Optimization of Neural Network for Charpy Toughness of Steel Welds

被引：27

作者：

Pak, Junhak ^{[1
]}

Jang, Jaehoon ^{[1
]}

Bhadeshia, H. K. D. H. ^{[1
]}

Karlsson, L. ^{[2
]}

机构：

[1] Pohang Univ Sci & Technol, GIFT, Pohang 790784, Kyungbuk, South Korea

[2] Cent Res Labs, ESAB AB, Gothenburg, Sweden

来源：

MATERIALS AND MANUFACTURING PROCESSES | 2009年 / 24卷 / 01期

关键词：

Bias; Charpy energy; Neural networks; Welds; STRAIN-INDUCED TRANSFORMATION; TRIP-AIDED STEELS; LOW-ALLOY STEELS; RETAINED AUSTENITE; IMPACT TOUGHNESS; PHASE-CHANGE; STRENGTH; MICROSTRUCTURE; KINETICS; MODEL;

D O I：

10.1080/10426910802540232

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

By their very nature, empirical models must be treated with care in order to avoid predictions which are not physically possible. One example is the calculation of the Charpy impact toughness of steel welds as a function of composition and processing, where the impact energy should not be negative. However, there is nothing to prevent a user from implementing inputs which lead to nonsensical results. We examine here whether a scheme used in kinetic theory can be generalized to create neural networks which are bounded. It is found that such procedures lead to bias. In the process of doing this work, some interesting trends have been discovered on the role of process parameters in determining the toughness of steel welds.

引用

页码：16 / 21

页数：6

共 50 条

[31] Modeling of the Stress in 13Cr Supermartensitic Stainless Steel Welds by Artificial Neural Network
Yu, Junhui
Zou, Dening
Han, Ying
Chen, Zhiyu
ECO-MATERIALS PROCESSING AND DESIGN XI, 2010, 658 : 141 - 144
[32] Optimization of strength and toughness of railway wheel steel by alloy design
Zeng, Dongfang
Lu, Liantao
Gong, Yanhua
Zhang, Ning
Gong, Yubin
MATERIALS & DESIGN, 2016, 92 : 998 - 1006
[33] CHARPY NOTCH TOUGHNESS AND HARDNESS OF REHEATED MARTENSITE AND LOWER BAINITE
Vodopivec, F.
Sustarsic, B.
Vojvodic-Tuma, J.
Kosec, G.
METALURGIJA, 2010, 49 (03): : 149 - 154
[34] Microstructural and chemical dependences of fracture toughness in stainless steel welds at 4.2 K
Fu, Yang
Liu, Qi
Lv, Ying-Bin
Zhang, Mao -Long
Xin, Ji-Jun
Zhu, Ming -Liang
Xuan, Fu -Zhen
ENGINEERING FRACTURE MECHANICS, 2024, 305
[35] STRENGTH-MISMATCH EFFECT ON STEEL WELD HAZ-TOUGHNESS IN CTOD AND CHARPY TESTS
Chiba, Y.
Murayama, K.
Satoh, S.
Miyashiro, K.
Ohata, M.
Minami, F.
WELDING IN THE WORLD, 2010, 54 (5-6) : R147 - R153
[36] Cryogenic fracture toughness of 9%Ni steel flux cored arc welds
Mu, Weidong
Li, Yuzhang
Cai, Yan
Wang, Min
JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 2018, 252 : 804 - 812
[37] Effects of untransformed ferrite on Charpy impact toughness in 1.8-GPa-grade hot-press-forming steel sheets
Jo, Min Cheol
Park, Jaeyeong
Sohn, Seok Su
Kim, Seongwoo
Oh, Jinkeun
Lee, Sunghak
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2017, 707 : 65 - 72
[38] Strength-Mismatch Effect on Steel Weld HAZ-Toughness in CTOD and Charpy Tests
Yasutake Chiba
Keiji Murayama
Susumu Satoh
Kyohsuke Miyashiro
Mitsuru Ohata
Fumiyoshi Minami
Welding in the World, 2010, 54 : R147 - R153
[39] Mild Steel GMA Welds Microstructural Analysis and Estimation Using Sensor Fusion and Neural Network Modeling
Caio, Leandro Bruno Alves
Silva, Alysson Martins Almeida
Bestard, Guillermo Alvarez
Vieira, Lais Soares
de Carvalho, Guilherme Caribe
Alfaro, Sadek Crisostomo Absi
SENSORS, 2021, 21 (16)
[40] Unexpected Charpy Impact Toughness Spike of 1.25Cr-0.5Mo Steel After Simulated Postweld Heat Treatment
Shen, Yang
Wang, Cong
METALLURGICAL AND MATERIALS TRANSACTIONS B-PROCESS METALLURGY AND MATERIALS PROCESSING SCIENCE, 2019, 50 (02): : 595 - 600

← 1 2 3 4 5 →