M. S. Rudenko scite author profile

M. S. Rudenko

5Publications

4Citation Statements Received

34Citation Statements Given

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Siberian State Aerospace University

Publications

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Influence of the Filler Particles’ Surface Morphology on the Polyurethane Matrix’s Structure Formation in the Composite

et al. 2021

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This article presents the surface morphology effect of silicon carbide (SiC) particles on the polyurethane binder’s structure formation in a dispersed-filled composite. The difference in the morphology and surface relief of filler particles was ensured by the implementation of plasma chemical modification. As a result of this modification, the filler consisted of core-shell particles characterized by a SiC core and a carbon shell (SiC@C), as well as a carbon shell decorated with silicon nanoparticles (SiC@C/SiNP) or nanos (SiC@C/SiNW). The study of the relaxation properties of polyurethane composites has shown that the strongest limiting effect on the molecular mobility of boundary layer’s chain segments is exerted by a highly developed surface with a complex relief of SiC@C/SiNP and SiC@C/SiNW particles. An empirical method was proposed to find the polymer fractions spent on the formation of the boundary, transition and bulk layers of the polymer matrix in the composite. It was shown that the morphology of the filler particles’ surface does not affect the dependence of the boundary layer thickness on the filler’s volume fraction. However, with an increase in the degree of surface development, the boundary layer thickness decreases.

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Structure, composition, and preparation of thermal conductive composite materials based on polyurethane and modified silicon carbide particles

2022

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This paper presents the first data on the dependence of thermal conductivity of DFPCM on generalized parameters and type of structure, according to the classification (dilute – low filled – medium filled – high filled systems), using the system of polyurethane + modified silicon carbide particles as an example. New plasma-modified silicon carbide particles with a unique structure and high specific surface area have been obtained, and their main characteristics necessary for calculating the compositions, generalized parameters, and determining the type of disperse structure of DFPCM have been determined. The main regularities are established that describe the relationship between the thermal conductivity coefficient (λ pcm) and the generalized parameter Θ, the type of structure of the DFPCM, and the surface morphology of SiC particles. For the first time, the contribution of the specific surface area of dispersed SiC particles (S BET − from 3 to 45 m2/g) to the thermal conductivity of disperse systems is shown.

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The effect of laser surface treatment of titanium samples on the adhesive strength of adhesive joints

Гирн

Rudenko

Taigin

et al. 2022

S&T

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The article considers the strength of adhesive joints of specimens made of OT-4 titanium alloys, the surface of which has been treated with laser radiation. The paper presents the results of the dependence of the macro- and microgeometry of the obtained surface, chemical composition, wetting angle and adhesion strength of adhesive joints under shear on laser processing modes. The purpose of this work is to determine the optimal parameters of laser processing for obtaining high strength adhesive joints. The results obtained can be used for gluing spacecraft structural elements. The studies were carried out on the adhesive pair «Titan – Titan». Depending on the processing mode, characteristic surface textures were identified, which were combined into groups «B», «K» and «C». High-energy modes of laser surface treatment of samples before gluing lead to a significant increase in the strength characteristics of the adhesive joint (up to 70 %) due to an increase in the area of the gluing surface and mechanical locking of the adhesive in the microrelief of the texture of the samples. In addition, the use of this method, in comparison with mechanical and chemical methods, significantly increases the productivity of surface treatment.

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The Research of Dependence Between the Input Parameters of Plasma Spraying and Microstructure of the Obtained Coatings

Balashov¹,

Rudenko²,

Волочаев³

et al. 2019

SJST

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Manufacturing Technology Honeycomb Core From Polymeric Composite Materals

Rudenko¹,

Mikheev²,

Гирн³

2021

SAJ

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M. S. Rudenko

Influence of the Filler Particles’ Surface Morphology on the Polyurethane Matrix’s Structure Formation in the Composite

Structure, composition, and preparation of thermal conductive composite materials based on polyurethane and modified silicon carbide particles

The effect of laser surface treatment of titanium samples on the adhesive strength of adhesive joints

The Research of Dependence Between the Input Parameters of Plasma Spraying and Microstructure of the Obtained Coatings

Manufacturing Technology Honeycomb Core From Polymeric Composite Materals

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