Effects of Process Parameters on FPE in Radial Forging Processes

Abstract

Abstract:

By projecting the hammer of the radial forging process to a unit cylindrical surface, constraint conditions should be fulfilled by the parameters: radial feed rate and the axial feed rate were obtained after analysis. The relationship among the empirical triangle criterion and the processing parameters in radial forging process was derived, the effects of the parameters on FPE was analyzed. FEA software MSC.Marc/Mentat was used to simulate the radial FPE in radial forging process. Equivalent strain should be larger than the critical value and the axial compressive stress criterion were adopted in the simulation, and the simulation results were compared with the results of the empirical criterion of FPE prediction. The comparison shows that the empirical method is suitable for radial forging process design. Also, the calculation results of the process parameters are approximate accurate in estimating the FPE of radial forging process.

Key words: radial forging, forging penetration efficiency(FPE), empirical criterion, finite element analysis(FEA)

摘要：

将轴类锻件径向锻造过程的锤迹投影到单位圆柱面上,分析了径向压下率、轴向送进率等工艺参数应满足的约束条件,推导了判断径向锻造锻透性的经验三角形法则与锻造工艺参数的关系,分析了锻造工艺参数对锻透率的影响；为了验证经验法则的有效性,对轴类锻件径向锻造过程进行了数值模拟,以等效应变应大于临界值以及不出现轴向拉应力作为锻透性的判断准则，分析了工艺参数对锻透率的影响。经验准则计算结果与数值模拟结果的比较表明:采用经验准则能够有效地判断轴类锻件径向锻造过程中的锻透性，其结果偏于安全。

关键词: 径向锻造, 锻透性, 经验准则, 有限元分析

CLC Number:

TG156

Luan Qiancong, Dong Xianghuai, Wu Yunjian. Effects of Process Parameters on FPE in Radial Forging Processes[J]. China Mechanical Engineering, 2014, 25(22): 3098-3103.

栾谦聪, 董湘怀, 吴云剑. 径向锻造工艺参数对锻透性的影响[J]. 中国机械工程, 2014, 25(22): 3098-3103.

References

[1]曹洋,康凤,黄少东,等.钛合金管径向精锻数值模拟分析[J].锻压技术,2006(3):71-73.
Cao Yang,Kang Feng,Huang Shaodong,et al.Numerical Simulation Analysis of Titanium Alloy Tube Radial Precision Forging[J].Forging & Stamping Technology,2006(3):71-73.
[2]吕炎.锻件缺陷分析与对策[M].北京:机械工业出版社,1999.
[3]中国锻压协会.特种锻造[M].北京:国防工业出版社,2011.
[4]杨时勇.径向锻造的模拟实验研究[J].金属成形工艺,1987(3):23-26.
Yang Shiyong.Simulation and Experiment Study of Radial Forging[J].Metal Forming Technology,1987(3):23-26.
[5]Yang Shiyong. Research into the GFM Forging Process[J]. Journal of Materials Processing Technology, 1991, 28(3): 307-319.
[6]王振范,胡宗式.径向锻造终锻过程的流函数法解析[J].东北大学学报(自然科学版),1994,15(1):35-39.
Wang Zhenfan,Hu Zongshi.Stream Function Method for Final Forging Process in Radial Forging[J]. Journal of Northeastern University(Natural Science),1994,15(1):35-39.
[7]周旭东,戴晓珑,王国宣,等.基于刚塑性有限元的GFM精锻锻透性仿真[J].河南科技大学学报(自然科学版),2006,27(2):1-4.
Zhou Xudong,Dai Xiaolong,Wang Guoxuan,et al.Forging Penetration Efficiency Study with Rigid-plastic FEM for GFM Forging[J].Journal of Henan University of Science & Technology(Natural Science),2006,27(2):1-4.
[8]董节功,周旭东,朱锦洪,等.径向锻造三维成形锻透性的数值模拟[J].机械工程材料,2007,11(3):76-78.
Dong Jiegong,Zhou Xudong,Zhu Hongjin,et al.FEM Simulation of Forging Penetration Efficiency of Radial Forging in 3D[J]. Materials for Mechanical Engineering,2007,11(3):76-78.
[9]Liu Xiangru,Zhou Xudong.The Forging Penetration Efficiency of C45 Steel Stepped Shaft Radial Forging with GFM Forging Machine[J].Advanced Materials Research,2011,154/155:593-596.
[10]胡宗式. 精锻钛合金棒材的锻透性[J]. 钛工业进展, 2000(5):15-18.
Hu Zongshi.Forging Penetration Efficiency of Forging Titanium Rod[J].Titanium Industry Progress,2000(5):15-18.

