Keyword search (4,163 papers available)

"Elastomer" Keyword-tagged Publications:

Title Authors PubMed ID
1 Rubber Fatigue Revisited: A State-of-the-Art Review Expanding on Prior Works by Tee, Mars and Fatemi Wang X; Sedaghati R; Rakheja S; Shangguan W; 40219307
ENCS
2 Topology optimization of adaptive sandwich plates with magnetorheological core layer for improved vibration attenuation Zare M; Sedaghati R; 39398530
ENCS
3 Investigation of Macroscopic Mechanical Behavior of Magnetorheological Elastomers under Shear Deformation Using Microscale Representative Volume Element Approach Abdollahi I; Sedaghati R; 38794567
ENCS
4 Modeling and tracking control of dielectric elastomer actuators based on fractional calculus Wu J; Xu Z; Zhang Y; Su CY; Wang Y; 36792481
ENCS
5 Analysis of an Adaptive Periodic Low-Frequency Wave Filter Featuring Magnetorheological Elastomers Jafari H; Sedaghati R; 36772034
ENCS
6 Folding photopolymerized origami sheets by post-curing. He X, Matte CD, Kwok TH 33490875
ENCS
7 Multidisciplinary Design Optimization of a Novel Sandwich Beam-Based Adaptive Tuned Vibration Absorber Featuring Magnetorheological Elastomer. Asadi Khanouki M, Sedaghati R, Hemmatian M 32422988
ENCS
8 Development and assessment of a stiffness display system for minimally invasive surgery based on smart magneto-rheological elastomers. Hooshiar A, Alkhalaf A, Dargahi J 31924050
ENCS

 

Title:Folding photopolymerized origami sheets by post-curing.
Authors:He XMatte CDKwok TH
Link:https://www.ncbi.nlm.nih.gov/pubmed/33490875
DOI:10.1007/s42452-020-04018-w
Publication:SN applied sciences
Keywords:Digital light processingElastomerHinge designOrigamiPost-curing
PMID:33490875 Category:SN Appl Sci Date Added:2021-01-26
Dept Affiliation: ENCS
1 Department of Mechanical, Industrial and Aerospace Engineering, Concordia University, Montreal, Canada.

Description:

Folding photopolymerized origami sheets by post-curing.

SN Appl Sci. 2021; 3(1):133

Authors: He X, Matte CD, Kwok TH

Abstract

The paper presents a novel manufacturing approach to fabricate origami based on 3D printing utilizing digital light processing. Specifically, we propose to leave part of the model uncured during the printing step, and then cure it in the post-processing step to set the shape in a folded configuration. While the cured regions in the first step try to regain their unfolded shape, the regions cured in the second step attempt to keep their folded shape. As a result, the final shape is obtained when both regions' stresses reach equilibrium. Finite element analysis is performed in ANSYS to obtain the stress distribution on common hinge designs, demonstrating that the square-hinge has a lower maximum principal stress than elliptical and triangle hinges. Based on the square-hinge and rectangular cavity, two variables-the hinge width and the cavity height-are selected as principal variables to construct an empirical model with the final folding angle. In the end, experimental verification shows that the developed method is valid and reliable to realize the proposed deformation and 3D development of 2D hinges.

PMID: 33490875 [PubMed]




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