Molecular Simulations of Adsorption and Thermal Energy Storage of Mixed R1234ze/UIO-66 Nanoparticle Nanofluid

Wang, Qiang; Tang, Shengli; Tian, Sen; Wei, Xiaojian; Peng, Tiefeng

doi:10.1155/2019/5154173

Cited by 3 publications

(1 citation statement)

References 30 publications

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“…[3,4] At present, many porous materials can be used as adsorbents for AHT, including silica gel, [5] activated carbon, [6,7] zeolite, [8] aluminum phosphate, [9,10] and metal-organic framework materials (MOFs). [11][12][13][14] In comparison with silica gel, zeolite, and other traditional porous materials, MOFs have much higher specific surface area [15] and pore volume, [16] as well as the characteristic of adjustable pore structure. [17,18] Because of these properties, MOFs have substantial advantages for AHT applications.…”

Section: Introductionmentioning

confidence: 99%

Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications

Liu

et al. 2022

Chinese Phys. B

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UiO-66 is a potential material for adsorption heat transformation (AHT) with high specific surface area, and excellent thermal and chemical stability. However, the low water adsorption capacity of UiO-66 in the low relative pressure range (0<P/P0<0.3) limits its application in AHT. We prepared the UiO-66 modified by MgCl2 with the methods of solvothermal and impregnation, and studied their water vapor adsorption performance and heat storage capacity. Attributed to the extremely high saturated water uptake and excellent hydrophilicity of MgCl2, the water adsorption performance of UiO-66 was improved, although the introduction of MgCl2 reduced its specific surface area and pore volume. The water adsorption capacity at (P/P0=0.3) and the saturated water adsorption capacity of the UiO-66 (with MgCl2 content of 0.57 wt.%) modified by the solvothermal method was 0.27 g/g and 0.57 g/g at 298 K, respectively, which is 68.8 % and 32.6 % higher than that of pure UiO-66. Compared with pure UiO-66, the water adsorption capacity of the UiO-66 (with MgCl2 content of 1.02 wt.%) modified by the impregnation method is increased by 56.3 % and 14.0 % at the same pressure, respectively. During 20 water adsorption/desorption cycles, the above two materials showed high heat storage densities (~1293 J/g and 1378 J/g). Therein, the UiO-66 modified by the solvothermal method exhibits excellent cyclic stability. These results suggest that the introduction of an appropriate amount of MgCl2 makes UiO-66 more suitable for AHT applications.

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Section: Introductionmentioning

confidence: 99%

Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications

Liu

et al. 2022

Chinese Phys. B

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An updated review of nanofluids in various heat transfer devices

Okonkwo

Wole‐Osho

Almanassra

et al. 2020

J Therm Anal Calorim

236

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The field of nanofluids has received interesting attention since the concept of dispersing nanoscaled particles into a fluid was first introduced in the later part of the twentieth century. This is evident from the increased number of studies related to nanofluids published annually. The increasing attention on nanofluids is primarily due to their enhanced thermophysical properties and their ability to be incorporated into a wide range of thermal applications ranging from enhancing the effectiveness of heat exchangers used in industries to solar energy harvesting for renewable energy production. Owing to the increasing number of studies relating to nanofluids, there is a need for a holistic review of the progress and steps taken in 2019 concerning their application in heat transfer devices. This review takes a retrospective look at the year 2019 by reviewing the progress made in the area of nanofluids preparation and the applications of nanofluids in various heat transfer devices such as solar collectors, heat exchangers, refrigeration systems, radiators, thermal storage systems and electronic cooling. This review aims to update readers on recent progress while also highlighting the challenges and future of nanofluids as the next-generation heat transfer fluids. Finally, a conclusion on the merits and demerits of nanofluids is presented along with recommendations for future studies that would mobilise the rapid commercialisation of nanofluids.

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Molecular modelling of energy storage performance on metal organic frameworks/ethane nanoparticles nanofluids mixtures and derivatives

Tiomo,

Madu,

Ezema

et al. 2024

Materials Today Communications

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Molecular Simulations of Adsorption and Thermal Energy Storage of Mixed R1234ze/UIO-66 Nanoparticle Nanofluid

Cited by 3 publications

References 30 publications

Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications

Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications

An updated review of nanofluids in various heat transfer devices

Molecular modelling of energy storage performance on metal organic frameworks/ethane nanoparticles nanofluids mixtures and derivatives

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Molecular Simulations of Adsorption and Thermal Energy Storage of Mixed R1234ze/UIO-66 Nanoparticle Nanofluid

Cited by 3 publications

References 30 publications

Water adsorption performance of UiO-66 modified by MgCl2 for heat transformation applications

Water adsorption performance of UiO-66 modified by MgCl2 for heat transformation applications

An updated review of nanofluids in various heat transfer devices

Molecular modelling of energy storage performance on metal organic frameworks/ethane nanoparticles nanofluids mixtures and derivatives

Contact Info

Product

Resources

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Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications

Water adsorption performance of UiO-66 modified by MgCl₂ for heat transformation applications