3D Printing of Fractal Deterministic Shapes into Polymer Matrix with Respect to Final Composite Mechanical Properties

Jiří Bobek; Jiří Šafka; Jiří Habr; Martin Seidl

doi:10.4028/www.scientific.net/AMM.693.207

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 6933D Printing of Fractal Deterministic Shapes into...

3D Printing of Fractal Deterministic Shapes into Polymer Matrix with Respect to Final Composite Mechanical Properties

Abstract:

This paper deals with mechanical properties research of innovative polymer multiphase composite materials consisting of matrix and isotropic or anisotropic oriented deterministic fractal shapes made by 3D printing. Standard polymer composite materials consisting for example of polypropylene matrix and glass fibres have mechanical properties which depend mainly on matrix-fibre interface strength, fibre length, fibre strength and fibres orientation. [1] In case of under critical fibre length is fibres orientation stochastic in for example injection moulded composites. So is possible to say that mechanical properties of these (standard) composites with short fibres are isotropic and thus all direction limited. However by creating of reinforcing internal structure consisting of deterministic fractal connected shapes is possible to gain unlimited mechanical properties directing. These fractal shapes – placed in multiphase system matrix – are significantly influencing whole material system mechanical properties mainly in case of stress on the limit of strength, proportional elongation on the limit of strength or tensile/ flexural modulus. Fractal shapes are also possible to properly locate, orient or shape modify according to potential material using with goal to gain maximal efficiency of fractal shapes occurrence. Producing of this multiphase system is realized by the help of two component 3D printing technology. So is possible to create any fractal shapes placed in polymer matrix which are by another technology unmanufacturable. Mechanical properties analyse is performed with respect to fractal shape type, fractal dimension, fractal shape orientation and shear and tensile strength of matrix.

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Periodical:

Applied Mechanics and Materials (Volume 693)

Pages:

207-212

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.693.207

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Online since:

December 2014

Authors:

Jiří Bobek, Jiří Šafka, Jiří Habr, Martin Seidl

Keywords:

3D Print, Composite, Fractal Shapes, Mechanical Property, PolyJet Matrix

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References

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