ANALYSIS OF THE STATISTICAL DATA GENERATED BY AN ADAPTIVE STRETCH FORMING PROCESS

C. Grigoras, V. Zichil, Cătălin Drob, V. Ciubotariu
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Abstract

: Constant industrial processes improvements represent a fundamental step in the evolution of efficient processing. Due to physical or financial limits, there is a limit to how the mechanical or electronic side can be optimised. A solution for improving industrial processes can come in the form of complex machine algorithms that analyse the process in real-time and decide, with each step, what is optimal. To put this statement into practise, we have designed and implemented a fully operational self-adaptive stretch forming process controlled with the help of a dedicated statistical analysis algorithm. The foundation of the algorithm lies in the deformation theory of metals. In its simplest form, it can be summarised that if a sheet of metal is stretched, its length will increase as the force acting upon it increases until the ultimate tensile strength limit is reached; after this limit, failure occurs. Therefore, the algorithm analyses the material strain controlling the bi-axial nature of the stretch forming process by constantly adjusting for axial force and die speed. It does this through complex computer-vision image analysis techniques for strain measurement and stretching pressure readings as input data. The readings are analysed using the ANOVA method, providing R-squared and p-values for stretching pressure and die speed. The decisions that the algorithm takes are based on the statistical analysis of its previous decision, aiming to improve the overall process R-squared. The overall results are validated by measuring the obtained stretched parts’ deviation to the die shape. Therefore, the measurements were taken using a GOM 3D measuring system. This paper aims to explain the methodology of the algorithm using how the measurements are taken, how the statical analysis generated decisions for controlling the industrial equipment, and to analyse the statistical data generated by the self-adaptive stretch forming algorithm for the experimental study by comparing the decision it takes for each for the 20 processed 1050 aluminium alloys blanks. The results indicate the ideal succession of decisions and which path should be taken to improve the decision-making for both elastic and plastic domains.
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自适应拉伸成形过程统计数据的分析
当前位置工业过程的不断改进是高效加工的基本步骤。由于物理或财务限制,机械或电子方面的优化是有限的。改善工业流程的解决方案可以以复杂的机器算法的形式出现,这些算法可以实时分析流程,并在每一步中决定什么是最佳的。为了将这一说法付诸实践,我们设计并实现了一个完全可操作的自适应拉伸成形过程,该过程由专用的统计分析算法控制。该算法的基础是金属的变形理论。在最简单的形式中,可以总结为,如果金属板被拉伸,其长度将随着作用在其上的力的增加而增加,直到达到极限抗拉强度;超过这个限制,就会发生故障。因此,该算法通过不断调整轴向力和模具速度来分析控制拉伸成形过程双轴特性的材料应变。它通过复杂的计算机视觉图像分析技术将应变测量和拉伸压力读数作为输入数据。使用方差分析方法分析读数,提供拉伸压力和模具速度的r平方和p值。算法做出的决策是基于对之前决策的统计分析,旨在提高整个过程的r平方。通过测量得到的拉伸件与模具形状的偏差,验证了整体结果。因此,使用GOM 3D测量系统进行测量。本文旨在解释该算法的方法,使用如何测量,静态分析如何生成控制工业设备的决策,并通过比较20个加工的1050铝合金坯料的决策来分析自适应拉伸成形算法生成的统计数据,用于实验研究。结果表明了理想的决策序列,以及改进弹性和塑性领域决策的路径。
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来源期刊
International Journal of Modern Manufacturing Technologies
International Journal of Modern Manufacturing Technologies Engineering-Industrial and Manufacturing Engineering
CiteScore
0.70
自引率
0.00%
发文量
15
期刊介绍: The main topics of the journal are: Micro & Nano Technologies; Rapid Prototyping Technologies; High Speed Manufacturing Processes; Ecological Technologies in Machine Manufacturing; Manufacturing and Automation; Flexible Manufacturing; New Manufacturing Processes; Design, Control and Exploitation; Assembly and Disassembly; Cold Forming Technologies; Optimization of Experimental Research and Manufacturing Processes; Maintenance, Reliability, Life Cycle Time and Cost; CAD/CAM/CAE/CAX Integrated Systems; Composite Materials Technologies; Non-conventional Technologies; Concurrent Engineering; Virtual Manufacturing; Innovation, Creativity and Industrial Development.
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