Assessment of internal quality of billets using ultrasonic three-dimensional layered characterization
作者机构:School of Mechanical EngineeringUniversity of Science and Technology BeijingBeijing100083China Collaborative Innovation Center of Steel TechnologyUniversity of Science and Technology BeijingBeijing100083China
出 版 物:《Journal of Iron and Steel Research International》 (钢铁研究学报(英文版))
年 卷 期:2024年第31卷第11期
页 面:2727-2739页
核心收录:
学科分类:08[工学] 080502[工学-材料学] 0805[工学-材料科学与工程(可授工学、理学学位)]
基 金:supported by the joint funds of the National Natural Science Foundation of China (Grant No. U22A20186) the Open Foundation of Key Laboratory of Metallurgical Equipment and Control Technology (Wuhan University of Science and Technology) Ministry of Education (Grant No. MECOF2019804) the Foundation of Key Technologies R&D Program of Guangdong Province (Grant No. 2020B0101130007)
主 题:Internal quality of billets Ultrasonic testing Scanning acoustic microscope Layered characterization Three-dimensional reconstruction
摘 要:To address the challenge of visualizing internal defects within castings, ultrasonic nondestructive testing technology has been introduced for the detection and characterization of internal defects in castings. Ultrasonic testing is widely utilized for detecting and characterizing internal defects in materials, thanks to its strong penetration ability, wide testing area, and fast scanning speed. However, traditional ultrasonic testing primarily relies on one-dimensional waveforms or two-dimensional images to analyze internal defects in billets, which hinders intuitive characterization of defect quantity, size, spatial distribution, and other relevant information. Consequently, a three-dimensional (3D) layered characterization method of billets internal quality based on scanning acoustic microscope (SAM) is proposed. The method starts with a layered focus scanning of the billet using SAM and pre-processing the obtained sequence of ultrasonic images. Next, the ray casting is employed to reconstruct 3D shape of defects in billets, allowing for characterization of their quality by obtaining characteristic information on defect spatial distributions, quantity, and sizes. To validate the effectiveness of the proposed method, specimens of 42CrMo billets are prepared using five different processes, and the method is employed to evaluate their internal quality. Finally, a comparison between the ultrasonic image and the metallographic image reveals a difference in dimensional accuracy of only 2.94%. The results indicate that the new method enables visualization of internal defect information in billets, serving as a valuable complement to the traditional method of characterizing their internal quality.