Phase change materials (PCMs) having a large latent heat during solid-liquid phase transition are promising for thermal energy storage applications. However, the relatively low thermal conductivity of the majority of promising PCMs (<10 W/ (m ⋅ K)) limits the power density and overall storage efficiency. Developing pure or composite PCMs

New concept of solar-driven phase change material-integrated interfacial evaporation. • First-time employment of latent heat storage method into interfacial evaporation. • Realization of a combined cycle of energy harvesting, heat recovery & releasing. • Durable and

The innovative application of the micro heat pipe arrays in the cold-side heat dissipation of a thermoelectric module The results show that when the phase change energy storage unit is in

Phase change materials that can absorb or release large amounts of heat during phase transition, play a critical role in many important processes, including heat dissipation, thermal energy

Box-type phase change energy storage thermal reservoir phase change materials have high energy storage density; the amount of heat stored in the same volume can be 5–15 times that of water, and the volume

A typical problem faced by large energy storage and heat exchange system industries is the dissipation of thermal energy. Management of thermal energy is difficult because the concentrated heat density in electronic systems is not experimental. 1 The great challenge of heat dissipation systems in electronic industries is that the high

Combining phase change capsules with polymeric matrices is expected to develop flexible composites with both heat storage capacity and thermal reliability, which can be applied in various fields, including chip heat dissipation [15] and battery thermal management [16, 17].

Phase change materials (PCMs) are candidates as TIM for next-generation electronic devices due to their excellent latent heat storage. However, some inherent problems of PCMs, such as low thermal conductivity, high solid-state rigidity, and easy leakage, also limit their application in the thermal management of electronic

Polymeric composites containing phase change capsules (PCC) have both heat storage capacity and thermal reliability, thus having important applications. The simulative study facilitates systematic investigations on the effects of the mass fraction and phase change characteristic of the capsules as well as the thermal conductivity of the

Comprehensive lists of most possible materials that may be used for latent heat storage are shown in Fig. 1(a–e), as reported by Abhat [4].Readers who are interested in such information are referred to the papers of Lorsch et al. [5], Lane et al. [6] and Humphries and Griggs [7] who have reported a large number of possible candidates for

The melting of a phase change material in a container of rectangular cross-section with multiple discrete heat sources mounted on one side is investigated for electronics cooling by latent heat energy storage. This numerical study focuses on the thermal management issues that arise when electronic components experience sudden surges in power

Phase change material; HDP Heat dissipation performance TM Thermal management 1. Introduction Battery thermal management with thermal energy storage composites of PCM, metal foam, fin and nanoparticle J Energy Storage, 28 (2020), pp. 866-880 Z.

Phase change material (PCM) cooling is an excellent approach for reducing the excessive temperature of electronic devices. However, the heat transfer capacity of a heat sink is diminished by the low thermal conductivity of a PCM. Although this issue can be ameliorated by using extended pin-fins and nanoparticles, the latent heat

The transient response of the energy storage system to short pulses in power dissipation is studied. Convective cooling using air-cooled heat sinks on the sides of the containment remote from the

The heat dissipation experiment showed that the MPCS with 5%, 8%, and 10% MPCM concentrations increased heat dissipation by 8.7%, 11.1%, and 13.7%, respectively, compared to pure water. This work reports a new strategy through introducing hectorite into phase change fluids to enhance suspension stability.

Phase change material (PCM)-based thermal energy storage significantly affects emerging applications, with recent advancements in enhancing heat capacity and cooling power. This perspective by Yang et al. discusses

In the process of industrial waste heat recovery, phase change heat storage technology has become one of the industry''s most popular heat recovery technologies due to its high heat storage density and almost constant temperature absorption/release process. In practical applications, heat recovery and utilization speed

Experiment study of oscillating heat pipe and phase change materials coupled for thermal energy storage and thermal management Int. J. Heat Mass Transf., 99 ( 2016 ), pp. 252 - 260 View PDF View article View in Scopus Google Scholar

Hence, it is necessary to investigate the heat storage properties of the composite PCM itself, such as the inner temperature distribution and the phase change time. However, most previous studies focused on the surface temperature change of Li-ion battery, which is controlled by the composite PCM thermal management system, but not

Thermal management has become a crucial problem for high-power-density equipment and devices. Phase change materials (PCMs) have great prospects in thermal management applications because of their large capacity of heat storage and isothermal behavior during phase transition. However, low intrinsic thermal conductivity, ease of leakage, and lack

Phase change materials (PCMs) having a large latent heat during solid-liquid phase transition are promising for thermal energy storage applications. However,

Phase change thermal conductive materials have been applied as heat dissipation interface materials in new electronic devices owing to their high thermal conductivity, phase change energy storage performance, low energy consumption, renewability, and long service life. However, it is a huge challenge to achi

This work provides a review of phase change and boiling heat transfer from two perspectives of contact and non-contact. J. Energy Storage, 32 (2020), Article 101837, 10.1016/j.est.2020.101837 View PDF View article View in

A phase change material has been investigated within the battery module to absorb the heat dissipation for reducing the cell temperature during melting progression. Ling et al. [15] proposed an

A highly thermally conductive solid–liquid phase change film can be a potential candidate for the next-generation heat dissipation material by coupling the efficient heat storage

Abstract. Phase change materials (PCMs) utilized for thermal energy storage applications are verified to be a promising technology due to their larger benefits

A potential route to achieving such a goal involves cooling energy storage during low demand and releasing the stored cooling at peak demand times via thermal energy storage (TES). Latent heat thermal

In comparison with sensible heat storage devices, phase change thermal storage devices have advantages such as high heat storage density, low heat dissipation loss, and

Fig. 1 The thermal contr ol system of the satellite payload. The phase change energy storage heat exchanger is consist of 20 layers of PCM, 17l ayers of. internal fluid circuit, and 2 layers of

As a latent thermal storage material, phase change materials (PCM) is based on the heat absorption or release of heat when the phase change of the storage material occurs, which can provides a greater energy density. and have already being

KEYWORDS: phase change energy storage, transient heat dissipation, electronics cooling, pulsed power, phase change material † Submitted for publication in IEEE CPMT, August, 2002, and in revised

The melting and re-solidification of a phase change material in a container of rectangular cross-section with multiple discrete heat sources mounted on one side is investigated for electronics cooling by latent heat energy storage. This numerical study focuses on the thermal management issues that arise when electronic components experience a sudden

Power Level Power requirement of the electronic device is the amount of heat dissipated to a great extent. In an experimental study done by Rehman et al. [], the heat loads were varied as 8 W, 16 W and 24 W by fixing the ambient conditions and volume fraction of the phase change material.They found that as power levels were increased

In order to enhance the thermal conductivity and secondary heat dissipation capability of the phase change material (PCM) in battery thermal management (BTM) applications, a new kind of composite PCM (CPCM) is successfully prepared by constructing a binary thermal conductive skeleton of expanded graphite (EG)/copper

Hydrated salt phase change materials (PCMs) can play an important role in the temperature regulation of buildings by storing and releasing latent heat. However, hydrated salt PCMs are affected by phase separation, supercooling, and leakage, which greatly limit their application. In this study, an innovative modified calcium chloride

Box-type phase change energy storage thermal reservoir phase change materials have high energy storage density; the amount of heat stored in the same volume can be 5–15 times that of water, and the volume can also be 3–10 times smaller than that of ordinary water in the same thermal energy storage case [28]. Compared to the building

Problems involving solid/liquid phase change are encountered in many scientific and engineering applications such as crystal growth [1], latent heat thermal energy storage for thermal control [2