Behaviour of S 355JO steel subjected to uniaxial stress at lowered and elevated temperatures and creep

Brnić, Josip; Čanađija, Marko; Turkalj, Goran; Lanc, Domagoj

doi:10.1007/s12034-010-0073-1

Cited by 25 publications

(21 citation statements)

References 6 publications

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“…Also, some correlations between fracture toughness determined by standard tests and those proposed by formulas based on impact energy can be found in Refs. [20][21][22]. The proposed equation in Ref.…”

Section: Engineering Fracture Toughness Assessment Based On Charpy Immentioning

confidence: 99%

AISI 316Ti (1.4571) steel—Mechanical, creep and fracture properties versus temperature

Brnić

Turkalj

Čanađija

et al. 2011

Journal of Constructional Steel Research

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Section: Engineering Fracture Toughness Assessment Based On Charpy Immentioning

confidence: 99%

AISI 316Ti (1.4571) steel—Mechanical, creep and fracture properties versus temperature

Brnić

Turkalj

Čanađija

et al. 2011

Journal of Constructional Steel Research

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“…Austenitic stainless steel, used for important structure of pressure equipment, retains high strength and excellent ductility from cryogenic to elevated temperatures [1,2]. 316L austenitic stainless steel, a common structural material, meets requirements for high-pressure vessels, pipes, valves, etc.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Behavior of 316L Stainless Steel after Strain Hardening

Peng

2017

MATEC Web Conf.

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Abstract. The effects of strain hardening on the mechanical behavior of 316L stainless steel were studied in the paper. The original and different strain hardening materials were compared to investigate the mechanical behavior. The results demonstrate that the yield strengths increase with the magnitude of strain hardening significantly, but the ultimate strengths of the original and different strain hardening materials are closed. In addition, the plastic parameters of 316L stainless steel including fracture elongation and fracture surface shrinkage decrease with the magnitude of strain hardening. Finally, the Ramberg-Osgood equation is used to predict the stress-strain curves after strain hardening, and the results indicate that the predicted values agree with the experimental values.

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“…Considering the standardized testing of material properties, uniaxial tension, and/or compression tests are most commonly used [8][9][10]. They often describe material behavior (yield stress, ultimate tensile stress, flow curve, material's anisotropy, etc.)…”

Section: Introductionmentioning

confidence: 99%

Upsetting Analysis of High-Strength Tubular Specimens with the Taguchi Method

Pepelnjak¹,

Šašek

Kudláček

2016

Metals

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Abstract:In order to obtain input data for numerical simulations of tube forming, the material properties of tubes need to be determined. A tube tensile test can only be used to measure yield stress and ultimate tensile stress. For tubes with a large diameter/thickness ratio (D/t), tensile specimens are cut out and processed in a similar way as with sheet metal. However, for thin tubes with a diameter/thickness ratio below 10, the tensile specimens could not be cut out. The flow curve of the analyzed tube with a small diameter and D/t ratio of 7 was determined with a ring-shaped specimen. The experimental force-travel diagram was acquired. A reverse-engineering method was used to determine flow curves by numerical simulations. Using an L 25 orthogonal array of the Taguchi method different flow curve parameters and friction coefficient combinations were selected. Tube upsetting with determined parameter combinations was performed with the finite element method. With analysis of variance influential equations among selected input parameters were determined for the force levels at six upsetting states. With the evaluation of known friction coefficients and flow curve parameters, K, n, and ε 0 according to the Swift approximation were determined and proved by the final shape of the workpiece.

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Behaviour of S 355JO steel subjected to uniaxial stress at lowered and elevated temperatures and creep

Cited by 25 publications

References 6 publications

AISI 316Ti (1.4571) steel—Mechanical, creep and fracture properties versus temperature

AISI 316Ti (1.4571) steel—Mechanical, creep and fracture properties versus temperature

Mechanical Behavior of 316L Stainless Steel after Strain Hardening

Upsetting Analysis of High-Strength Tubular Specimens with the Taguchi Method

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