Mathematical Modeling of Carbon Content and Intercritical Annealing Temperature in DP Steels by Factorial Design Method
Gulcan TOKTAS1,Alaaddin TOKTAS1,Aslan Deniz KARAOGLAN2
1. Department of Mechanical Engineering, Balikesir University, Balikesir 10145, Turkey 2. Department of Industrial Engineering, Balikesir University, Balikesir 10145, Turkey
Mathematical Modeling of Carbon Content and Intercritical Annealing Temperature in DP Steels by Factorial Design Method
Gulcan TOKTAS1,Alaaddin TOKTAS1,Aslan Deniz KARAOGLAN2
1. Department of Mechanical Engineering, Balikesir University, Balikesir 10145, Turkey 2. Department of Industrial Engineering, Balikesir University, Balikesir 10145, Turkey
ժҪ 2k factorial design is employed to find the mathematical relation between the carbon content and intercritical annealing temperature (IAT) in order to predict the responses namely martensite volume fraction (MVF), microhardness (H), yield strength (YS), ultimate tensile strength (UTS), total elongation (TEL), yield ratio (YR) and Charpy impact energy (CIE) in dual phase (DP) steels. Steels containing different carbon contents (0.085% C and 0.380% C) had been chosen for this purpose. The main advantages of factorial design are its easy implementation and the effective computation compared with the other optimization techniques, which were employed for predicting mentioned responses in the literature. To verify the proposed approach based on factorial design, experiments for verification were performed. The results of the verification experiments and the mathematical models are in accordance with each other and the literature.
Abstract��2k factorial design is employed to find the mathematical relation between the carbon content and intercritical annealing temperature (IAT) in order to predict the responses namely martensite volume fraction (MVF), microhardness (H), yield strength (YS), ultimate tensile strength (UTS), total elongation (TEL), yield ratio (YR) and Charpy impact energy (CIE) in dual phase (DP) steels. Steels containing different carbon contents (0.085% C and 0.380% C) had been chosen for this purpose. The main advantages of factorial design are its easy implementation and the effective computation compared with the other optimization techniques, which were employed for predicting mentioned responses in the literature. To verify the proposed approach based on factorial design, experiments for verification were performed. The results of the verification experiments and the mathematical models are in accordance with each other and the literature.
Gulcan TOKTAS,Alaaddin TOKTAS,Aslan Deniz KARAOGLAN. Mathematical Modeling of Carbon Content and Intercritical Annealing Temperature in DP Steels by Factorial Design Method[J]. �й������ڿ���, 2014, 21(7): 715-722.
Gulcan TOKTAS,Alaaddin TOKTAS,Aslan Deniz KARAOGLAN. Mathematical Modeling of Carbon Content and Intercritical Annealing Temperature in DP Steels by Factorial Design Method. Chinese Journal of Iron and Steel, 2014, 21(7): 715-722.