New Deployable Structures Based on an Elastic Origami Model

Deployable Structures ◽

Elastic Deformations ◽

Simulation Techniques ◽

Folding Simulation ◽

Plate Models

Traditionally, origami-based structures are designed on the premise of “rigid folding,” meaning that the facets and fold lines of origami can be replaced with rigid panels and ideal hinges, respectively. Rigid folding is an important factor in defining origami for mathematicians and geometricians. However, ideal rigid folding is impossible in real structures and every act of folding and unfolding is accompanied by elastic deformations. In this study, we focus on these elastic deformations in order to expand origami into a new method of designing morphing structures. We start by proposing a simple model for evaluating elastic deformation in nonrigid origami structures. In this model, the facets of origami are replaced with plates that are not only rigid but also elastic. This partially elastic origami model has a one-degree-of-freedom mechanism; therefore, its folding process can be described using rigid folding simulation techniques. In this process, the deformations of the elastic plates can be calculated and we can estimate the elastic energy through folding/unfolding. We then apply these methods to deployable plate models constructed of quadrilateral plates and hinges to design new deployable structures. Initial strain is introduced into the elastic parts of the partially elastic origami model and these parts function as actuators for deployment. Then, by using the finite element method, we conduct numerical simulations and confirm the deploying capabilities of the models.

New Deployable Structures Based on an Elastic Origami Model

Journal of Mechanical Design ◽

10.1115/1.4029228 ◽

2015 ◽

Vol 137 (2) ◽

Cited By ~ 17

Author(s):

Kazuya Saito ◽

Akira Tsukahara ◽

Yoji Okabe

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Simple Model ◽

Elastic Deformation ◽

Initial Strain ◽

New Method ◽

Deployable Structures ◽

Elastic Deformations ◽

Plate Models

Traditionally, origami-based structures are designed on the premise of “rigid folding,” However, every act of folding and unfolding is accompanied by elastic deformations in real structures. This study focuses on these elastic deformations in order to expand origami into a new method of designing morphing structures. The authors start by proposing a simple model for evaluating elastic deformation in nonrigid origami structures. Next, these methods are applied to deployable plate models. Initial strain is introduced into the elastic parts as actuators for deployment. Finally, by using the finite element method (FEM), it is confirmed that the proposed system can accomplish the complete deployment in 3 × 3 Miura-or model.

The study of the elastic deformation of a flexible wheel by a cam wave generator

Studia Universitatis Babeș-Bolyai Engineering ◽

10.24193/subbeng.2020.1.6 ◽

2020 ◽

Vol 65 (1) ◽

pp. 51-58

Author(s):

Sava Ianici

Keyword(s):

Numerical Simulation ◽

Finite Element Method ◽

Finite Element ◽

Elastic Deformation ◽

Theoretical Study ◽

Elastic Field ◽

Elastic Deformations ◽

Wave Generator ◽

Two Stages

The paper presents the results of research on the study of the elastic deformation of a flexible wheel from a double harmonic transmission, under the action of a cam wave generator. Knowing exactly how the flexible wheel is deformed is important in correctly establishing the geometric parameters of the wheels teeth, allowing a better understanding and appreciation of the specific conditions of harmonic gearings in the two stages of the transmission. The veracity of the results of this theoretical study on the calculation of elastic deformations and displacements of points located on the average fiber of the flexible wheel was subsequently verified and confirmed by numerical simulation of the flexible wheel, in the elastic field, using the finite element method from SolidWorks Simulation.

