Recapitulation on latent heat hybrid buildings

Anand, Ashok; Shukla, Amritanshu; Sharma, Atul

doi:10.1002/er.4920

Cited by 17 publications

(5 citation statements)

References 110 publications

(146 reference statements)

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“…While solar energy, wind energy, and other green energy sources are widely utilized, they encounter challenges like intermittency and uneven distribution . Thermal energy storage technology has emerged as a viable solution to address these challenges and enhance energy utilization. − PCMs have gained significant attention as they offer high thermal storage capacity, cost-effectiveness, and stable performance. − Among them, organic reversible thermochromic materials represent a novel class of smart materials composed of three components: a color-generating agent, a color-developing agent, and an organic solvent. These materials enable the storage and release of thermal energy while providing a visual indication of the energy storage state through color changes. − They find widespread applications not only in construction, , thermoregulated fabrics, and printing inks, but also in thermal management systems for electronic components, lithium-ion batteries, and photovoltaic modules …”

Section: Introductionmentioning

confidence: 99%

Leak-Proof Reversible Thermochromic Microcapsule Phase Change Materials with High Latent Thermal Storage for Thermal Management

Zhou,

Duan

2024

ACS Appl. Energy Mater.

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In this study, a range of reversible thermochromic microencapsulated phase change materials (RTPCMs) encapsulated in silica (SiO 2 ) microcapsules modified with a silane coupling agent was successfully created and produced. The structure and composition of these thermochromic microcapsules were analyzed using Fourier transform infrared (FTIR) spectroscopy and scanning electron microscopy (SEM), while their heat storage capacity was evaluated using differential scanning calorimetry (DSC). SEM images revealed that these microcapsules exhibited a spherical shape with a well-defined core−shell structure. Both DSC and thermogravimetric (TG) analyses demonstrated that microcapsules modified with MPTMS exhibited a favorable enthalpy of phase transition (98.57 J/g). Furthermore, the contact angle of the microcapsules was substantially enhanced, reducing the leakage rate from 6.2% to 1.2%, and the thermal conductivity of the RTPCMs increased by 300% after incorporating the SiO 2 shell layer. Notably, MPTMS-modified microcapsules not only exhibited high latent heat storage and release capacity but also maintained excellent shape stability, thermal stability, phase transition reliability, and durability. Additionally, these microcapsules displayed thermochromic properties during phase transition and were successfully integrated into textile applications. Hence, the dualfunctional microencapsulated phase change materials (PCMs) explored in this study hold significant promise for various thermal management applications, including energy-efficient buildings, smart material coatings, and thermal sensors.

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Section: Introductionmentioning

confidence: 99%

Leak-Proof Reversible Thermochromic Microcapsule Phase Change Materials with High Latent Thermal Storage for Thermal Management

Zhou,

Duan

2024

ACS Appl. Energy Mater.

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“…Using lightweight thermal insulating materials together with PCMs allows increasing significantly the heat-storing properties of thermal insulation due to the latent heat of phase transition, as well as improving significantly the thermal protection characteristics of building envelopes. PCMs are used in the form of additives to lightweight insulation materials to increase the thermal inertia of wall structures [6][7][8]. Studies have been conducted on using PCMs in building envelopes to prevent overheating of internal spaces in summer [9,10].…”

Section: Introductionmentioning

confidence: 99%

Influence of the location of the phase-change material on heating and cooling the heat-insulating layer

Nizovtsev,

Letushko,

Sterlyagov

2023

E3S Web Conf.

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The experimental investigation of thermal parameters during heating and cooling of PCM sample placed at different locations has revealed that the phase transition was accompanied by a significant decrease in the growth rate of the PCM temperature when heating, and a slowdown when cooling. The completion of the phase transition upon heating the PCM sample was accompanied by a sharp increase in the heat flux density at the outer surface of the PCM regardless of its location. The produced experimental results on the change of thermal parameters of the PCM depending on its location will be used to verify the calculation model.

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“…However, along with increased efficiency in the energy sector, significant barriers must also be overcome, including the creation of conventional energy sources, reducing the use of fossil-based fuels, as well as reducing greenhouse gas emissions i.e., CO 2 (carbon dioxide), SO X (oxides of sulfur), CH 4 (methane), NO X (nitrogen oxides). 1 Researchers around the world have been looking for new technologies in the last 30-40 years that will reduce the use of fossil fuels and, lessen the detrimental effects that energy production has on the climate and environment. A practical way of using alternative energy is through energy storage, in addition to conserving energy, energy storage also improves the stability and quality of the energy supply and reduces the variation between supply and demand.…”

Section: Introductionmentioning

confidence: 99%

Development and thermophysical analysis of binary eutectics phase change materials for solar drying application

Pandey

Anand²,

Buddhi³

et al. 2022

F1000Res

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Background: In the past 30–40 years, conflicts over limited conventional energy sources and the negative climate change caused by them have attracted researchers and analysts to new, clean, and green energy technologies. Thereby reducing the consumption of conventional fuel and the negative impact on the climate. The production of alternative energy in the form of thermal energy storage using phase change materials (PCMs) is one of the techniques that not only reduces the gap between the supply and demand of energy but also increases the stability of the energy supply. The tendency of PCMs to melt and solidify over a wide temperature range makes them more attractive for use in many applications. The effective and efficient storage of solar energy by PCM has the potential to significantly advance the use of renewable energy. Methods: Organic non-paraffin compound beeswax (BW) mixed with other non-paraffin compounds stearic acid (SA), Palmitic acid (PA), Myristic acid (MA), and Lauric acid (LA) in different compositions with the help of magnetic stirrer at 50–60°C for 3–4 hours to prepare BWSA, BWPA, BWMA, and BWLA eutectic PCM. Results: Prepared eutectics melt and solidify in the temperature range 36–56°C and with latent heat in the range of 155–211 kJ/Kg. Conclusions: Due to suitable temperature and good latent heat storage range, it is a good choice as thermal energy storage, for solar drying applications.

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Recapitulation on latent heat hybrid buildings

Cited by 17 publications

References 110 publications

Leak-Proof Reversible Thermochromic Microcapsule Phase Change Materials with High Latent Thermal Storage for Thermal Management

Leak-Proof Reversible Thermochromic Microcapsule Phase Change Materials with High Latent Thermal Storage for Thermal Management

Influence of the location of the phase-change material on heating and cooling the heat-insulating layer

Development and thermophysical analysis of binary eutectics phase change materials for solar drying application

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