Transactions of Materials and Heat Treatment

Title：Design and realization on special control system for precision forging press

Authors： Ma Pengju1 Lan Xiaolong1 Wang Wenjie1 Liu Yong2 Tian Jie2

Unit： 1. Beihang University 2. Engineering Department Xi′an Innovation Precision Instrument Research Institute

KeyWords： precision forging press lubrication motion control multi-function control card NC software development

ClassificationCode：TP273

year,vol(issue):pagenumber：2023,48(2):149-160

Abstract：

A complete and practical research and development scheme for the special control system of precision forging press was proposed, including the development of a lubrication system to protect key components such as main engine forging box and manipulator chuck etc., and the design of a hydraulic auxiliary system to provide a stable source of power for precision forging press. Moreover, the motion control systems such as the forging of hammer head, the rotation of chuck and the feeding of manipulator were planned based on the principle of high-frequency rotary forging for the precision forging press. On this basis, the special control system was realized by the control mode of industrial computer and four multi-function control cards. Using Python as a software development tool, the multi-function control card, PLC and intermediate relays were used to realize the stable software and hardware communication and the high-precision control of each subsystem for the precision forging press. Thus, the special numerical control system for precision forging press with independent intellectual property rights was developed which lays the foundation of the application and continuous improvement of precision forging press.

Funds：

国家科技重大专项(2019ZX04018001-9)

作者简介：马鹏举（1962-），男，博士，副教授,E-mail：lanxlbuaa@126.com

Reference：

[1]Hsiang S H,Ho H L. A study on the warping problems of thin flange under the radial forging processes by FEM and experiments[J]. The International Journal of Advanced Manufacturing Technology,2005，26(1/2) 47-55.

[2]杨华, 高俊峰,何琪功,等.径向锻造机的几种典型主机结构分析[J].锻压技术,2021,46(6):16-32.

Yang H,Gao J F,He Q G,et al. Analysis of several typical main engine structures of radial forging machine [J]. Forging & Stamping Technology,2021,46(6):16-32.

[3]杨震, 王炳正,宋道春,等.径向锻造设备与工艺综述[J].锻压装备与制造技术,2018,53(6):27-30.

Yang Z,Wang B Z,Song D C,et al.Overeview of radial forging equipment and process[J]. China Metalforming Equipment & Manufacturing Technology,2018,53(6):27-30.

[4]曹明, 韩笑宇,栗文锋.四砧径向锻造工艺研究[J].大型铸锻件,2015，(4):4-7.

Cao M,Han X Y,Li W F. Research on four hammer radial forging process [J]. Heavy Casting and Forging,2015，(4):4-7.

[5]李建军, 黄茂林,彭谦之,等.锻造技术的发展现状及趋势[J].热处理技术与装备,2015,36(3):57-62.

Li J J,Huang M L,Peng Q Z,et al. Development status and trend of forging technology [J].Heat Treatment Technology and Equipment,2015,36(3):57-62.

[6]牛勇, 权晓惠,张营杰,等.现代自由锻造装备技术研究现状与发展趋势[J].精密成形工程,2015,7(6):17-24.

Niu Y,Quan X H,Zhang Y J,et al.Current developmentof free forging equipment [J]. Journal of Netshape Forming Engineering,2015,7(6):17-24.

[7]黄雷. 不锈钢身管弹膛精锻成形分析[D].南京:南京理工大学,2016.

Huang L. Precision Forging Forming Analysis of Stainless Steel Body Tube Bore[D]. Nanjing: Nanjing University of Science and Technology,2016.

[8]邹景锋, 马立峰,朱艳春,等.径向锻造成形技术及其在镁合金锻造中的应用[J].轻金属,2018，(5):48-52.

Zou J F,Ma L F,Zhu Y C,et al. The application of radial forging forming technology to magnesium alloy forging[J]. Light Metals,2018，(5):48-52.

[9]王艳芳. 精锻机锻造车轴工艺余量研究[J].内燃机与配件,2018，(24):20-21.

Wang Y F. Research on process allowance of forging axle for precision forging machine[J].Internal Combustion Engine & Parts,2018，(24):20-21.

[10]张超, 赵升吨,母东.航空锻件用径向锻机液压驱动方式合理性探讨[J].液压与气动,2014，(6):13-16.

Zhang C,Zhao S D,Mu D. Study of hydraulic driving radial forging machine for aeronautic products[J].Chinese Hydraulics & Pneumatics,2014，(6):13-16.

[11]Fan L X,Wang Z G,Wang H.3D finite element modeling and analysis of radial forging processes[J].Journal of Manufacturing Processes,2014,16 (2)：329-334.

[12]韩风, 胡强.径向锻造工艺参数对Mg-8Al-0.6Zn-0.3V镁合金棒材性能的影响[J]. 热加工工艺,2020,49(17):115-117.

Han F,Hu Q. Effect of radial forging process parameters on performance of Mg-8Al-0.6Zn-0.3V magnesium alloy bars [J]. Hot Working Technology,2020,49(17):115-117.

