Tensile Fracture Behavior of Progressively-Drawn Pearlitic Steels

Toribio, J.; Ayaso, Francisco-Javier; González, Beatriz; Matos, Juan-Carlos; Vergara, Diego; Lorenzo, Miguel

doi:10.3390/met6050114

Cited by 31 publications

(19 citation statements)

References 30 publications

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“…The diameters of the wires E0 and E3 were, respectively, d E0 = 11.03 mm and d E3 = 8.21 mm [32]. Accordingly, the drawing induced engineering plastic strain in the steel E3 is (d which corresponds to the engineering strain of 3.9 (the details of drawing chain behind the present study can be found in the cited paper [32]). Taking into account elevated levels of test load and rather not large wire diameters, undesirable buckling could appear during testing in the compression loading phase.…”

Section: Methodsmentioning

confidence: 64%

“…To analyse the BE in high strength steels used in civil engineering, various Bauschinger tests were carried out with the steels corresponding to two stages of the industrial seven-step cold drawing process used for obtaining commercial prestressing steel wires: the initial hot rolled bar not yet subjected to drawing to generate plastic strain (i.e., the drawing induced strain is nil there), which is labelled hereafter as the steel E0, and the steel from the intermediate drawing stage after passing through three drawing dies, which is denoted as the steel E3. The diameters of the wires E0 and E3 were, respectively, dE0 = 11.03 mm and dE3 = 8.21 mm [32]. Accordingly, the drawing induced engineering plastic strain in the steel E3 is (dE0 2 /dE3 2 ) − 1 = 0.80, which is rather moderate in comparison with that generated by the industrial drawing process rendering the diameter of manufactured prestressing wire close to 5 mm, which corresponds to the engineering strain of 3.9 (the details of…”

Section: Methodsmentioning

confidence: 99%

“…As a consequence, the manufacturing-induced residual stress-strain state is generated that strongly affects the wire failure, in particular, due to hydrogen embrittlement phenomenon [30]. During the drawing process, the material undergoes severe plastic strains and diverse microstructural changes [31][32][33][34][35][36][37].…”

Section: Introductionmentioning

confidence: 99%

“…To this end, the most relevant BE indicators were evaluated from the experimental data, and the type of appropriate strain hardening model was determined. The tests were performed taking the wires from two stages of a commercial cold drawing process, namely the as-received hot rolled bars (not yet cold drawn) and the wires from an intermediate stage of the cold drawing process, after passing three consecutive diameter reductions when the manufacturing-induced microstructural changes [32] and corresponding material behaviour anisotropy [38] become detectable. Based on the original results obtained in the present work, the most adequate type of material behaviour model is suggested to describe the fatigue performance of cold-drawn pearlitic steels for prestressing wires, which are the key constituents of prestressed concrete.…”

Section: Introductionmentioning

confidence: 99%

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Analysis of the Bauschinger Effect in Cold Drawn Pearlitic Steels

Toribio

Kharin

Ayaso

et al. 2020

Metals

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Prestressing steel wires usually undergo cyclic loading in service. Therefore, it is of interest to analyse certain features of their mechanical behaviour under this type of loading, such as the Bauschinger effect (BE) or the hardening rule, that fit the real mechanical behaviour appropriately. In this study, different samples of high strength pearlitic steel wires were subjected to cyclic tension-compression load exceeding the material yield strength, thus generating plastic strains. From the experimental results, various parameters were obtained revealing that analysed steels exhibited the so-called Masing type BE. In addition, the variation of the BE characteristics (of the effective and internal stresses) with the applied plastic pre-strain indicated that the studied materials followed a mixed strain hardening rule with the domination of the kinematic component.

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Section: Methodsmentioning

confidence: 64%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Analysis of the Bauschinger Effect in Cold Drawn Pearlitic Steels

Toribio

Kharin

Ayaso

et al. 2020

Metals

Self Cite

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“…This way, loading cycles oscillate between a null stress and a different maximum stress (σ max ) for each case of study. Thus, Load I and Load II applies a maximum load within the material elastic domain (i.e., about 75% and 90% of σ Y = 1300 MPa, 0.002% offset yield strength of a typical prestressing steel used in construction [19]: 1000 and 1200 MPa, respectively). Three additional loading schemes were also considered: a load that reaches the material yield strength at maximum load (Load III), and two loading where the maximum stress overcomes the material yield strength: Load IV, 110% of yield strength (i.e., 1400 MPa) and Load V, 125% of yield strength (i.e., 1600 MPa), respectively.…”

Section: Numerical Modellingmentioning

confidence: 99%

The Role of Overloading on the Reduction of Residual Stress by Cyclic Loading in Cold-Drawn Prestressing Steel Wires

et al. 2017

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Prestressing steel wires are commonly used as reinforcement elements in structures bearing fatigue loads. These wires are obtained by a conforming process called cold drawing, where a progressive reduction of the wire diameter is produced, causing residual stress in the commercial wire. The aim of this paper is to analyze the effect of diverse in-service cyclic loading conditions (cyclic loading and cyclic loading with overload) on such a residual stress field. To achieve this goal, firstly, a numerical simulation of the wire drawing process of a commercial prestressing steel wire was carried out to reveal the residual stress state induced by the manufacture technique. Afterwards, a numerical simulation was performed of the in-service loading conditions of a prestressing steel wire in which the previously calculated residual stress state is included. The analysis of the obtained results shows a significant reduction of the residual stress state of about 50% for common in-service loadings and as high as 90% for certain cases undergoing overloads during cyclic loading. Therefore, an improvement of the mechanical performance of these structural components during their life in-service can be achieved.

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Deformation and Microstructural Evolution of Nanostructured Pearlite under Tension versus Torsion

Khiratkar

Mishra

Singh

2020

steel research int.

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In the current work, nanostructured pearlitic steels in bulk with interlamellar spacing of 86 and 168 nm, respectively, are developed through suitable alloying combined with appropriate heat treatment. The specimens extracted from the steels are tested separately in tension and torsion. Under tensile extension, finer pearlite shows a higher yield strength and ultimate tensile strength but fractures at a lower value of strain. However, under torsion testing, finer pearlite deforms to higher shear stress while fracturing at marginally larger shear strain than the coarser pearlite. Under torsion loading, the fractured surface of the finer pearlite presents a larger length of ductile crack propagation (DCP) extending from the circumference toward the center before initiation of cleavage fracture. Scanning electron microscopy (SEM) images of the DCP region are used to characterize the deformation of cementite lamellae, whereas electron backscattered diffraction (EBSD) maps reveal the misorientation changes in ferrite due to torsion. A more frequent and irregular change in ferrite misorientation for coarser pearlite in the DCP region is observed compared with finer pearlite. Bending and fragmentation of cementite lamellae are observed to be higher for fine pearlite, suggesting better strain accommodation. Thus, decreasing the lamellar spacing in nanostructured pearlite improves the torsional response.

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Tensile Fracture Behavior of Progressively-Drawn Pearlitic Steels

Cited by 31 publications

References 30 publications

Analysis of the Bauschinger Effect in Cold Drawn Pearlitic Steels

Analysis of the Bauschinger Effect in Cold Drawn Pearlitic Steels

The Role of Overloading on the Reduction of Residual Stress by Cyclic Loading in Cold-Drawn Prestressing Steel Wires

Deformation and Microstructural Evolution of Nanostructured Pearlite under Tension versus Torsion

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