Influence of non-abrasive ultrasonic finishing on surface characteristics and fatigue strength of UFG titanium

R.N. Asfandiyarov, D.A. Aksenov, M.A. Shishkunova, G.I. Raab показать трудоустройства и электронную почту
Получена 18 апреля 2023; Принята 14 июня 2023;
Эта работа написана на английском языке
Цитирование: R.N. Asfandiyarov, D.A. Aksenov, M.A. Shishkunova, G.I. Raab. Influence of non-abrasive ultrasonic finishing on surface characteristics and fatigue strength of UFG titanium. Письма о материалах. 2023. Т.13. №3. С.260-265
BibTex   https://doi.org/10.22226/2410-3535-2023-3-260-265

Аннотация

Increased fatigue resistance of grade 4 titanium as a result of complex processing, including the formation of an UFG structure and non-abrasive ultrasonic finishing of surfaceThis paper considers the complex treatment of Grade 4 titanium, including the formation of an UFG structure and surface hardening by non-abrasive ultrasonic finishing (NAUF). In the study it is shown that NAUF of UFG titanium leads to noticeable refinement of the structure of the surface layer. Thus, at a depth up to 60 μm, an equiaxed structure is formed with the refinement of structural fragments from an average transverse size of 175 nm to 130 nm. It has been established that NAUF of UFG titanium makes it possible to increase the surface microhardness up to 8740 MPa. It is found that after NAUF compressive residual stresses prevail in the surface, the value of which is an order of magnitude higher than that of UFG titanium and reaches 620 MPa. Comparative fatigue tests of CG and UFG specimens with a V-shaped annular groove under conditions of bending with rotation were carried out. It has been established that with the testing base N = 3 ∙106 cycles, the fatigue endurance limit of UFG specimens (σσ =1.33) with NAUF reaches σ−1= 490 MPa, and without treatment σ−1= 400 MPa, thus the increase in the fatigue endurance limit was ≈20 %.

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Финансирование на английском языке

1. Russian Scientific Foundation - 21-79-00124