Transactions of Materials and Heat Treatment

Title：Continuous ring-roller spinning process on stainless steel seamless tube without intermediate annealing

Authors： Xu Yiwei1 Li Shaolu1 Zhao Jun2 Zhao Ning1 Zhao Chunjiang1 3

Unit： 1. School of Mechanical Engineering Taiyuan University of Science and Technology 2. School of Information Science and Technology Taiyuan University of Science and Technology 3. Transfer Preparatory Office of Modern College of Humanities and Sciences of Shanxi Normal University

KeyWords： ring-roller spinning process stainless steel seamless tube stress triaxiality microstructure stress state

ClassificationCode：TG335.71

year,vol(issue):pagenumber：2023,48(5):137-146

Abstract：

A new process of ring-roller spinning was proposed, which has a plane compressive shear stress state where the stress triaxiality in the deformation zone was less than the fracture cut-off value，namely, η＜-1/3, and the influence laws of this stress state on the plastic deformation during the ring-roller spinning process for tube was investigated. Then, the stress state distribution in the deformation zone and the microstructure evolution characteristics based on this stress state were verified by a combination of finite element and material characterization method, and the wall-reducing processing of 304 austenitic stainless steel seamless tube with the size of 57 mm×3 mm was carried out by a rotary ring-roller spinning machine of independent design and processing. Furthermore, the stainless steel seamless tube with the minimum wall thickness of 0.35 mm were obtained after five passes of continuous ring-rolling spinning process without intermediate annealing, and the morphological characteristics, material properties and microstructure of the processed tube specimens were characterized. The results show that after forming the wall thickness uniformity of tube is good, the volume fraction of martensite phase increases to 35%, and reaches the peak value. When the cumulative deformation amount reaches 1.8 mm, the grain size reaches 200 nm and remains stable. The subsequent plastic deformation process is achieved through grain tensile fracture and grain boundary strengthening plasticizing effects.

Funds：

国家自然科学基金面上项目（52275358）

作者简介：许镱巍（1995-），男，博士研究生,E-mail：xuyiweiedu@163.com;通信作者：赵春江（1975-），男，博士，教授,E-mail：zhaochj75@163.com

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