Boštjan Bradaškja scite author profile

Boštjan Bradaškja

4Publications

20Citation Statements Received

99Citation Statements Given

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Affiliations

Acroni (Slovenia), University of Ljubljana

Publications

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Deformation Behaviour and Microstructural Evolution During Hot Compression of AISI 904L

Bradaškja

Pirnar

Fazarinc

et al. 2011

steel research int.

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The hot deformation behaviour and microstructural evolution of AISI 904L super‐austenitic steel has been investigated by means of hot compression tests. The tests were carried out on a Gleeble 1500D thermo‐mechanical simulator in the temperature range from 850 °C to 1150 °C and at strain rates range from 0.001 s−1 to 5 s−1. The microstructure evolution was examined by means of light optical microscopy (LOM). The results show that after an initial deformation hardening, softening mechanisms occur. The peak stress level decreases with increasing deformation temperature and decreasing strain rate, which can be represented by a Zener–Hollomon parameter in the hyperbolic‐sine equation with the activation energy for deformation of 463 kJ/mol. The steady state was achieved at maximum strain of 0.9 only at the lower strain rates (under 1 s−1) and the higher temperatures (above 1100 °C). Microstructural analyses showed a gradual increase in the dynamically recrystallized area with an increase of the temperature and a decrease of the strain rate. The grain size did change, as expected, correlating to the deformation conditions.

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Mean-flow-stress analysis of laboratory hot-rolled S1100QL steel with minor Nb addition

Foder¹,

Klančnik²,

Burja³

et al. 2020

Mater. Tehnol.

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Hot Deformation Behavior of C-Mn Steel with Incomplete Recrystallization during Roughing Phase with and without Nb Addition

Klančnik¹,

Foder

Bradaškja

et al. 2022

Metals

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The objective of the study is to improve understanding of the practical role of niobium (Nb) in the case of industrial inconsistent rolling processes such as the rolling of heavy gauge plates where a lower stored energy rolling practice will result in a less stable and less repeatable static recrystallization (SRX) activation that prevents complete recrystallization. In the current study, these variabilities are validated by comparing the mean flow stress (MFS) indirectly determined from the rolling force measured on a reverse four-high rolling mill stand. The material resistance to deformation and grain size evolution of a C-Mn steel during hot rolling was observed and validated with and without Nb addition. The pre-defined rolling schedule was predicted to exhibit incomplete recrystallization in the roughing phase due to the limited stored energy of deformation that resulted from low rolling loads and a higher number of rolling passes. The prior austenite grain size (PAGS) distribution was predicted and compared to the measured effective ferrite grain (FG) size distribution after the completion of hot rolling and phase transformation achieved using natural air plate cooling. Both the predicted PAG and measured FG distributions revealed the presence of multimodality, and both distributions were used for grain size reduction factor determination for γ → α transformation for the current study with 1.96 for 0 Nb and 1.70 for 240 Nb. The results presented in this paper are not only limited to the rolling schedule used in this paper because instabilities resulting in incomplete austenite conditioning are also observed when evaluating the cross-sections of other heavy plates and various steel grades utilizing different processing routes with comparable compositions such as modern lean abrasion-resistant steels, regular line pipe steels, and other similar grades.

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Development of New Testing Procedure for Physical Simulation of the Continuous‐Casting Process for Steels

Bradaškja¹,

Fazarinc

Kugler

2012

steel research int.

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A new testing procedure was developed to simulate the microstructural changes encountered during the continuous‐casting process of steels. It offers a simultaneous guide to the temperature and mechanical loading with great accuracy. In the present study, two types of experiments were conducted for two different thermo‐mechanical programs: the first type with melting of the specimen before the simulation, and second type with homogenization of the specimen prior to conducting the simulation. The results show that the testing set‐up can be implemented to define the optimum process parameters during continuous casting. Furthermore, the test can also be used to study other microstructural changes in steels or other metals during complex thermo‐mechanical loadings.

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