Contact/impact modeling and analysis of 4D printed shape memory polymer beams

Damanpack, A.R.; Bodaghi, Mahdi; Liao, Wei-Hsin

doi:10.1088/1361-665x/ab883a

Cited by 22 publications

(11 citation statements)

References 29 publications

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“…Damanpack et al investigated the shape memory effect after large deformations due to contact or impact loading in 3D printed beams from polyurethane. 87 They found nearly full recovery by heating the samples and suggested using similar beam-like SMP structures for applications exposed to impact loadings.…”

Section: Other Fdm Printable Shape Memory Polymersmentioning

confidence: 96%

3D printing of shape memory polymers

Ehrmann¹,

Ehrmann

2021

J of Applied Polymer Sci

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Shape memory polymers (SMPs) are polymers which ''remember'' their original shape and can return to it after deformation, if an external stimulus-often an increased temperatureis applied. Some SMPs can be 3D printed, typically by fused deposition modeling (FDM). The most well-known SMP is poly(lactic acid), which belongs to the most often used materials in FDM 3D printing. There are; however, many more SMPs which can be 3D printed to combine the possibilities to prepare new, sophisticated shapes with the opportunity to restore these shapes after undesirable or intentional deformation. This review gives an overview of several 3D printable SMPs, their mechanical characteristics and their possible applications.

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Section: Other Fdm Printable Shape Memory Polymersmentioning

confidence: 96%

3D printing of shape memory polymers

Ehrmann¹,

Ehrmann

2021

J of Applied Polymer Sci

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“…Damanpack et al [ 47 ] analysed the contact and impact behaviours of SMP beams printed with 4D technology via constitutive modelling, FEM formulation and simulation, as well as supported by experimental tests. They used a node-to-surface algorithm to evaluate the global/local contact and to simulate the visco-elastic-plastic behaviour of SMPs, while an innovative constitutive model was developed to predict the shape memory effect in large strain regimes.…”

Section: Shape Memory Effect In Polymersmentioning

confidence: 99%

Fused Filament Fabrication-4D-Printed Shape Memory Polymers: A Review

et al. 2021

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Additive manufacturing (AM) is the process through which components/structures are produced layer-by-layer. In this context, 4D printing combines 3D printing with time so that this combination results in additively manufactured components that respond to external stimuli and, consequently, change their shape/volume or modify their mechanical properties. Therefore, 4D printing uses shape-memory materials that react to external stimuli such as pH, humidity, and temperature. Among the possible materials with shape memory effect (SME), the most suitable for additive manufacturing are shape memory polymers (SMPs). However, due to their weaknesses, shape memory polymer compounds (SMPCs) prove to be an effective alternative. On the other hand, out of all the additive manufacturing techniques, the most widely used is fused filament fabrication (FFF). In this context, the present paper aims to critically review all studies related to the mechanical properties of 4D-FFF materials. The paper provides an update state of the art showing the potential of 4D-FFF printing for different engineering applications, maintaining the focus on the structural integrity of the final structure/component.

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“…In the last few years, several authors have been investigating the potential of SMP for 3D printing. In this context, Bodaghi et al developed constitutive models and numerical codes to predict the impact behavior of SMP beams, [ 16 ] the behavior of meta‐structures, [ 17 ] and the self‐bending of SMP beams printed at different speeds. [ 18 ] Raasch et al [ 19 ] and Garcia Rosales et al [ 20 ] studied the extrusion of filament and printing conditions of SMP aiming at optimizing the shape recovery of printed samples.…”

Section: Introductionmentioning

confidence: 99%

Shape memory polymers as actuators: Characterization of the relevant parameters under constrained recovery

Peixoto

Zille

Silva

et al. 2021

Polymer Engineering & Sci

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In this work, a shape memory polyurethane is characterized through constrained recovery experiments performed in a tensile testing equipment. The most relevant results obtained are those concerned with the stress released over time during the recovery stage, since they provide quantitative information that can be used in the design of actuators. For this sake, design guidelines are proposed based on the effect of: (i) the programming temperature; (ii) the deformation imposed during the programming stage; (iii) the recovery temperature; and (iv) the manufacturing process used to produce the samples tested (compression molding and Fused Filament Fabrication). The set of experiments performed with compression‐molded samples put in evidence a considerable variety of material responses: (i) the maximum released stress varied from 0.74 to 1.68 MPa; (ii) the time required to attain this stress varied from 47 to 600 s; and (iii) the stress was released as a peak value that relaxed rapidly, or, contrarily, had a lasting effect. Another relevant conclusion is that the 3D printing technique does not affect the shape memory behavior of the material. Having this in mind, the conclusions provided by the compression‐molded samples study can be extended to printed ones.

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Contact/impact modeling and analysis of 4D printed shape memory polymer beams

Cited by 22 publications

References 29 publications

3D printing of shape memory polymers

3D printing of shape memory polymers

Fused Filament Fabrication-4D-Printed Shape Memory Polymers: A Review

Shape memory polymers as actuators: Characterization of the relevant parameters under constrained recovery

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