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Due to its high production flexibility, roller hemming has become the mainstream process for forming and joining metal sheets in the automotive industry. The traditional roller hemming process requires specific dies to support sheet metal parts and repeated offline manual adjustment of hemming routes, resulting in high die costs, high time consumption, and excessive labor inputs. The universal platform presented in this paper could replace specific dies to effectively reduce costs and expand production flexibility. To reach this objective, a vision-based automatic compensation path to achieve a dies-free roller hemming process is proposed and investigated in this paper. Hand–eye sensor modules assisted by multi-coordinate synchronization calibration for the roller hemming were designed to reconstruct three-dimensional (3-D) shape data of the incoming materials. Results from the proposed system were validated with experimental measurements for the sheet offset and the compensation of the arm hemming position, showing that the single-axis error can be reduced to ≤0.1 mm.
Yi-Ping Huang; Bor-Tung Jiang; Chia-Hung Wu; Jen-Yuan Chang. Vision-Based Path Guidance to Achieve Dies-Free Roller Hemming Process. Applied Sciences 2021, 11, 5741 .
AMA StyleYi-Ping Huang, Bor-Tung Jiang, Chia-Hung Wu, Jen-Yuan Chang. Vision-Based Path Guidance to Achieve Dies-Free Roller Hemming Process. Applied Sciences. 2021; 11 (12):5741.
Chicago/Turabian StyleYi-Ping Huang; Bor-Tung Jiang; Chia-Hung Wu; Jen-Yuan Chang. 2021. "Vision-Based Path Guidance to Achieve Dies-Free Roller Hemming Process." Applied Sciences 11, no. 12: 5741.
Assembly is the final process of manufacturing, and a good assembly plan reduces the effect of the tolerance generated in the early stages by the tolerance elimination. In the current assembly lines, the assemblers pick up the workpieces and install them together by the assembly instructions. When the workpieces are oversize or undersize, the product can not be installed correctly. Therefore, the assembler considers the secondary processing to fix the tolerance and then installs them together again. The product could be installed, but the product quality may be reduced by the secondary process. So, we formulate the assembly process as a combinatorial optimization problem, named by the dimensional chain assembly (DCA) problem. Given some workpieces with the corresponding actual size, computing the assembly guidance is the goal of the DCA problem, and the product quality is applied to represent the solution quality. The assemblers follow the assembly guidance to install the products. We firstly prove that the DCA problem is NP-complete and collect the requirements of solving the DCA problem from the implementation perspective: the sustainability, the minimization of computation time, and the guarantee of product quality. We consider solution refinement and the solution property inheritance of the single-solution evolution approach to discover and refine the quality of the assembly guidance. Based on the above strategies, we propose the assembly guidance optimizer (AGO) based on the simulated annealing algorithm to compute the assembly guidance. From the simulation results, the AGO reaches all requirements of the DCA problem. The variance of the computation time and the solution quality is related to the problem scale linearly, so the computation time and the solution quality can be estimated by the problem scale. Moreover, increasing the search breadth is unnecessary for improving the solution quality. In summary, the proposed AGO satisfies with the necessaries of the sustainability, the minimization of computation time, and the guarantee of product quality for the requirements of the DCA, and it can be considered in the real-world applications.
Chen-Kun Tsung; Tseng-Fung Ho; Hsuan-Yu Huang; Shu-Hui Yang; Po-Nien Tsou; Ming-Cheng Tsai; Yi-Ping Huang. Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly. Sustainability 2020, 12, 4690 .
AMA StyleChen-Kun Tsung, Tseng-Fung Ho, Hsuan-Yu Huang, Shu-Hui Yang, Po-Nien Tsou, Ming-Cheng Tsai, Yi-Ping Huang. Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly. Sustainability. 2020; 12 (11):4690.
Chicago/Turabian StyleChen-Kun Tsung; Tseng-Fung Ho; Hsuan-Yu Huang; Shu-Hui Yang; Po-Nien Tsou; Ming-Cheng Tsai; Yi-Ping Huang. 2020. "Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly." Sustainability 12, no. 11: 4690.