Spannungsintensitätsfaktoren für Risse in Schienen

Budnitzki, Grigori; Edel, Karl-Otto

doi:10.3139/120.100700

Cited by 4 publications

(8 citation statements)

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“…As a partial conclusion, one must distinguish between a situation where a positive eigenstress state in the amount of σ r = 150−175MPa exists after straightening and overrolling for low loads and traction and the situation of heavy loading and traction with σ r being a compressive stress at the level of –250 MPa. This value is of the same magnitude as reported by Boudnitzki et al ., 2 namely –175 MPa, for heavily loaded Russian rails. A final remark may be of interest about the effect of a series of parallel surface cracks as they may appear in the case of ‘head checks’.…”

Section: Thermal Stress and Residual State Near The Rail Headsupporting

confidence: 89%

“…To the knowledge of the authors, the most comprehensive literature review can be taken from the reports in Refs. [1–3]. The team of Prof. Edel 2 reports on classification of diverse crack‐like defects, edited by various organizations, distinguishing approximately 15 to 40 different types of crack‐like defects.…”

Section: Introductionmentioning

confidence: 99%

“…[1–3]. The team of Prof. Edel 2 reports on classification of diverse crack‐like defects, edited by various organizations, distinguishing approximately 15 to 40 different types of crack‐like defects. Here rolling contact fatigue cracks (RCF cracks), growing from microcracks generated in the deformed surface layer of the rail head, are considered.…”

Section: Introductionmentioning

confidence: 99%

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Some comments on surface cracks in rails

Fischer

Daves

Pippan

et al. 2006

Fatigue Fract Eng Mat Struct

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A B S T R A C TThe present work considers the problem of whether a shallow angle surface crack on a rail may propagate either parallel or perpendicular to the surface. After referring to a classification of crack-like defects, a distinct surface crack with a typical length of 1 mm and more, inclined to the surface by an angle of approx. 30 • , is introduced. Then various strain and stress states are discussed (eigenstress, residual and load stress state) which may control the crack growth. Stress intensity factor equations are provided for the internal and load stress states. In particular, the deformation process due to a single pass (overrolling) by a wheel is investigated. Recommendations are presented on how to relate the stress intensity factor ranges to the actual deformation process. For a typical loading condition, the positive part of the mode I stress intensity factor range is near to the effective threshold value of a rail steel. The influence of the material and its strength on the crack propagation behaviour is discussed qualitatively.

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Section: Thermal Stress and Residual State Near The Rail Headsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Some comments on surface cracks in rails

Fischer

Daves

Pippan

et al. 2006

Fatigue Fract Eng Mat Struct

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“…These are tensile stresses at lower and compressive stresses at higher temperatures. Due to Boudnitski and Edel [15] most European rail failures occur at temperatures at or slightly above . At this temperature high tensile thermal stresses are combined with relatively low toughness values of the rail materials.…”

Section: Loading Of Railsmentioning

confidence: 99%

Fatigue crack initiation life prediction of railroad

Tehrani¹,

Saket²

2009

J. Phys.: Conf. Ser.

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Abstract. Study of multiaxial high-cycle fatigue initiation life prediction for railroad is done in this paper. Using ANSYS 11.0 software three dimensional elasto-plastic finite element model of rail/wheel contact is constructed and fine mesh technique in contact region is used to achieve both computational efficiency and accuracy. Stress analysis is performed and fatigue damage in railroad is evaluated numerically using multiaxial fatigue crack initiation model. Using the stress history during one loading cycle and fatigue damage model, the effects of vertical loading, material hardness material fatigue properties and wheel/rail contact situation on fatigue crack initiation life are investigated.

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“…Other transverse crack types such as straight and semi-elliptical surface cracks in the rail head (c and d) and in the rail foot (f) and corner cracks at both sites (b, g, d) have also been investigated (e.g. [101][102][103][104]). Besides the transverse crack geometries shown in Figure 55, further crack configurations such as web cracks induced by bolt holes and weldments, vertical axial rail head cracks (splits) and cracks in switches have been investigated as well [105][106][107][108][109][110][111].…”

Section: Final Crack Propagationmentioning

confidence: 99%

Introduction to the damage tolerance behaviour of railway rails – a review

Zerbst¹,

Lundén

Edel

et al. 2009

Engineering Fracture Mechanics

174

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Despite substantial advantages in material development and in periodic non-destructive inspection together with periodic grinding and other measures in order to guarantee safe service, fatigue crack propagation and fracture is still in great demand as emphasised by the present special issue. Rails, as the heart of the railway system, are subjected to very high service loads and harsh environmental conditions. Since any potential rail breakage includes the risk of catastrophic derailment of vehicles, it is of paramount interest to avoid such a scenario. The aim of the present paper is to introduce the most important questions regarding crack propagation and fracture of rails. These include the loading conditions: contact forces from the wheel and thermal stresses due to restrained elongation of continuously welded rails together with residual stresses from manufacturing and welding in the field, which is discussed in Section 2. Section 3 provides an overview of crack-type rail defects and potential failure scenarios. Finally the stages of crack propagation from initiation up to final breakage are discussed.

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Spannungsintensitätsfaktoren für Risse in Schienen

Cited by 4 publications

References 0 publications

Some comments on surface cracks in rails

Some comments on surface cracks in rails

Fatigue crack initiation life prediction of railroad

Introduction to the damage tolerance behaviour of railway rails – a review

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