Forming Mechanism of Axial Wrinkle Defects in Inner Walls of Radial Precision Forged Gun Barrel with Integrated Forming Chamber and Rifling

doi:10.3969/j.issn.1004-132X.2023.16.013

Abstract

Abstract: Integrated radial precision forging forming the chamber and rifling of the gun barrels was efficient， and the radial forged gun barrels had high coaxiality. However， the inner walls of the barrels formed by this processes would generate axial wrinkles. The wrinkles might evolve into a fissure which significantly affected the safety of the gun barrels. To investigate the forming mechanism of wrinkle defects， a three-dimensional radial precision forging finite element model was established， and multiple sets of processing parameters such as feed speed， rotational speed， hammer angle， and clamping pressure were simulated. The simulation results show that the axial wrinkle defects in the inner walls are formed in the sinking zones of the forging processes. The gaps among the four hammerheads cause uneven radial deformation of the workpieces at the same cross-section during each forging， resulting in a difference in radial displacements. After multiple forging accumulations， the radial displacement difference between adjacent nodes on the inner walls forms the axial wrinkles. The paper also shows that the larger the hammer angle， the smaller the blank thickness， and the smaller the internal diameter of the blank， the later the wrinkle formation occurres. A wrinkle-forming criterion was established based on the radius reduction in the sinking zones， and the correctness of the criterion was verified through radial precision forging experiments.

Key words: radial precision forging with integrated forming chamber and rifling, wrinkle defect in inner wall, forming mechanism, criterion

摘要： 弹线膛一体径向精锻工艺能同时成形身管的弹膛和线膛，内膛同轴度高，成形效率高，但该工艺成形的身管内壁会产生轴向的褶皱，褶皱在后续锻造中会演化成裂缝，从而严重影响身管的安全性。为了研究内膛褶皱缺陷的形成机理，建立了三维径向精锻有限元模型，设置进给速度、转速、锤头角度、夹持压力等多组工艺参数变量进行了仿真。仿真结果表明，内膛轴向褶皱是在锻造过程的下沉段形成的，其形成机理是由于四锤头之间存在间隙，导致每次锻打时同一截面工件径向发生不均匀变形，使得径向位移产生差异，经过多次锻打累积，内壁相邻节点的径向位移差就形成了轴向褶皱。同时研究表明，锤头角度越大，毛坯厚度越小，毛坯内径越小，则褶皱形成越晚。建立了以减径量为指标的下沉段褶皱成形判据，通过径向精锻实验验证了该判据的正确性。

关键词: 弹线膛一体径向精锻, 内膛褶皱缺陷, 形成机理, 判据

CLC Number:

TG316.3

YANG Yuzhao, YANG Chen, XU Cheng, FAN Lixia. Forming Mechanism of Axial Wrinkle Defects in Inner Walls of Radial Precision Forged Gun Barrel with Integrated Forming Chamber and Rifling[J]. China Mechanical Engineering, 2023, 34(16): 1991-2000,2008.

杨宇召, 杨晨, 徐诚, 樊黎霞. 弹线膛一体径向精锻成形身管内膛轴向褶皱缺陷的形成机理[J]. 中国机械工程, 2023, 34(16): 1991-2000,2008.

