Development of Composite Materials for 3d Printing on the Basis of Polyphenylenesulfone

Azamat L. Slonov; Azamat A. Zhansitov; Diana M. Khakulova; Zh.I. Kurdanova; Ismel V. Musov; S.Yu. Khashirova

doi:10.4028/www.scientific.net/MSF.935.15

Paper Titles

Spectrophotometric Study of Complex Compounds of Polyacrylate and Polymethacrylate of Guanidine, and also of Composites on their Basis with Fe (II) Ions
p.1

Study of the Geometric Characteristics of Carbon Fiber Fillers on the Properties of Polyphenylene Sulfone
p.5

Investigation of the Influence of Fillers of Various Nature on the Properties of Polyether Sulfone and Determination of the Possibility of Using Composites on their Basis in 3D-Printing
p.11

Development of Composite Materials for 3d Printing on the Basis of Polyphenylenesulfone
p.15

Mechanical Properties of Samples of Polyphenylene Sulfone Obtained by the 3D-Printing Method
p.21

Methods for the Synthesis of Polyethereketone
p.27

Thermal Stability of Polyetherketones
p.31

Investigation of the Crystallization of Polyetherketones by the Differential Scanning Calorimetry Method
p.36

HomeMaterials Science ForumMaterials Science Forum Vol. 935Development of Composite Materials for 3d Printing...

Development of Composite Materials for 3d Printing on the Basis of Polyphenylenesulfone

Abstract:

The influence of talc and various polymeric additives on the basic mechanical properties of polyphenylenesulfone was investigated. It was found out that with the increase in the filler concentration there is an increase in stiffness, tensile strength and a decrease in the plasticity of the polyphenylenesulfone. While studying of polymer-polymer composites based on polyphenylenesulfone, high efficiency of polycarbonate as a modifier of impact strength was revealed. An effective method for producing a composite with a high impact strength and a modulus of elasticity has beendeveloped; it is based on the features of the distribution of the filler in the binary system polyphenylenesulfone – polycarbonate. The concentration of the filler in the polycarbonate phaseleads to low values of impactstrength, while its concentration in the phase of polyphenylenesulfone, followed by the introduction of polycarbonate leads to the formation of a high impact and high modulus composite. The samples obtained by 3D printing have high mechanical characteristics.

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Periodical:

Materials Science Forum (Volume 935)

Pages:

15-20

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.935.15

Citation:

Cite this paper

Online since:

October 2018

Authors:

Azamat L. Slonov, Azamat A. Zhansitov, Diana M. Khakulova, Zh.I. Kurdanova, Ismel V. Musov, S.Yu. Khashirova

Keywords:

3D-Printing, Composite Materials, Polyphenylene Sulfone, Talc

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