Compressive Strength of Four-Layer Titanium-Steel Adapter with Soft Interlayer of Varying Thickness

Leonid Moiseevich Gurevich; Dmitriy V. Pronichev; Roman Evgenyevich Novikov

doi:10.4028/www.scientific.net/SSP.284.9

Paper Titles

Preface

Analysis of Elastoplastic Behavior Model of Antifriction Polymers
p.3

Compressive Strength of Four-Layer Titanium-Steel Adapter with Soft Interlayer of Varying Thickness
p.9

Creation of Oil-Filled Composites of Tribotechnical Purpose Based on Aromatic Polyamide Phenylone C-2
p.14

Dependence of the Elastic Properties of a Single-Walled Carbon Nanotube on its Chirality
p.20

Effect of Organoclays on Fire Resistance of Siloxane Rubbers
p.25

Effect of Thermochemical Treatment on the Structure and Mechanical Properties of Materials Based on Aluminum Oxide
p.30

Electromagnetic Effect of Eddy Currents in Composites with Conductive Components: Magnetic Field Strengthening and its Simple Analytical Estimation
p.37

Fatigue Testing Method of Test Coupon and Structurally Equivalent Samples of Carbon Fiber Reinforced Polymer for Gas Turbine Engine Parts and Assemblies
p.43

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Compressive Strength of Four-Layer Titanium-Steel Adapter with Soft Interlayer of Varying Thickness

Abstract:

The work presents the result of the 3D finite element simulating of four-layer titanium-steel titanium + niobium + copper + steel 12Cr18Ni10Ti composite adapter behavior under axial compression using a SIMULIA/Abaqus software package. The "stress-strain" curves for adapters with various thicknesses of the copper sublayer was obtained. The differences in the deformation of niobium and copper sublayers on the outer and inner surfaces of the adapter was shown.

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Periodical:

Solid State Phenomena (Volume 284)

Pages:

9-13

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.284.9

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Online since:

October 2018

Authors:

Leonid Moiseevich Gurevich, Dmitriy V. Pronichev, Roman Evgenyevich Novikov*

Keywords:

Compression, Deformation, Destruction, Finite Element Method, Soft Interlayer, Steel, Titanium

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