Coupled thermo-mechanical swelling of a thermo-responsive hydrogel hollow cylinder under extension-torsion: Analytical Solution and FEM

Shojaeifard, Mohammad; Dolatabadi, Roshanak; Sheikhi, Sara; Baghani, Mostafa

doi:10.1177/1045389x20951273

Cited by 16 publications

(7 citation statements)

References 42 publications

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“…Furthermore, the rise in swelling value with rising temperature up to a specific point for the hydrogel might be due to an increase in thermal mobility of polymer molecules inside the hydrogels. [26] Figure (3) shows the swelling rate in g water/g dry hydrogel/min. The results shows that the increase of temperature from 25 to 40°C did not show any remarkable effect on the welling rate.…”

Section: Ftirmentioning

confidence: 99%

Swelling Modelling and Kinetics Investigation of Polymer Hydrogel Composed of Chitosan-g-(AA-AM)

Eid¹,

Yehia

Amin

2021

Egypt. J. Chem.

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Swelling is one of the distinct properties and a significant parameter in the characterization of the crosslinked hydrogels. Swelling investigation at different temperatures was conducted for the produced hydrogel of chitosan grafted acrylamide/acrylic acid. Peleg's model is a two parameters model, which can be used to describe the absorption of water or swelling. The data show that the swelling degree increases with temperature until it reaches 60°C, after which it decreases as the temperature rises higher. At RT, 30, 40, 60, and 80 °C, the swelling degree values of 1.4, 1.5,1.4, 2.3 and 0.7 g water/g dry hydrogel were observed after 8 hours. The applied models provided a good agreement with the experimental data with high values of the coefficient of determination ( 2 ). The observed F values and the standard error indicate the validity of the proposed model to describe the swelling of hydrogel at different temperatures. The swelling rate and swelling degree can be expressed using a 4 th degree polynomial. It was concluded that the exponential association equation model represents swelling characteristics better than the others.

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Section: Ftirmentioning

confidence: 99%

Swelling Modelling and Kinetics Investigation of Polymer Hydrogel Composed of Chitosan-g-(AA-AM)

Eid¹,

Yehia

Amin

2021

Egypt. J. Chem.

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“…Hydrogels are three-dimensional polymeric networks that can absorb and expel a huge amount of solvent under external stimuli (Niroumandi et al, 2021a; Shojaeifard and Baghani, 2020) which in turn causes the hydrogel to swell or shrink. Due to the swelling and de-swelling of hydrogels, these materials undergo considerable volume change under a change in external stimuli, including temperature, pH, light intensity, ion concentration, electric and magnetic fields (Kasinathan and Srinivasan, 2018; Shojaeifard and Baghani, 2019; Shojaeifard et al, 2019a, 2019b, 2021). Although conventional hydrogels have various merits to be utilized in diverse applications (Bin et al, 2021; Guenther et al, 2009; Niroumandi et al, 2021b, 2022), the composition of inhomogeneous networks and low polymer content make the hydrogels mechanically weak.…”

Section: Introductionmentioning

confidence: 99%

Programmable self-folding of trilayer and bilayer-hinge structures by time-dependent swelling of tough hydrogels

Shojaeifard

Niroumandi

Baghani

2022

Journal of Intelligent Material Systems and Structures

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Inspired by nature, active materials are used to developed complex 3D configurations considering their specific characteristics. One of the shape-shifting methods in smart structures is utilizing programmable materials in self-folding structures. Hydrogels due to their biocompatibility, controllable functionalities, large reversible deformations, and their sensitivity to environmental stimuli are vital candidates to be used in self-folding structures. To avoid the mechanical weakness of conventional hydrogels, in this paper polyampholyte tough hydrogel is inspected considering a transient electro-chemo-mechanical constitutive model combining a visco-hyperelastic model with Nernst-Planck and Poisson’s equations. After calibrating the material parameters and verifying the accuracy of the model and its implementation, we present two approaches in order to generate self-folding hydrogel-based structures: polymer structure with bilayer hinges and trilayer structure composed of a hydrogel film sandwiched between two elastomer layers. Next, diverse factors are examined in the self-folding of smart structures which conforms with experimental test data, including hydrogel swelling, structure thickness and stiffness, bilayer configuration and composition, the width of the bilayer as well as opening width in trilayer and layers thickness. Finally, several transient self-folding of 2D flat patterns which turn into 3D complex configurations are scrutinized such as the closure of box, pyramids, and flower-shaper gripper.

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“…Employing a UHYPER subroutine, developed in the finite element method (FEM) framework, they showed that their proposed solution has an excellent agreement with FEM results. In another work, Shojaeifard et al (2021) proposed a coupled solution for the same problem, while the temperature distribution was solved simultaneously. Again, their solution was only acceptable for the equilibrium behavior of the hydrogel.…”

Section: Introductionmentioning

confidence: 99%

Transient swelling of cylindrical hydrogels under coupled extension-torsion: Analytical and 3D FEM solutions

Amiri

Baniassadi

Bayat

et al. 2022

Journal of Intelligent Material Systems and Structures

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To design more accurate soft sensors and actuators, there is a significant requirement for the application of complicated deformation conditions. Coupled extension-torsion is a type of deformation which may be utilized in the property characterization of materials with complex behavior such as soft hydrogels. Hydrogels with coupled diffusion and large deformation behavior have intricate kinetics which should be studied in detail. In this work, a robust semi-analytical procedure is proposed to capture the transient behavior of cylindrical hydrogels in combined loading of extension and torsion in different conditions. Moreover, the whole problem with the same conditions is simulated in COMSOL-Multiphysics as a verification framework of the proposed semi-analytical procedure, where comparing the results shows a good agreement. The results demonstrate that the transient behavior of the cylindrical hydrogel under coupled extension-torsion is significantly dependent on the rate of the deformation and material properties. Besides, since the hydrogel undergoes a highly nonlinear swelling in this deformation regime, the simulations predict a complicated reaction force and moment. Visualizing the effect of different parameters engaged in the material shows the robust behavior of the proposed semi-analytical procedure, which can be employed in constitutive models’ calibration as well as in the design and optimization of hydrogels structures.

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Coupled thermo-mechanical swelling of a thermo-responsive hydrogel hollow cylinder under extension-torsion: Analytical Solution and FEM

Cited by 16 publications

References 42 publications

Swelling Modelling and Kinetics Investigation of Polymer Hydrogel Composed of Chitosan-g-(AA-AM)

Swelling Modelling and Kinetics Investigation of Polymer Hydrogel Composed of Chitosan-g-(AA-AM)

Programmable self-folding of trilayer and bilayer-hinge structures by time-dependent swelling of tough hydrogels

Transient swelling of cylindrical hydrogels under coupled extension-torsion: Analytical and 3D FEM solutions

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