Homogenization of material properties in additively manufactured structures

Liu, Xingchen; Shapiro, Vadim

doi:10.1016/j.cad.2016.05.017

Cited by 68 publications

(25 citation statements)

References 37 publications

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“…Rapid prototyping (RP) refers to a collection of new technologies, such as fused deposition modeling (FDM), direct metal deposition (DMD), selective laser sintering (SLS), inject modeling (IJM) and stereolithography (SLA), which can be used to create any desired 3D physical model of a printed part, element, device or artefact faster than before without machining or tooling [1] by layer manufacturing from computer aided design (CAD) data [2] and without a significant increase in time or cost [3]. This rapid growth of the market has placed 3D printers not just in enormously varied industrial settings but also in schools, universities, and homes, and it is therefore often preferable to call these devices a 'personal 3D printer' or 'desktop 3D printer' [4,5].…”

Section: Rapid Prototyping and 3d Printingmentioning

confidence: 99%

Quantitative analysis of 0% infill density surface profile of printed part fabricated by personal FDM 3D printer

Alsoufi

Elsayed

2018

IJET

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Fused deposition modeling or FDM technology is an additive manufacturing (AM) technology commonly used for prototyping applications which suffer seriously from low levels of fluctuated surface finish quality, demanding some hand finishing tool for even the necessary levels of 3D printed parts. This paper, therefore, aims at giving close attention to the variation in the surface roughness profile between the inner and the outer faces of FDM 3D printed parts based on advanced polylactic acid (PLA+) thermoplastic filament material. The surface roughness is quantitatively analyzed using a contact-type test-rig with a 90° angle measurement on each face along with each zone and sub-zone. The obtained results revealed that the surface finish of the inner faces is rougher than those of the outer faces as regards nozzle temperature, nozzle diameter, infill density and layer height is 220°C, 0.5 mm, 0% and 0.3 mm, respectively. The personal FDM 3D printer is thus confirmed to be an excellent platform, flexible, straightforward and cost-effective. Keywords: Additive Manufacturing (AM), Fused Deposition Modeling (FDM), Surface Profile, 3D Printer.1. Background Rapid Prototyping and 3D PrintingRapid prototyping (RP) refers to a collection of new technologies, such as fused deposition modeling (FDM), direct metal deposition (DMD), selective laser sintering (SLS), inject modeling (IJM) and stereolithography (SLA), which can be used to create any desired 3D physical model of a printed part, element, device or artefact faster than before without machining or tooling [1] by layer manufacturing from computer aided design (CAD) data [2] and without a significant increase in time or cost [3]. This rapid growth of the market has placed 3D printers not just in enormously varied industrial settings but also in schools, universities, and homes, and it is therefore often preferable to call these devices a 'personal 3D printer' or 'desktop 3D printer' [4,5]. The range of applications where FDM 3D printer technology can be used is widespread in different fields, ranging from medical [6] to automotive [7] and aeronautics applications [8]. Currently, as RP is moving towards rapid manufacturing, there is an increasing demand for obtaining good surface quality printed parts as this has more influence on how customers assess the quality of the 3D printed parts. FDM TechnologyOpen source fused deposition modeling (FDM) is one of several RP technologies available that is currently attracting attention [9]. The FDM process was established commercially and sold to international trade in the early 1990s in the USA as a form of concept modeling by Stratasys Inc. [10]. Figure 1 shows the schematic concept of the FDM 3D printer process. It begins with a 3D model (or three-dimensional modeling) in a computer aided design (CAD) file in order to calculate the horizontal cross-sections at sufficiently small increments of the layer height of the printed part before converting it to an STL (Stereo-Lithography) format file [11]. The STL (Stereo-Lithog...

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Section: Rapid Prototyping and 3d Printingmentioning

confidence: 99%

Quantitative analysis of 0% infill density surface profile of printed part fabricated by personal FDM 3D printer

Alsoufi

Elsayed

2018

IJET

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“…The stiffness properties should satisfy the reciprocal relation ν 12 /E 1 = ν 21 /E 2 , where ν 12 obtained from previous case and ν 21 = −ε 11 /ε 22 is calculated from this case.…”

Section: Fiber Orientation Normal To Axis Of Loading In Tensile Testmentioning

confidence: 98%

“…Rodriguez et al [20] employed a numerical homogenization approach and a strength of material approach to find the elastic moduli of a material. Liu and Shapiro [21] proposed a new approach to find the elastic moduli of the parts fabricated by FDM, in which mesostructure is accounted for homogenization at macro scale level using Green's function. An experimental fatigue damage analysis of FDM processed parts was carried out in [22].…”

Section: Introductionmentioning

confidence: 99%

Mechanical Characterization of Additively Manufactured Parts by FE Modeling of Mesostructure

Somireddy

Czekanski

2017

JMMP

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Abstract:In the present study, the mesostructure of a fused deposition modeling (FDM) processed part is considered for the investigation of its mechanical behavior. The layers of FDM printed part behave as a unidirectional fiber reinforced laminae, which are treated as an orthotropic material. The finite element (FE) procedure to find elastic moduli of a layer of the FDM processed part is presented. The mesostructure of the part that would be obtained from the process is replicated in FE models in order to find stiffness matrix of a layer. Two distinctive architectures of mesostructure are considered in the study to predict the mechanical behavior of the parts. Also, influences of layer thickness, road shape and air gap on the elastic properties of a material are investigated. Further, the parts fabricated with FDM process are treated as laminate structures. From the numerical results, it is seen that the elastic moduli are governed by mesostructures. Our laminate results are validated with experimental to demonstrate the use of classical laminate theory (CLT) for FDM parts. The elastic moduli (E 1 , E 2 , G 12 , ν 12 ) of a layer used in the analysis are calculated from FE simulations. This study establishes relationship between mesostructure and macro mechanical properties of the part.

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“…Liu et al [48] use a different approach to predict mechanical behavior, a homogenization method to compensate for the heterogeneity FDM parts. An implicit representation of the effective mesoscale structure is created and is then homogenized at a macro scale using a solution through an integral equation using Green's function [48].…”

Section: Analytical Approachesmentioning

confidence: 99%

Comparison of As-Built FEA Simulations and Experimental Results for Additively Manufactured Dogbone Geometries

Baikerikar

Turner

2017

Volume 1: 37th Computers and Information in Engineering Conference

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Fused Deposition Modeling (FDM - a technology of additive manufacturing) parts entail a certain amount of ambiguity in terms of its material properties and microstructure due to its manufacturing technique. Therefore, an FDM part differs from its design model in terms of strength and stiffness. With an increasing amount of FDM parts being used as end use products, it is necessary to simulate and analyze them. Due to the differences in microstructure and material properties of FDM parts, it is necessary to determine the accuracy of analysis methods like Finite Element Analysis (FEA) while analyzing the non-continuous, non-linear FDM parts. The goal of this study is to compare FEA simulations of the as-built geometries with the experimental tests of actual FDM parts. A dogbone geometry with different infill patterns is tested under tensile loading. Further, as-built 3D models are simulated using FEA and the stress results are compared with experimental data. This study found that FEA results are not always an accurate or reliable means of predicting FDM part behaviors.

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Homogenization of material properties in additively manufactured structures

Cited by 68 publications

References 37 publications

Quantitative analysis of 0% infill density surface profile of printed part fabricated by personal FDM 3D printer

Quantitative analysis of 0% infill density surface profile of printed part fabricated by personal FDM 3D printer

Mechanical Characterization of Additively Manufactured Parts by FE Modeling of Mesostructure

Comparison of As-Built FEA Simulations and Experimental Results for Additively Manufactured Dogbone Geometries

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