Analysis comparative of different simulation techniques by the finite element method in the study of an open die forging process

10.1063/1.4707622 ◽

2012 ◽

Author(s):

F. J. Olivares ◽

A. M. Camacho ◽

M. A. Sebastián

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Forging Process ◽

Simulation Techniques ◽

Die Forging ◽

Open Die Forging ◽

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

Designing of self-deploying origami structures using geometrically misaligned crease patterns

10.1098/rspa.2015.0235 ◽

2016 ◽

Vol 472 (2185) ◽

pp. 20150235 ◽

Cited By ~ 11

Author(s):

Kazuya Saito ◽

Akira Tsukahara ◽

Yoji Okabe

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Numerical Simulations ◽

Elastic Energy ◽

Degrees Of Freedom ◽

New Method ◽

Quadrilateral Mesh ◽

Arbitrary Size ◽

Folding Simulation

Usually, origami-based morphing structures are designed on the premise of ‘rigid folding’, i.e. the facets and fold lines of origami can be replaced with rigid panels and ideal hinges, respectively. From a structural mechanics viewpoint, some rigid-foldable origami models are overconstrained and have negative degrees of freedom (d.f.). In these cases, the singularity in crease patterns guarantees their rigid foldability. This study presents a new method for designing self-deploying origami using the geometrically misaligned creases. In this method, some facets are replaced by ‘holes’ such that the systems become a 1-d.f. mechanism. These perforated origami models can be folded and unfolded similar to rigid-foldable (without misalignment) models because of their d.f. focusing on the removed facets, the holes will deform according to the motion of the frame of the remaining parts. In the proposed method, these holes are filled with elastic parts and store elastic energy for self-deployment. First, a new extended rigid-folding simulation technique is proposed to estimate the deformation of the holes. Next, the proposed method is applied on arbitrary-size quadrilateral mesh origami. Finally, by using the finite-element method, the authors conduct numerical simulations and confirm the deployment capabilities of the models.

The Finite Element Method Applied to Agricultural Engineering: A Review

Current Agriculture Research Journal ◽

10.12944/carj.6.3.08 ◽

2018 ◽

Vol 6 (3) ◽

pp. 286-299

Author(s):

Nara Silveira Velloso ◽

André Luis Gonçalves Costa ◽

Ricardo Rodrigues Magalhães ◽

Fábio Lúcio Santos ◽

Ednilton Tavares de Andrade

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Soil Mechanics ◽

Agricultural Product ◽

Agricultural Engineering ◽

Simulation Techniques ◽

Number Of Publications ◽

Wide Dissemination ◽

The use of numerical simulations has been widespread in many engineering fields and related areas. One of the main numerical methods used in modeling and simulations is the finite element method (FEM). Despite its wide dissemination, especially in mechanical and civil engineering, FEM has high potential to be applied in other areas, such as in agricultural engineering. This paper aims to present a review of the FEM applications in three agricultural engineering areas. This research is focused on agricultural mechanization, agricultural product processing and soil mechanics, since these are agricultural engineering areas with highest number of publications using FEM. As result, it is expected greater FEM dissemination in other agricultural engineering areas. In addition, modeling and simulation techniques can be widely used in order to represent the increasing behavior of agricultural machinery and products from real physical systems.

Topic of the issue: Determination of the processing error during face milling of flat surfaces

10.33920/pro-2-2012-01 ◽

2020 ◽

pp. 9-22

Author(s):

V.L. Kiselev ◽

A. S. Pronin

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Geometric Parameters ◽

Elastic Deformations ◽

Flat Surfaces ◽

The Relationship ◽

Center Distance ◽

Using the finite element method and CAD SolidWorks Simulation, the relationship between the geometric parameters of workpieces and the error in processing flat surfaces of levers caused by elastic deformations of the workpiece due to the application of holding force is established. In this paper, we developed a method for determining the error of processing flat surfaces that occurs from fixing, compiled a model for determining the error by the finite element method, and calculated the error of processing flat surfaces that occurs from fixing for workpieces with different geometric parameters. As a result of the study, the relationship between the value of the center distance of workpieces and the error in processing flat surfaces of levers caused by elastic deformations of the workpiece due to the application of holding forces was determined.