[13]Panov D,Pertsev A,Smirnov A,et al. Metastable austenitic steel structure and mechanical properties evolution in the process of cold radial forging[J]. Materials,2019,12 (13):2058-2076.

[14]Huang J L,Slater C D,Mandral A,et al. A dynamic model for simulation of hot radial forging process[J]. Procedia Engineering,2017,207(9): 478-483.

[15]Darki S,Raskatov E Y. Analysis of the hot radial forging process according to the finite element method [J]. The International Journal of Advanced Manufacturing Technology,2020,110(3/4):1061-1070.

[16]Koppensteiner R,Auer M. New Forging drive systemfor radial forging based on double stroke mechanism[J]. BHM Berg-und Hüttenmnnische Monatshefte，2018，63：361-366.

[17]Koppensteiner R,Auer M,Fair B,et al. GFM radial forging machines for the titanium market[A]. Proceedings of the 13th World Conference on Titanium[C].California,2016.

[18]Glushenkova S G,Polozhentsev K A,Dmitriev A I,et al. Development of a technology for a hydraulic radial forging machine at the elektrostal metallurgical plant[J]. Metallurgist，2017，61：394-399.

[19]夏波. RF70精锻机在线监测与故障分析[J].设备管理与维修,2013，(12):58-59.

Xia B. RF70 fine forging machine online monitoring and fault analysis [J]. Plant Maintenance Engineering,2013，(12):58-59.

[20]王飞伟. 精锻机锻造功率监测系统研究[J].设备管理与维修,2018，(18):25-27.

Wang F W.Research on forging power monitoring system of fine forging machine [J]. Plant Maintenance Engineering,2018，(18):25-27.

[21]暴怀乾, 赵洪章,刘永平.基于PROFIBUS-DP的PLC、HMI控制系统在径锻机中的应用[J].宁夏工程技术,2014,13(2):170-173.

Bao H Q,Zhao H Z,Liu Y P. Application of PROFIBUS-DP PLC,the HMI control system based on the radial forging machine [J].Ningxia Engineering Technology,2014，13(2):170-173.

[22]陈殿领. 利用西门子电气对1400 t精锻机进行电气及数控化改造[J].制造技术与机床,2011，(9):133-135,150.

Chen D L. The electrical and NC transformation for 1400 t precision forging machine using SIEMENS electric [J]. Manufacturing Technology & Machine Tool,2011，(9):133-135,150.

[23]李显通. SXP-130卧式精锻机电控系统改造[J].设备管理与维修,2019，(1):88-89.

Li X T.Transformation of SXP-130 horizontal precision forging electromechanical control system[J].Plant Maintenance Engineering,2019，(1):88-89.

[24]苏振华, 张营杰,冯东晓,等.基于PID+前馈的3 MN径向锻造机控制系统的研究[J].重型机械,2020，(3):44-47.

Su Z H,Zhang Y J,Feng D X,et al.Research and development of the contron system based on PID closed-loop control plus feedforward for 3 MN radial-direction hydraulic forging machine [J]. Heavy Machinery,2020，(3):44-47.

[25]葛鹏. 1.6 MN精锻机主机设计[D]. 兰州:兰州交通大学,2016.

Ge P. Design of 1.6 MN Fine Forging Machine [D]. Lanzhou:Lanzhou Jiaotong University,2016.

[26]李佳, 何雪龙,黄艳龙,等.径锻机锤头调节过程分析[J].锻压装备与制造技术,2016,51(6):28-29.

Li J,He X H,Huang Y L,et al. Analysis on adjustment process of hammer head of diameter forging machine [J]. China Metalforming Equipment & Manufacturing Technology,2016,51(6):28-29.

[27]武哲. 径锻机四锤头液压伺服系统的同步特性研究[D]. 兰州:兰州理工大学,2015.

Wu Z. Research on Synchronous Characteristics of Four Hammer Hydraulic Servo System of Diameter Forging Machine [D]. Lanzhou: Lanzhou University of Technology,2015.

[28]李阳, 白景年,王飞云,等.精锻机夹头结构及运行原理研究[J].机械工程师,2014,(1):173-174.

Li Y,Bai J N,Wang F Y,et al. Study on chuck structure and function theory of forging machine [J].Mechanical Engineer,2014,(1):173-174.

[29]赵玮. 精锻机随动控制系统的设计[D].太原:太原科技大学,2013.

Zhao W. Design of Servo Control System for Fine Forging Machine [D]. Taiyuan:Taiyuan University of Science and Technology,2013.

[30]王飞伟, 朱秦岭,杨鹏飞,等.磁致伸缩位移传感器在精锻机夹头中的应用[J].中国设备工程,2018，(18):201-203.

Wang F W,Zhu Q L,Yang P F,et al.Application of magnetostrictive displacement sensor in chuck of fine forging machine [J]. China Plant Engineering,2018，(18):201-203.

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