[1]	TANG Kun, SHU Yong, LI Dianyu, KONG Minghui, LUO Hong, YU Jianwu, ZHANG Mingjun, MAO Cong. Precision GHP Mold Manufacturing for Dual Aspherical Chalcogenide GlassLens with Small Aperture [J]. China Mechanical Engineering, 2022, 33(02): 217-225.
[2]	YANG Qinghua;QIN Zhengyong;WANG Zhiheng;BAO Guanjun. Influences of Two-dimensional Electro-hydraulic Flutters on Cold Extrusion Forming [J]. China Mechanical Engineering, 2019, 30(05): 621-629.
[3]	ZHANG Wentao1;WANG Zhenhu2;FANG Xiangdong3;YANG Xuyue1;LI Luoxing2;WANG Wanlin2. A Calculation Method of Car Body in White's Static Stiffness Based on Modal Theory [J]. China Mechanical Engineering, 2018, 29(05): 511-518.
[4]	LIN Xiezhao;WANG Fuzhen. Multi-objective Optimization of Threaded Connection on Tension Rods for a Uniform Load Distribution between Teeth [J]. China Mechanical Engineering, 2017, 28(17): 2024-2028.
[5]	JING Xuan1;TAN Yuanqiang2;ZHU Jie3. Impacts of Magnetic Flux Coupling on Force Arrangements of Radial Magnetic Bearings and Its Decoupling Control Strategies [J]. China Mechanical Engineering, 2017, 28(14): 1669-1676.
[6]	ZHU Xiaohua;JING Yang. Analysis of Main Influence Factors for Slip Ring Combined Rotating Seals Based on 3D Contact [J]. China Mechanical Engineering, 2017, 28(13): 1548-1553.
[7]	Du Fengshan, Fu Zhiqiang, Yu Hui. Roll Flower Design and Forming Mechanism of Rectangular Tubes in Cold Roll Forming Processes [J]. China Mechanical Engineering, 2016, 27(21): 2841-2845.
[8]	Liu Kai, Cao Yi, Ding Rui. Design and Analysis of LEMs Planar Springs [J]. China Mechanical Engineering, 2016, 27(19): 2663-2667,2674.
[9]	Li Guolong, Zhao Jun, Liu Xiaoxu, Yang Yong. Construction of SLD in Gear Hobbing Process Based on FEA [J]. China Mechanical Engineering, 2016, 27(17): 2286-2292,2297.
[10]	Fan Lifeng, Gao Ying, Yun Jianbin, Bai Yujie. Robustness Design for Crimping of Large Diameter Straight Welded Pipe [J]. China Mechanical Engineering, 2015, 26(8): 1112-1116.
[11]	Ge Ende, Su Honghua, Cheng Yuanqing, Fu Yucan, Xu Jiuhua, Xiao Ruiheng. Residual Stress Fields and Fatigue Life of Cold Expansion Hole in Titanium Alloy TC4 [J]. China Mechanical Engineering, 2015, 26(7): 971-976.
[12]	Tang Jinyuan, Zhao Guowei. Research on Lightweight Design for Disc Brake Caliper [J]. China Mechanical Engineering, 2015, 26(17): 2285-2290.
[13]	Luo Zhenxing, Dong Mingming, Zeng Rongbing. Research on Working Stress and Stiffness of Vehicle Suspension Coiled Spring [J]. China Mechanical Engineering, 2014, 25(22): 3119-3123.
[14]	Meng Longhui, He Ning, Li Liang. Calculation of Residual Stress Induced by Machining in Internal Surface of TC4 Tubular Parts and Its FEA [J]. China Mechanical Engineering, 2014, 25(19): 2583-2587.
[15]	Zhong Liangwei, Li Xiaowei, Hu Shougen. Research on Parametric Modeling and Mechanical Properties of Lightweight Lattice Structures [J]. China Mechanical Engineering, 2014, 25(16): 2253-2261.