Transactions of Materials and Heat Treatment

Title：Development of monitoring and management system for axle forging production process

Authors：

Unit：

KeyWords：

ClassificationCode：TG248

year,vol(issue):pagenumber：2019,44(8):1-5

Abstract：

For the problems that realtime monitoring was not realized in the axle forging production process, the system was difficult to achieve interconnection, the production data was more and could not achieve interoperability etc., a forging production process monitoring and management system based on the MES system framework was designed and implemented, which adopted C/S framework to realize the digital transparency of production process monitoring and assured the security and integrity of the realtime production process data resources. Additionally, through simple configuration for the networking communication with upper manufacturing execution system (MES) and lower industrial control equipment, tasking assignment and uploading forging process data etc. were conducted, and orderly and unified production scheduling, equipment operation and monitoring management were realized. Therefore, the operation efficiency of enterprises was effectively improved, and the operation complexity of engineers and technicians was minimized. The verification of production site test results shows that the proposed monitoring system has the advantages of strong realtime, simple operation and meeting the actual production needs.

Funds：

靳龙（1965-），男，学士，高级工程师 Email：13893611403@163.com

Reference：

[1]朱秀梅.车轴锻造中的质量保证体系[J].锻压装备与制造技术，1988，(1)：51-52.

Zhu X M. Quality assurance system in axle forging[J]. China Metalforming Equipment & Manufacturing Technology, 1988, (1):51-52.

[2]陶竑宇，付传锋.中国高速铁路几个重要零件的精锻成形[J]. 兵器装备工程学报，2016，37(6)：119-123.

Tao H Y, Fu C F. Precision forging and shaping of several important parts of Chinese highspeed railway[J]. Journal of Ordnance Equipment Engineering, 2016, 37(6): 119-123.

[3]闻向阳，王岩，梁进城，等. “智能制造”探索研究[J]. 自动化技术与应用，2018，37(2)：139-142.

Wen X Y, Wang Y, Liang J C, et al. “Intelligent manufacturing” exploration and research[J]. Techniques of Automation and Applications, 2018, 37(2): 139-142.

[4]吕印增. 铁路货车车轴锻造生产线浅谈[J]. 锻压装备与制造技术，2008，43(1)：41-43.

Lyu Y Z. Discussion of the axle forging production line for lorry[J]. China Metalforming Equipment & Manufacturing Technology, 2008, 43(1): 41-43.

[5]王胜强，芮执元，刘军. 制造执行系统MES及其功能技术模型[J]. 甘肃科技，2009，25(5)：18-21.

Wang S Q, Rei Z Y, Liu J. Functional and technology model of manufacturing execution system[J]. Gansu Science and Technology, 2009, 25(5): 18-21.

[6]周济.智能制造——“中国制造2025”的主攻方向[J]. 中国机械工程，2015，26(17)：2273-2284.

Zhou J. Intelligent manufacturing-Main direction of “Made in China 2025” [J]. China Mechanical Engineering, 2015, 26(17): 2273-2284.

[7]吕佑龙，张洁. 基于大数据的智慧工厂技术框架[J]. 计算机集成制造系统，2016，22(11)：2691-2697.

Lyu Y L, Zhang J. Bigdatabased technical framework of smart factory[J]. Computer Integrated Manufacturing Systems, 2016, 22(11): 2691-2697.

[8]戚景观. PC和PLC自由口通信在数码显示中的应用[J]. 智慧工厂，2011,(2)：40-42.

Qi J G. The application of free port communication between upper computer and PLC in digital display[J]. Programmable Controller & Factory Automation,2011,(2): 40-42.

[9]蔡明，张怀存.基于VC++的生产线信息管理系统开发[J]. 成组技术与生产现代化，2010，27(4)：12-17.

Cai M, Zhang H C. A production lines information management system development based on VC++[J]. Group Technology & Production Modernization, 2010, 27(4): 12-17.

[10]王道守，王正超. 基于UDP协议网络实时通讯系统的设计与实现[J]. 电脑学习，2009，(3)：33-35.

Wang D S, Wang Z C. Design and realization of network realtime communication system based on UDP protocol[J]. Intelligent Computer and Applications, 2009, (3): 33-35.

[11]郝浩. FTP原理解析[J].计算机与网络，2016，42(14)：40-41.

Hao H. Analysis of FTP principle [J]. Computer & Network, 2016, 42(14): 40-41.

[12]黄玉昌. 基于FTP协议的企业级文件传输系统设计[J]. 中国新通信，2018，20(6)：134-135.

Huang Y C. Design of enterpriselevel file transfer system based on FTP protocol[J]. China New Telecommunications, 2018, 20(6): 134-135.

Service：

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