Transactions of Materials and Heat Treatment

Title：Effect of Pilger hot-rolling process parameters on bonding layer and ovality of 06Cr19Ni10/Q235 bimetal composite pipe

Authors： He Zonglin1 Chen Jianxun1 Shuang Yuanhua1 Gou Yujun2 Ding Xiaofeng1 Gui Hailian1 Huang Ximeng3

Unit： (1.College of Material Science and Engineering Taiyuan University of Science and Technology Taiyuan 030024 China 2.College of Vehicle Engineering Taiyuan University of Science and Technology Taiyuan 030024 China 3.Shanxi Gangheli New Material Technology Co. Ltd. Taiyuan 030024 China)

KeyWords： Pilger hot-rolling bimetal composite pipe feeding amount rotation angle ovality bonding layer

ClassificationCode：TG339

year,vol(issue):pagenumber：2023,48(6):96-101

Abstract：

In order to improve the quality of bimetal composite pipes by Pilger hot-rolling, the critical theory was put forward. For the process parameters such as feeding amount and rotation angle, the numerical simulation and experimental research were carried out on the Pilger hot-rolling process of 06Cr19Ni10/Q235 bimetal composite pipe. Then, the influences of feeding amount and rotation angle on bonding layer and ovality of bimetal composite pipe were studied, and the reliability of the critical theory was verified. The results show that the smaller rotation angle makes the stress on the bonding layer of bimetal composite pipe uniform, and the stress on the bonding layer is greater. When the ratio of rotation angle to feeding amount is close to the critical value 20°·mm-1, the maximum size of inclusion in the bonding layer of bimetal composite pipe is less than 8 μm, the ovality is 1.2 mm, and the formability is good. When the ratio is below the critical value 20°·mm-1, the maximum size of inclusions in the bonding layer of bimetal composite pipe is less than 6 μm, the avality is 1.1 mm, and cracking occurs locally. When the ratio is higher than the critical value 20°·mm-1, the maximum size of inclusions in the bonding layer of bimetal composite pipe reaches 25 μm, the avality is 11.8 mm, and cracking and earing occur at the same time.

Funds：

山西省科技重大专项（20191102009）；山西省重点研发计划项目(201903D121049）；太原科技大学博士科研启动金项目（20222045）；太原科技大学大学生创新训练项目（XJ2022024）

何宗霖（1982-），男，博士，副教授

Reference：

［1］Alcaraz J L, Gil-Sevillano S J, Martinez-Esnaola J M. A fracture condition based on the upper bound method for the extrusion of bimetallic tubes
［J］. Journal of Materials Processing Technology,1996,61(3):265-274.

［2］Wright H D, Oduyemi T O S,Evans H R. The experimental behaviour of double skin composite elements
［J］. Journal of Constructional Steel Research,1991,19(2):97-110.

［3］王纯，毕宗岳，张万鹏，等.国内外双金属复合管研究现状
［J］.焊管，2015，38 (12):7-12.

Wang C, Bi Z Y, Zhang W P, et al. Research status on double-metal composite pipe at home and abroad
［J］. Welded Pipe and Tube,2015,12(38):7-12.
［4］王永飞，赵升吨，张晨阳.双金属复合管成形工艺研究现状及发展
［J］.锻压装备与制造技术，2015，50(3):84-89.

Wang Y F, Zhao S D, Zhang C Y. Research status and development of forming technology for bi-metal-lined pipe
［J］. China Metalforming Equipment & Manufacturing Technology,2015,50(3):84-89.

［5］Niu G, Sui Y D, Zeng H B,et al. Effect of centrifugal casting temperature on the microstructure and properties of ZTAP/HCCI matrix composites
［J］. Materials Research Express, 2021,(8): 026513.

［6］汪华林，李海林，吴东棣.离心铝热法制造陶瓷衬里复合管 Ⅲ:中试研究
［J］.化工机械, 1998,(5):13-15,62.

Wang H L, Li H L, Wu D L. Fabrication of ceramic lined composite pipes by centrifugal thermit process Ⅲ:Pilot study
［J］. Chemical Machinery,1998,(5): 13-15,62.

［7］Nie H H, Liang W, Chen H S, et al. Vacuum hot pressed AZ31/UCF/AZ31 composite sheets:Microstructure and mechanical properties
［J］. Vacuum, 2017,(144): 247-255.

［8］Ding Y, Cao R, Yan Y J. Effects of heat treatment on fracture mechanism of martensite/austenite MLS composite plates by hot roll bonding
［J］. Materials Science & Engineering A,2020,(773): 138727.

［9］张晶晶, 刘洁, 曹志刚,等.不同轧制压下率对热轧NM500/Q345/NM500复合板界面微观组织的影响
［J］.热加工工艺, 2019,48(3):52-56.

Zhang J J, Liu J, Cao Z G. et al. Effect of different rolling reduction rate on microstructure of interface of hot-rolled NM500/Q345/NM500 composite plate
［J］. Hot Working Technology,2019,48(3):52-56.

［10］白于良，李晶琨，刘雪峰，等.感应加热温度对冷-热轧制成形钛/钢复合板界面的影响
［J］.工程科学学报，2020, 42(12)： 1639-1646.

Bai Y L，Li J K，Liu X F. et al. Effect of induction heating temperature on the interface of cold-hot-rolled titanium/steel composite plates
［J］. Chinese Journal of Engineering, 2020, 42(12)：1639-1646.

［11］吕泽华，Agamuradov Dayanch，张志雄，等.热轧双覆层不锈钢/碳钢复合板组织与性能研究
［J］.塑性工程学报，2020,27(7):168-175.

Lyu Z H, Agamuradov D, Zhang Z X. et al. Research on microstructure and properties of double cladding stainless steel / carbon steel clad plate by hot rolling
［J］. Journal of Plasticity Engineering,2020,27(7):168-175.

［12］李豪.热轧复合不锈钢-碳钢层合板的界面层性能与塑性变形行为
［D］.北京：北京科技大学，2020.

Li H. Interface Layer Properties and Plastic Deformation Behavior of Hot Rolling Bonded Stainless/Carbon Steel Clad Plate
［D］. Beijing:Beijing University of Science and Technology, 2020.

［13］Vaidyanath L R, Nicholas M G, Milner D R. Pressure welding by rolling
［J］. British Welding Journal,1959,(6):13-28.

Service：

【This site has not yet opened Download Service】【Add Favorite】