Effect of Strain Rates and Heat Exposure on Polyamide (PA12) Processed via Selective Laser Sintering

Morano, Chiara; Alfano, Marco; Pagnotta, Leonardo

doi:10.3390/ma16134654

Cited by 8 publications

(2 citation statements)

References 51 publications

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“…Moreover, all details of the responses are rate dependent i.e., the material is more ductile, larger strains are achieved, and wider hysteresis appear in the cyclic response at a lower loading speed. These results are consistent with formerly reported findings [ 36 , 37 ] and indicate that the viscous nature of the polymer is dominant in such conditions; thus, hyper-viscoelasticity governs the mechanical behaviors of selectively laser sintered polyamide 12. Similar responses with these details are obtained for different maximum loads beyond the elastic limit of the material and also for the produced pantographic structure, as is seen in Fig 6 .…”

Section: Experimental Findings and Discussionsupporting

confidence: 93%

An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sintering

Kadkhodaei,

Pawlikowski,

Drobnicki

et al. 2024

PLoS ONE

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Polyamide 12 (PA12) is vastly utilized in many additive manufacturing methods, such as Selective Laser Sintering (SLS), and a better understanding of its mechanical behaviors promotes available knowledge on the behaviors of 3D-printed parts made from this polymer. In this paper, SLS-produced standard tensile specimens are studied under monotonic and cyclic tension tests, as well as stress relaxation experiments, and the obtained force-displacement responses are shown to be consistent with a hyper-viscoelastic material model. This finding is also observed in typical pantographic structures produced by the same manufacturing parameters. To propose a constitutive model for predicting these behaviors, the convolution integral of a strain-dependent function and a time-dependent function is developed where the material parameters are determined with the use of both short-term and long-term responses of the specimens. Numerical results of the presented model for standard test specimens are shown to be in good agreements with the experimental ones under various loading conditions. To prove the capabilities of the proposed model in studying any SLS-produced part, finite element implementation of the constitutive equations is shown to provide numerical results in agreement with the empirical findings for tensile loading of the 3D-printed pantographic structure.

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Section: Experimental Findings and Discussionsupporting

confidence: 93%

An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sintering

Kadkhodaei,

Pawlikowski,

Drobnicki

et al. 2024

PLoS ONE

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show abstract

“…Polyamide is the most popular polymer in the SLS application since it allows for the creation of parts that have good mechanical properties, good finishes, low costs, and recyclability [27]. In addition, they are also suitable for the production of composite materials and medical applications [28,29].…”

Section: The Polyamide Familymentioning

confidence: 99%

Additive Manufactured Parts Produced Using Selective Laser Sintering Technology: Comparison between Porosity of Pure and Blended Polymers

Morano,

Pagnotta

2023

Polymers

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For different manufacturing processes, porosity occurs in parts made using selective laser sintering (SLS) technology, representing one of the weakest points of materials produced with these processes. Even though there are different studies involving many polymeric materials employed via SLS, and different manuscripts in the literature that discuss the porosity occurrence in pure or blended polymers, to date, no researcher has reported a systematic and exhaustive comparison of the porosity percentage. A direct comparison of the available data may prove pivotal in advancing our understanding within the field of additively manufactured polymers. This work aims to collect and compare the results obtained by researchers who have studied SLS’s applicability to different amorphous or semi-crystalline polymers and pure or blended materials. In particular, the porosity values obtained by different researchers are compared, and tables are provided that show, for each material, the process parameters and the measured porosity values.

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Effect of post-heat treatment on the mechanical and surface properties of nylon 12 produced via material extrusion and selective laser sintering processes

Balan,

Raj,

Adithya

2024

Polym. Bull.

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Effect of Strain Rates and Heat Exposure on Polyamide (PA12) Processed via Selective Laser Sintering

Cited by 8 publications

References 51 publications

An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sintering

An experimental and theoretical investigation on the hyper-viscoelasticity of polyamide 12 produced by selective laser sintering

Additive Manufactured Parts Produced Using Selective Laser Sintering Technology: Comparison between Porosity of Pure and Blended Polymers

Effect of post-heat treatment on the mechanical and surface properties of nylon 12 produced via material extrusion and selective laser sintering processes

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