FSI and non-FSI studies on a functionally graded temperature-responsive hydrogel bilayer in a micro-channel

Mazaheri, Hashem; Khodabandehloo, Amin

doi:10.1088/1361-665x/ac36ae

Cited by 2 publications

(1 citation statement)

References 61 publications

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“…They modeled cylindrical FG hydrogels with different crosslink densities along the radius. Furthermore, in another study, Mazaheri et al [96] investigated the swelling of photo-thermal-sensitive cylindrical polyelectrolyte hydrogel micro-valves and proposed an analytical solution for the swelling of hydrogel cylinders under temperature variations and different light intensities. Ayra et al [97] studied the behavior of a temperature-sensitive hydrogel microchannel.…”

Section: Research On Computational Fluid Dynamics Applied To Hydrogelmentioning

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: Research On Computational Fluid Dynamics Applied To Hydrogelmentioning

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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Analytic and Finite Element Studies on Deformation of Bilayers with a Functionally Graded PH-Responsive Hydrogel Layer

Khodabandehloo

Mazaheri

2022

Int. J. Appl. Mechanics

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Due to their wide application, responsive hydrogel bilayers have recently persuaded researchers to develop efficient tools to design these attractive structures. In this work, the deformation of a bilayer comprising a neutral elastomeric layer and a functionally graded (FG) pH-responsive one is investigated. The material properties of the FG hydrogel layer vary in the thickness direction. An analytical technique is developed to predict the behavior of the bilayer. To predict the pH-responsive layer behavior, a second-order ordinary differential equation (ODE) is formulated and solved such that the relevant boundary conditions are satisfied, resulting in solving the governing equations related to this layer. Also, for the under-study bilayer, numerical simulation of the considered problem is performed using the finite element method (FEM) — implementing a user-defined subroutine of UHYPER — through ABAQUS. The bending semi-angle, radial, and tangential stresses of the bilayer are studied in some cases via the proposed analytical technique and FEM. The results of both methods indicated excellent conformity. Furthermore, the effect of changes in thickness ratios of the layers was examined. Lastly, the cross-linking density of the hydrogel layer and some other parameters were studied to investigate their influence on the bilayer deformation and specify the optimal values of some of those parameters for the considered bilayers.

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FSI and non-FSI studies on a functionally graded temperature-responsive hydrogel bilayer in a micro-channel

Cited by 2 publications

References 61 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

Analytic and Finite Element Studies on Deformation of Bilayers with a Functionally Graded PH-Responsive Hydrogel Layer

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