References

［1］王涛. 精锻枪管炸裂与机械性能初探［J］. 四川兵工学报， 2002， 23（3）：38-40.
WANG Tao. Study on the Bursting and Mechanical Properties of Precision Forged Gun Barrel［J］. Journal of Sichuan Ordnance Industry， 2002， 23（3）：38-40.
［2］XU Weisheng， MO Jiahao， ZHANG Jin， et al. Evolution of Residual Stress and Microstructure during Annealing of 30SiMn2MoVA High-strength Alloy Steel Tube Processed by Cold Radial Forging［J］. Journal of Materials Engineering and Performance， 2021， 30（8）：5889-5897.
［3］XU Weisheng， ZHANG Jin. Investigation of Through-thickness Residual Stress， Microstructure and Texture in Radial Forged High-strength Alloy Steel Tubes［J］. Metals， 2022， 12（4）：622.
［4］樊红伟，徐宝池，樊黎霞，等. 锻后身管壁厚方向力学性能变化实验研究［J］. 精密成形工程， 2020， 12（6）：99-105.
FAN Hongwei， XU Baochi， FAN Lixia， et al. Experimental Research on the Mechanical Properties of the Forged Barrel in the Thickness Direction［J］. Journal of Netshape Forming Engineering， 2020， 12（6）：99-105.
［5］田文松，罗荣，代安源. 枪管径向冷精锻成形技术的应用研究［J］. 精密成形工程， 2009， 1（3）：58-62.
TIAN Wensong， LUO Rong， DAI Anyuan. Application Research of Radial Cold Forging Technology on Barrels Forming［J］. Journal of Netshape Forming Engineering， 2009， 1（3）：58-62.
［6］YANG Yuzhao， ZHANG Xiaoyun， FAN Lixia， et al. Mechanical Properties of Steel Gun Barrel Processed by Cold Radial Forging with Stepped Mandrel under Different Forging Ratios［J］. Journal of Physics：Conference Series， 2020， 1507：042004.
［7］GHAEI A， MOVAHHEDY M R， TAHERI A K. Finite Element Modelling Simulation of Radial Forging of Tubes without Mandrel［J］. Materials & Design， 2008， 29（4）：867-872.
［8］LI Yong， HE Ting， ZENG Zhixin. Numerical Simulation and Experimental Study on the Tube Sinking of a Thin-walled Copper Tube with Axially inner Micro Grooves by Radial Forging［J］. Journal of Materials Processing Technology， 2013， 213（6）：987-996.
［9］LI Yong， HUANG Jinlong， HUANG Guangwen， et al. Comparison of Radial Forging between the Two- and Three-split Dies of a Thin-walled Copper Tube during Tube Sinking［J］. Materials & Design， 2014， 56：822-832.
［10］陈修琳，陈岩. 铍青铜薄壁管径向锻造工艺研究［J］. 锻压技术， 2018， 43（8）：23-26.
CHEN Xiulin， CHEN Yan. Study on Radial Forging Process of Beryllium Bronze Thin-walled Tube［J］. Forging & Stamping Technology， 2018， 43（8）：23-26.
［11］刘金明，刘兵，杨晨，等. 精锻身管弹膛内壁成形圈纹缺陷机理研究［J］. 兵工学报， 2020， 41（3）：451-459.
LIU Jinming， LIU Bing， YANG Chen， et al. Research on the Forming Mechanism of Ring Pattern Defects on Inner Wall of Chamber during Precision Radial Forging Process［J］. Acta Armamentarii， 2020， 41（3）：451-459.
［12］童维，杨晨，杨宇召，等. 身管弹膛和线膛同锻时下沉段皱褶试验研究及其预测［J］. 兵工学报， 2020， 41（5）：865-873.
TONG Wei， YANG Chen， YANG Yuzhao， et al. The Experimental Study and Prediction of Wrinkles in Sinking Zone of Barrel Forged with Chamber and Rifled Bore［J］. Acta Armamentarii， 2020， 41（5）：865-873.
［13］周勐弢，杨晨，樊黎霞，等. 身管弹线膛同锻成形下沉段开裂缺陷影响因素及判断准则研究［J］. 兵器装备工程学报， 2021， 42（11）：102-108.
ZHOU Mengtao， YANG Chen， FAN Lixia， et al. Research on Influencing Factors and Judgment Criterion of Cracking Defects in Sinking Section of the Barrel Forged with Chamber and Rifled Bore［J］. Journal of Ordnance Equipment Engineering， 2021， 42（11）：102-108.
［14］HAO Qingle， HAN Jingtao， SONG Jingjie， et al. Causes and Remedies for Some Physical Defects in Rotary Swaged Products［J］. Advanced Materials Research， 2014， 941/944：1797-1801.
［15］石松，卢曦. 无芯棒旋锻径向进给参数匹配研究［J］. 塑性工程学报， 2020， 27（4）：21-26.
SHI Song， LU Xi. Research on Matching of Radial Feed Parameters of Mandrel-free Rotary Forging［J］. Journal of Plasticity Engineering， 2020， 27（4）：21-26.
［16］孙子莹，卢曦，李栋材. 无芯棒旋锻径向进给参数变化匹配研究［J］. 塑性工程学报， 2019， 26（2）：104-108.
SUN Ziying， LU Xi， LI Dongcai. Research on Matching of Radial Feed Parameters Variety of Rotary Swaging without Mandrel［J］. Journal of Plasticity Engineering， 2019， 26（2）：104-108.
［17］王宏，卢曦. 细长薄壁件旋锻成形工艺研究［J］. 农业装备与车辆工程， 2021， 59（10）：6-10.
WANG Hong， LU Xi. Study on Rotary Forging Process of Slender Thin Wall Parts［J］. Agricultural Equipment & Vehicle Engineering， 2021， 59（10）：6-10.
［18］王俊士，汪朝晖，徐文侠，等. 锤头入口曲面对旋锻加工工件变形特性的影响［J］. 塑性工程学报， 2022， 29（6）：17-24.
WANG Junshi， WANG Zhaohui， XU Wenxia， et al. Effect of Hammer Inlet Surface on Deformation Characteristics of Rotary Forged Workpiece［J］. Journal of Plasticity Engineering， 2022， 29（6）：17-24.
［19］ABE H， FURUGEN M. Method of Evaluating Workability in Cold Pilgering［J］. Journal of Materials Processing Technology， 2012， 212（8）：1687-1693.
［20］李恒，魏栋，杨恒，等. 高性能管材二辊皮尔格冷轧成形研究动态及存在问题［J］. 航空制造技术， 2018， 61（21）：16-24.
LI Heng， WEI Dong， YANG Heng， et al. Two-roller Cold Pilger Rolling of High-performance Tube：a Critical Review［J］. Aeronautical Manufacturing Technology， 2018， 61（21）：16-24.
［21］FAN Lixia， WANG Zhigang， WANG He. 3D Finite Element Modeling and Analysis of Radial Forging Processes［J］. Journal of Manufacturing Processes， 2014， 16（2）：329-334.

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