Mathematical Modelling of Shafts in Drives

Communications - Scientific letters of the University of Zilina ◽

10.26552/com.c.2018.4.36-40 ◽

2018 ◽

Vol 20 (4) ◽

pp. 36-40

Author(s):

Petr Hruby ◽

Tomas Nahlik ◽

Dana Smetanova

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Simple Model ◽

Mathematical Modelling ◽

Transfer Matrix Method ◽

Matrix Method ◽

Spectral Properties ◽

Test Model ◽

Torsional Stress ◽

The Finite Element Method

Propeller shafts of the vehicle's drive transmit a torque to relatively large distances. The shafts are basically long and slender and must be dimensioned not only in terms of torsional stress, but it is also necessary to monitor their resistance to lateral vibration.In the paper, a simple model (of the solved problem) is constructed by the method of physical discretization, which is evident from the nature of the centrifugal force fields' influence on the spectral properties of the shaft. An analytical solving of speed resonances prop shafts test model (whose aim is to obtain values for verification subsequently processed models based on the transfer-matrix method and the finite element method) is performed.

The History of Theoretical, Material and Computational Mechanics - Mathematics Meets Mechanics and Engineering - Lecture Notes in Applied Mathematics and Mechanics ◽

History of the Finite Element Method – Mathematics Meets Mechanics – Part II: Mathematical Foundation of Primal FEM for Elastic Deformations, Error Analysis and Adaptivity

10.1007/978-3-642-39905-3_23 ◽

2014 ◽

pp. 443-478

Author(s):

Erwin Stein

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Error Analysis ◽

Mathematical Foundation ◽

Elastic Deformations ◽

History Of ◽

Designing of Self-Deploying Origami Models Using Geometrically Misaligned Crease Patterns

Volume 5B: 38th Mechanisms and Robotics Conference ◽

10.1115/detc2014-35592 ◽

2014 ◽

Author(s):

Kazuya Saito ◽

Akira Tsukahara ◽

Yoji Okabe

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Numerical Simulations ◽

Elastic Energy ◽

Degrees Of Freedom ◽

New Method ◽

Quadrilateral Mesh ◽

Arbitrary Size ◽

Folding Simulation

Traditionally, origami-based structures are designed on the premise of “rigid folding,” i.e., the facets and fold lines of origami can be replaced with rigid panels and ideal hinges, respectively. Miura-ori and double corrugation surface are representative rigid-foldable origami models. However, from a structural mechanics viewpoint, these systems are usually overconstrained and have negative degrees of freedom (DOF), i.e., the number of constraints exceeds the number of variables. In these cases, the singularity in crease patterns guarantees their rigid foldability. Further, if misalignments are included in the systems’ crease patterns, they become no longer rigid-foldable. This study presents a new method for designing self-deploying origami using the geometrically misaligned creases. In this method, some facets are replaced by “holes” such that the systems become a 1-DOF mechanism. These perforated origami models can be folded and unfolded similar to rigid-foldable (without misalignment) models because of their DOF. Focusing on the removed facets, the holes will deform according to the motion of the frame of the remaining parts. In the proposed method, these holes are filled with elastic parts and store elastic energy for self-deployment. First, a new extended rigid-folding simulation technique is proposed to estimate the deformation of the holes. Next by using the above technique, the proposed method is applied on arbitrary-size quadrilateral mesh origami. Finally, by using the finite-element method, the authors conduct numerical simulations and confirm the deployment capabilities of the models.

Areas of Contact and Pressure Distribution in Bolted Joints

Journal of Engineering for Industry ◽

10.1115/1.3428263 ◽

1972 ◽

Vol 94 (3) ◽

pp. 864-870 ◽

Cited By ~ 54

Author(s):

H. H. Gould ◽

B. B. Mikic

Keyword(s):

Finite Element Method ◽

Finite Element ◽

Pressure Distribution ◽

Experimental Methods ◽

Bolted Joints ◽

The Other ◽

Elastic Plates ◽

Linear Elastic ◽

Made In

The pressure distribution in the contact zones and the radii at which flat and smooth axisymmetric, linear elastic plates will separate were computed for several thicknesses as a function of the configuration of the bolt load by the finite element method. The radii of separation were also measured by two experimental methods. One method employed autoradiographic techniques. The other method measured the polished area around the bolt hole of the plates caused by sliding under load in the contact zone. The computational and experimental results are in agreement and these yield smaller zones of contact than indicated by the literature. It is shown that the discrepancy is due to an assumption made in the previous analyses.