Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Standard

Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel. / Milosevic, Igor; Winter, Gerhard; Grün, Florian et al.
in: Procedia Engineering, Jahrgang 160, 2016, S. 61-68.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Harvard

Milosevic, I, Winter, G, Grün, F & Kober, M 2016, 'Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel', Procedia Engineering, Jg. 160, S. 61-68.

APA

Milosevic, I., Winter, G., Grün, F., & Kober, M. (2016). Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel. Procedia Engineering, 160, 61-68.

Vancouver

Milosevic I, Winter G, Grün F, Kober M. Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel. Procedia Engineering. 2016;160:61-68.

Author

Milosevic, Igor ; Winter, Gerhard ; Grün, Florian et al. / Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel. in: Procedia Engineering. 2016 ; Jahrgang 160. S. 61-68.

Bibtex - Download

@article{fe81be964d0d4b94960075a856f59525,
title = "Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel",
abstract = "Nowadays technical applications require very small components which leads to the question of how to handle fatigue strength data gained from tests carried out on specimen which are even larger than the component itself. Previous high-cycle-fatigue (HCF) tests have outlined the negative influence of increasing “risk volumes” due to enlargement of the specimen size. Additional to the effect of “risk volumes” the influence of stress gradient may not be neglected as the gradient changes as well due to the enlargement of the specimen size. Especially thin profiles could be affected by high stress gradients which results in high and low stress loaded profile areas. The fatigue strength of an hourglass shaped specimen with a standardized diameter of 7.5 mm tends to have higher fatigue strength than a specimen with a larger diameter. In this work rotating bending tests were carried out on specimens with a diameter of 4 and 7.5 mm. Lifetime simulations with different specimen diameters (D2.5, D4 and D7.5) were carried out by a common simulation tool FEMFAT and simultaneous testing of D4 and D7.5 specimens was performed to compare the results. An outlook is given on how such influences can be estimated and an appropriate method can be derived for damage calculations.",
author = "Igor Milosevic and Gerhard Winter and Florian Gr{\"u}n and Martin Kober",
year = "2016",
language = "English",
volume = "160",
pages = "61--68",
journal = "Procedia Engineering",
issn = "1877-7058",
publisher = "Elsevier",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Influence of Size Effect and Stress Gradient on the High-cycle Fatigue Strength of a 1.4542 Steel

AU - Milosevic, Igor

AU - Winter, Gerhard

AU - Grün, Florian

AU - Kober, Martin

PY - 2016

Y1 - 2016

N2 - Nowadays technical applications require very small components which leads to the question of how to handle fatigue strength data gained from tests carried out on specimen which are even larger than the component itself. Previous high-cycle-fatigue (HCF) tests have outlined the negative influence of increasing “risk volumes” due to enlargement of the specimen size. Additional to the effect of “risk volumes” the influence of stress gradient may not be neglected as the gradient changes as well due to the enlargement of the specimen size. Especially thin profiles could be affected by high stress gradients which results in high and low stress loaded profile areas. The fatigue strength of an hourglass shaped specimen with a standardized diameter of 7.5 mm tends to have higher fatigue strength than a specimen with a larger diameter. In this work rotating bending tests were carried out on specimens with a diameter of 4 and 7.5 mm. Lifetime simulations with different specimen diameters (D2.5, D4 and D7.5) were carried out by a common simulation tool FEMFAT and simultaneous testing of D4 and D7.5 specimens was performed to compare the results. An outlook is given on how such influences can be estimated and an appropriate method can be derived for damage calculations.

AB - Nowadays technical applications require very small components which leads to the question of how to handle fatigue strength data gained from tests carried out on specimen which are even larger than the component itself. Previous high-cycle-fatigue (HCF) tests have outlined the negative influence of increasing “risk volumes” due to enlargement of the specimen size. Additional to the effect of “risk volumes” the influence of stress gradient may not be neglected as the gradient changes as well due to the enlargement of the specimen size. Especially thin profiles could be affected by high stress gradients which results in high and low stress loaded profile areas. The fatigue strength of an hourglass shaped specimen with a standardized diameter of 7.5 mm tends to have higher fatigue strength than a specimen with a larger diameter. In this work rotating bending tests were carried out on specimens with a diameter of 4 and 7.5 mm. Lifetime simulations with different specimen diameters (D2.5, D4 and D7.5) were carried out by a common simulation tool FEMFAT and simultaneous testing of D4 and D7.5 specimens was performed to compare the results. An outlook is given on how such influences can be estimated and an appropriate method can be derived for damage calculations.

M3 - Article

VL - 160

SP - 61

EP - 68

JO - Procedia Engineering

JF - Procedia Engineering

SN - 1877-7058

ER -

Beziehungsdiagramm anzeigen

360 Link

Zeitschriften in BUGL

Vom selben Autor

Mehr zeigen