Passive cooling performance of polyacrylamide hydrogel on wooden and brick houses and effect of nanoparticle integration on its mechanical strength

Riaz, Muhammad Arslan Bin; Nasir, Muhammad Ali; Nauman, Saad; Amin, Salman; Mehmood, Faisal; Anwar, Osama Bin; Hafeez, Osama; Abid, Temoor

doi:10.1080/14658011.2021.1898880

Cited by 7 publications

(1 citation statement)

References 24 publications

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“…The structure has the potential for food and drug preservation and the temperature regulation of building structures in areas with limited power resources. Another study provided by Arslan et al [48] found that polyacrylamide hydrogels can effectively cool timber structures and masonry houses without relying on active cooling. They enhanced the mechanical strength of the hydrogels by adding nanoparticles and found that dual-network hydrogels provided better strength and cooling over extended periods of time.…”

Section: Building Energy Consumption Savingmentioning

confidence: 99%

Advancements and Prospects of Hydrogel Sweat Cooling Technology in Multiphase Heat Transfer Applications: A Review

Xu,

Li,

et al. 2024

Energies

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Hydrogel sweat cooling is one of the leading areas in the study of multiphase heat transfer. In this study, the principles, applications, current research status, and future trends of hydrogel sweat cooling technology are comprehensively reviewed. By combing through and analyzing the relevant literature, the research progress in hydrogel sweat cooling is presented from the application perspective, including its use in electronic devices, buildings, and clean-energy facilities. The principle of each application is illustrated, the research status is established, and pros and cons are proposed. To provide inspiration for future research, the development trend is set out. Our literature review indicates that research on advanced hydrogels is the most promising research direction, including studies on the effect of environmental and indoor factors on sweat cooling performance through numerical, experimental, and theoretical means. Challenges for future research mainly include conducting hydrogel numerical analysis which can be experimentally verified, developing advanced hydrogels in a green way, and achieving the precise regulation of hydrogel control through intelligent methods. Interdisciplinary integration might be promising as well due to the fact that it can reveal the hydrogel sweat cooling mechanism from a different perspective. This study aims to promote multiphase cooling technology in exploring the application of hydrogels in energy utilization criteria.

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Section: Building Energy Consumption Savingmentioning

confidence: 99%

Advancements and Prospects of Hydrogel Sweat Cooling Technology in Multiphase Heat Transfer Applications: A Review

Xu,

Li,

et al. 2024

Energies

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Hydrogel use in burn therapy, thermal management, wastewater treatment and fire fighting: a review

You,

Xue,

et al. 2023

Environ Chem Lett

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Recent progress in the conversion of agricultural waste into functional materials

Nqoro,

Taziwa,

Popoola

2023

Biomass Conv. Bioref.

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Agricultural waste is enriched with a variety of environmentally friendly materials that can potentially boost economic growth, reduce the spread of contagious diseases, and serve as a carbon-free renewable energy bioresource. Biopolymers produced from agricultural waste have a range of applications in medicine, agriculture, pharmaceutics, and industrial factories. The chemical extraction of biopolymers from biomass requires a series of alternating alkali, acid, and alkali treatments at controlled temperatures. Chemical extraction of plant-based biopolymers requires elevated temperatures (70–100°C), while for animal and sea organism-based biopolymers, moderate temperatures of 25–60°C are used. The obtained biopolymers are functionalized into various materials for application in a wide range of industries. The reported functional materials are loaded with inorganic nanomaterials, plant extracts, and organic compounds, which resulted in a synergistic effect and enhanced activity of the materials. Several researchers have synthesized biopolymers with synthetic polymers to improve their bioavailability, tensile strength, shelf life, and UV adsorption. This review article reports the extraction techniques of biopolymers from agricultural waste and their application in wound healing, water treatment, food storage, passive cooling, and cosmetics. The dearth of scientific articles on the applications of biopolymers generated from agricultural waste produced from food crops grown in Africa is a motivation for the present compilation.

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Passive cooling performance of polyacrylamide hydrogel on wooden and brick houses and effect of nanoparticle integration on its mechanical strength

Cited by 7 publications

References 24 publications

Advancements and Prospects of Hydrogel Sweat Cooling Technology in Multiphase Heat Transfer Applications: A Review

Advancements and Prospects of Hydrogel Sweat Cooling Technology in Multiphase Heat Transfer Applications: A Review

Hydrogel use in burn therapy, thermal management, wastewater treatment and fire fighting: a review

Recent progress in the conversion of agricultural waste into functional materials

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