Elsevier B.V. All rights reserved.

Published

2012