New shape‐stabilized phase change materials obtained by single‐screw extruder

Salgado-Pizarro, Rebeca; Ulldemolins, G.; Navarro, María Elena; Palacios, Anabel; Calderón, Alejandro; Ding, Yulong; Fernández, A. Inés; Barreneche, Camila

doi:10.1002/est2.268

Cited by 7 publications

(2 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Salgado‐Pizarro et al. found that shape‐stabilising PCMs with HDPE and Polyoxymethylene (POM) whilst adding carbon graphite and magnesium hydroxide through extrusion can obtain a chemically stable PCM with several potential applications, e. g. thermal indoor comfort in buildings [126] . However, researchers need to conduct more studies regarding how the extrusion parameters affect the TES performance.…”

Section: Energy‐saving Buildings With Pe‐pcmsmentioning

confidence: 99%

Recent Progress in Polyethylene‐enhanced Organic Phase Change Composite Materials for Energy Management

Wu,

Yeo,

Wang

et al. 2023

Chemistry An Asian Journal

View full text Add to dashboard Cite

Phase Change Materials (PCMs) are utilized to regulate temperature and store thermal energy in various industries such as infrastructure, electronics, solar power, and more. However, they face several limitations, such as leakage, poor thermal properties, incompatibility, as well as high flammability. Polyethylene (PE) is one of many polymers explored to enhance the desirable properties of PCMs, due to their versatile properties such as high strength, durability, chemical resistance, and low cost. The combination of PCMs and PE can be used to create composite materials, through micro/nano-encapsulation, melt-blending, formation of composites and with proper additives. They create enhanced thermal energy storage properties and in the meantime, benefited from the mechanical properties of the PE. This review provides a concise summary of the recent developments regarding PE-enhanced PCMs and provides insights into possible topics for further investigation. We summarised enhancement methods based on commonly adopted types of PEs, such as encapsulation, melt-blending, hot pressing, extrusion, and 3D printing. We then elaborate on how these PE-PCM composites are effectively utilised for heat management applications and the potential future directions in energy-saving buildings, electronic devices, and energy storage systems.

show abstract

Section: Energy‐saving Buildings With Pe‐pcmsmentioning

confidence: 99%

Recent Progress in Polyethylene‐enhanced Organic Phase Change Composite Materials for Energy Management

Wu,

Yeo,

Wang

et al. 2023

Chemistry An Asian Journal

View full text Add to dashboard Cite

show abstract

“…8 Solid-to-liquid PCMs (or vice versa) are the most common materials used to store energy due to their ease of contain. 9 PCMs have high phase change enthalpy, 10 controllable volume shape, 11 and so, solid-liquid (or vice-versa) PCMs are the most appropriate heat storage materials option. 12 At heating (charging phase), PCM melts when its temperature rises to reach the degree of melting, it absorbs its latent heat of melting at that temperature, and continues absorbing heat until it melts completely to the liquid phase, the same process is reversed with heat rejection during (discharging phase) that includes solidification process till the liquid PCM changes to a solid state after the rejection of all latent heat of solidification.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of two solar air heaters, with and without employing PCM

Midhat,

Aljubury

2024

Energy Storage

View full text Add to dashboard Cite

In the present study, an experimental test was conducted to investigate the energetic performance of a novel designed solar air heaters (SAHs), with, and without phase change material (PCM). Two identical SAHs were fabricated and tested to compare their performance. The first heater is a jacket‐tube solar air heater (SAH 1), while the second heater is similar to the first but filled with PCM (SAH 2). Experimental results showed that increasing air flow rate increases the daily thermal efficiency. Thermal energy during day hours can be stored in the PCM and used after sunset. SAH 2 gave an additional operating time after sunset for 4 hours at 0.01 kg/s, 2.5 hours at 0.035 kg/s, and 1 hour at 0.06 kg/s. Maximum improvement in the daily thermal efficiency was 15% at SAH 2, more than SAH 1 at 0.01 kg/s air flow rate. Employing PCM, as so as increasing air flow rate can reduce the daily thermal losses.

show abstract

Latent heat storage bio‐composites from egg‐shell/PE/PEG as feasible eco‐friendly building materials

Trigui,

Aribia,

Akrouti

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

Integrating phase change materials (PCMs), which store thermal energy as latent heat, into renewable energy production is an efficient way to harness solar energy. Thereby, the aim of this work is to develop convenient and efficient method to prepare a bio‐composite phase change materials (BCPCMs) that are eco‐friendly and cheap. The polyethylene glycol (PEG) with large latent heat was used as PCM, eggshell powder (ES) as an energy storage material (bio‐energy resources/bio‐waste is converted into useful energy storage material), the low‐density polyethylene (PE) performed as the supporting material and powder graphite (G) was the additives for improving the thermal conductivity. According to thermal gravimetric analysis (TGA), the use of ES and G improved the thermal stability of BCPCM. On the other hand, the results of the differential calorimetric analysis (DSC) showed that BCPCM6 with the addition of 5 wt% of graphite filler in the mixture PEG/PE/ES (70/20/5 wt%) provides excellent thermal stability and high energy storage density per unit mass. In light of its high latent heat storage capacity of 120.1 J/g as well as its ability to prevent PEG exudation, BCPCM ensures higher thermal conductivity and shape stability during phase transition than ordinary PCM. Significant enhancement in melting‐solidification time shows an improvement in Thermal Energy Storage (TES) response time to the demand by adding ES and G respectively to the PCM. Based on the obtained results, the BCPCM as a potential candidate for an application in buildings of hot and dry climates.Highlights Shape‐stabilized BCPCMs were prepared by blending and impregnating method. The BCPCM combines a high storage capacity and high heat propagation rate. BCPCM6 provides excellent thermal stability and high energy storage density. Enhancement in melting‐solidification time by adding ES and G to the PCM. BCPCM as a candidate for an application in buildings of hot and dry climates.

show abstract

New shape‐stabilized phase change materials obtained by single‐screw extruder

Cited by 7 publications

References 46 publications

Recent Progress in Polyethylene‐enhanced Organic Phase Change Composite Materials for Energy Management

Recent Progress in Polyethylene‐enhanced Organic Phase Change Composite Materials for Energy Management

Experimental investigation of two solar air heaters, with and without employing PCM

Latent heat storage bio‐composites from egg‐shell/PE/PEG as feasible eco‐friendly building materials

Contact Info

Product

Resources

About