Analysis of Effectiveness of Combined Surface Treatment Methods for Structural Parts with Holes to Enhance Their Fatigue Life-Reference-Cited by-同舟云学术

Analysis of Effectiveness of Combined Surface Treatment Methods for Structural Parts with Holes to Enhance Their Fatigue Life

Published:2024-01-08 Issue:1 Volume:12 Page:8
ISSN:2079-3197
Container-title:Computation
language:en
Short-container-title:Computation

Author:

Grebenikov Olexander¹,Humennyi Andrii¹,Svitlychnyi Serhii²,Lohinov Vasyl³^ORCID,Matviienko Valerii⁴

Affiliation:

1. Department of Airplanes and Helicopters Design, Faculty of Aircraft Engineering, National Aerospace University “Kharkiv Aviation Institute”, 61070 Kharkiv, Ukraine

2. Department of Theoretical Mechanics, Mechanical Engineering and Robotic Systems, Faculty of Aircraft Engine, National Aerospace University “Kharkiv Aviation Institute”, 61070 Kharkiv, Ukraine

3. JSC FED, 61023 Kharkiv, Ukraine

4. JSC “Ukrainian Research Institute of Aviation Technology”, 04080 Kyiv, Ukraine

Abstract

The typical and most widespread stress concentrators in the lower wing panels of aircraft are the drain holes located on the stringer vertical ribs. These are prime sources for the initiation and development of fatigue cracks, which lead to early failure of the wing structure. Therefore, improving fatigue life in these critical areas is one of the significant issues for research. Two combined methods of surface plastic treatment in the location around drain holes are discussed in this paper. Using the finite element method and ANSYS software, we created a finite element model and obtained nonlinear solution results in the case of tension in a plate with three holes. In addition, the development of residual stress due to the surface plastic treatment of the hole-adjacent areas was taken into account. In this paper, it is shown that after surface treatment of the corresponding areas of the holes, residual stress, which exceeds the yield stress for the plate material, is induced. When combined with alternative tensile stress, these reduce the amplitude of the local stresses, thus increasing the number of stress cycles before failure. The benefits of this technology were confirmed by fatigue test results, which include the fatigue failure types of the plates. Graphs showing the impact of applicable surface treatment combined methods on the number of cycles to failure were also plotted.

Publisher

MDPI AG

Subject

Applied Mathematics,Modeling and Simulation,General Computer Science,Theoretical Computer Science

Link

https://www.mdpi.com/2079-3197/12/1/8/pdf

Reference28 articles.

1. Ol’kin, B.I., Givanova, N.I., Rodchenko, T.S., Masyuk, A.M., Shcheglova, N.I., and Barten’eva, G.F. (1980). Eksperimental’nye issledovaniya vliyaniya konstruktivnykh i tekhnologicheskikh faktorov na vynoslivost’ tipovykh elementov aviatsionnykh konstruktsii. Tr. TsAGI, 1–86.

2. Rychik, V.P., Litvinenko, E.A., Ostapenko, N.T., and Vasilevskii, E.T. (1976). Issledovanie vynoslivosti nizhnikh panelei kryla s otverstiyami dlya peretekaniya topliva. Tr. TsAGI, 100–103.

3. Cold expansion technology of connection holes in aircraft structures: A review and prospect;Yucan;Chin. J. Aeronaut.,2015

4. Analiz kharakteristik lokal’nogo NDS s pomoshch’yu sistemy ANSYS v plastine s otverstiyami, podverzhennoi uprochneniyu dornovaniem ili glubokogo plasticheskogo deformirovaniyu i rastyazheniyu;Grebenikov;Vopr. Proekt. I Proizv. Konstr. Letatel’nykh Appar.,2003

5. Fatigue Performance of Laser Shock Peened Ti6Al4V and Al6060-T6 Alloys;Maharjan;Fatigue Fract. Eng. Mater. Struct.,2021