Investigation of the Effect of Vibration on the Bearing Capacity of Composite Materials

Sergei Koryagin; Oleg Sharkov; Nikolay Velikanov

doi:10.4028/p-cno390

Paper Titles

Friction-Electric Modification of the Surfaces of Machine Parts with Tungsten Carbides
p.538

Weldability Window for High-Velocity Impact Welding of Al and Ti Plates Obtained by Numerical Simulation
p.544

Study of the Effect of Copper (II), Zinc and Iron (II) Sulphates on the Froth Flotation of Sphalerite by Sulfhydryl Collectors
p.551

On the “Super” Storage of Hydrogen in Activated Graphite Nanofibers
p.559

Investigation of the Effect of Vibration on the Bearing Capacity of Composite Materials
p.567

Computational and Experimental Evaluation of the Tensile Strength of a Reinforced Polymer Coating with a Substrate
p.573

Microstructure and Properties of 20Cr23Ni18 (AISI 304L) Thin Steel Tapes Obtained by Melt Spinning
p.579

Tribological Behavior of Titanium Alloys during Friction against Ceramics
p.586

Regularities of Mass Transfer in the Finishing Layer on the Basis of a Heat-Insulating Dry Construction Mixture in the Process of Moistening
p.592

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Investigation of the Effect of Vibration on the Bearing Capacity of Composite Materials

Abstract:

Polymer coatings are increasingly used in mechanical engineering. In particular, sheet composite elements are created on their basis. But the question of the influence of vibration loads on the bearing capacity of composite structures remains relevant. This work presents the results of an experimental study of the operation of composite structures when exposed to vibration loads. The choice of the parameters of the test bench is due to the frequencies of natural vibrations of the specimens under study. The frequencies were determined using generally accepted approximations. A test bench was developed for carrying out measurements. A vibration-absorbing foundation was used, a support frame with the element was attached on elastic suspensions to the outer frame. A scheme for cutting sheet elements for tensile testing was developed. Nine sheet elements made of reinforced polymer material were tested. The influence of the number of loading cycles on the material ultimate strength is investigated. It was established that the presence of a reinforced polymer coating leads to a decrease in the vibration amplitude when approaching the resonance frequencies. This is due to the internal deformation of the polymer coating. After removing the vibration load, no cracks were found on the specimens.