Effects of shot peening and artificial surface defects on fatigue properties of 50CrV4 steel

Saklakoğlu, Nurşen; Bolouri, Amir; İrizalp, Simge Gençalp; Baris, Fatih; Elmas, Ali

doi:10.1007/s00170-020-06532-y

Cited by 12 publications

(4 citation statements)

References 44 publications

(51 reference statements)

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“…An as‐received notch surface (with corrosion pitting) typically had a lower number of crack initiation events, possibly due to the onset of early initiation activity and growth behavior inhibiting later crack initiation due to shielding effects 1 . The shot peened notch surface typically had more crack initiation events than a polished or as‐received notch surface, especially at lower strain ranges due to the presence of pre‐existing cracks before testing (Figure 14), a feature seen in similar shot peened steels 6,23,24 …”

Section: Discussionmentioning

confidence: 94%

“…1 The shot peened notch surface typically had more crack initiation events than a polished or as-received notch surface, especially at lower strain ranges due to the presence of pre-existing cracks before testing (Figure 14), a feature seen in similar shot peened steels. 6,23,24 The number of crack initiation events observed on a shot peened U-notch surface made from FV448 with applied strain ranges between 0.6% and 0.9% 10 were almost doubled when assessed in the FV566 at the same strain range. This difference can be attributed to the method used to count the number of initiation events on the surface.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Fatigue crack initiation and growth behavior within varying notch geometries in the low‐cycle fatigue regime for FV566 turbine blade material

Cunningham

Leering

Fan

et al. 2023

Fatigue Fract Eng Mat Struct

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Plain bend bars made from FV566 martensitic stainless steel were extracted from the root of ex‐service power plant turbine blades and several industry‐relevant notch geometries were introduced. Some of the samples were shot peened. The notched bend bars were loaded plastically in the low‐cycle fatigue regime and finite element (FE) modeling carried out to investigate the effects of changing notch geometry, combined with shot peening, on fatigue behaviors such as crack initiation, short crack growth, and coalescence. Shot peening damaged the notch surface, accelerating initiation behaviors, but had a lifetime‐extending effect by retarding short crack growth in all tested notch geometries. At a total strain range higher than 1.2%, the lifetime extension benefit from shot peening was diminished due to compressive residual stress relaxation in the notch stress field. Notch geometry (and the associated varying constraint levels and stress/strain gradients) was found to have no notable difference on fatigue life when tested at identical notch‐root strain ranges.

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Section: Discussionmentioning

confidence: 94%

Section: Discussionmentioning

confidence: 99%

Fatigue crack initiation and growth behavior within varying notch geometries in the low‐cycle fatigue regime for FV566 turbine blade material

Cunningham

Leering

Fan

et al. 2023

Fatigue Fract Eng Mat Struct

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show abstract

“…The results are consistent with the findings expressed by other Refs. [48][49][50][51]. As depicted in Fig.…”

Section: Phase Analysismentioning

confidence: 99%

Determination of the optimal coverage for heavy-duty-axle gears in shot peening

Yan

Zhu

Chen

et al. 2021

Int J Adv Manuf Technol

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Pitting and wear often appear on heavy-duty-axle gears due to their harsh working conditions, such as high torques, high loads and poor lubrication. Shot peening is a popular surface strengthening method for gears. In order to ensure complete coverage during shot peening, 100%~200% coverage is usually prescribed for most gears. However, it is difficult to effectively improve the contact fatigue and wear resistance of heavy-duty-axle gears. Generally, increasing shot peening coverage can heighten the compressive residual stress for prolonging the service lifetime of gears. Whereas, high coverage levels may cause the deterioration of surface roughness, thus increase the noise and vibration of gears. To address this issue, this paper deals with the determination of optimal coverage for heavy-duty-axle gears by experimental tests. The influence of shot peening coverage on the surface integrity of gears is analyzed in terms of residual stress, microhardness, surface morphology and dislocation density. The results show that the maximum compressive residual stress increases first and then keeps stable with the increase of coverage, and the maximum value is −1172.10 MPa. The microhardness peak increases obviously in the beginning and then slowly rises with the increase of coverage, and the maximum value is 747.5 HV1.0. The surface roughness (Ra) decreases initially and then enhances with the increase of coverage, and the minimum value is 0.99 μm under the coverage of 1000%. The dislocation density increases with the increase of coverage, and the maximum value is 3.70×10 16 m -2 . Numerous damages (microscalings, spallings) occur on the treated gear tooth flank affecting the residual stress distribution and roughness under high coverage levels. Taking into consideration of service lifetime, working noise and economic efficiency, the coverage of 1000% is the optimal coverage for heavy-duty-axle gears in shot peening.

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“…For instance, it has been demonstrated that ultrasonic impact peening (UIP) technology plays a positive role in refining the grain size and increasing hardness and wear resistance. [8,9] In addition, the residual compressive stress was applied to the metal surface, which can heal the microcracks and holes during the cycle wear. [10] Yin et al [11,12] found that the ultrasonic shot peening (USP) can induce nanocrystalline structure on the surface, thereby improving the nanohardness and Young's modulus.…”

Section: Introductionmentioning

confidence: 99%

Microstructure Evolution and Wear Resistance Improvement of Ultrasonic Peened M50 Steel via Electromagnetic Shocking

Qian

Wang

Dong

et al. 2023

steel research int.

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Herein, the effect of electromagnetic shocking treatment (EST) on microstructure evolution and wear resistance of M50 steel treated by ultrasonic shot peening (USP) is investigated. The microstructure observation indicates that the EST promotes the precipitation of nanoscale carbides. The average grain size decreases slightly and the submicron grain layer increases after EST. The low‐angle grain boundaries generated by USP will transform into high‐angle grain boundaries, thereby refining the grains on the surface during EST. In addition, the surface hardness of USP‐M50 steel decreases slightly, accompanied by the reduction of surface residual stress after EST. The wear resistance results indicate that the wear loss of the EST specimens decreases by 15.7% comparedwith the specimens after USP. The improvement of wear resistance induced by EST is attributed to the increased fine precipitations. These precipitations hinder the grinding of abrasive particles into the matrix and connect with wear debris and oxide particles to form well consolidated self‐lubricating films to prevent wear losses. The refinement of surface structure is another important reason for the improvement of wear resistance.

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Effects of shot peening and artificial surface defects on fatigue properties of 50CrV4 steel

Cited by 12 publications

References 44 publications

Fatigue crack initiation and growth behavior within varying notch geometries in the low‐cycle fatigue regime for FV566 turbine blade material

Fatigue crack initiation and growth behavior within varying notch geometries in the low‐cycle fatigue regime for FV566 turbine blade material

Determination of the optimal coverage for heavy-duty-axle gears in shot peening

Microstructure Evolution and Wear Resistance Improvement of Ultrasonic Peened M50 Steel via Electromagnetic Shocking

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