Optimization of 3D scanning and inspection scheme for thin plate components based on TRIZ theory

doi:10.13474/j.cnki.11-2246.2024.0218

Abstract

Abstract: To address the difficulties in overall data acquisition, low efficiency, and the inability to simulate real operating conditions in the process of three-dimensional scanning and inspection of thin plate components, researchers are currently optimizing the three-dimensional scanning and inspection scheme for thin plate components based on TRIZ innovation theory. After analyzing the existing issues, they employ methods such as causal chain analysis, nine-screen diagram, and technical contradictions, by integrating these methods with the actual scanning process of thin plate components, they are designing a multi-point flexible fixture to optimize the 3D scanning and inspection process. They validate the optimization process using automotive sheet metal parts as an example, providing a new, efficient, and accurate inspection method for quality assessment of thin plate components.

Key words: TRIZ theory, thin plate components, automotive sheet metal parts, 3D scanning, multi-point flexible fixture

CLC Number:

WANG Zhanhui, FENG Chaojie, GUO Xiaofan, GAO Fei, DU Xiaopeng, WEI Xun. Optimization of 3D scanning and inspection scheme for thin plate components based on TRIZ theory[J]. Bulletin of Surveying and Mapping, 2024, 0(2): 100-106.

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