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浙江大学学报(工学版)
Journal of ZheJiang University (Engineering Science)  2020, Vol. 54 Issue (2): 357-364    DOI: 10.3785/j.issn.1008-973X.2020.02.017
Mechanical and Energy Engineering     
Voxel-based recognition and visualization of water leakage gaps for automobile assembly
Jian-hui FU1(),Jin WANG1,*(),Guo-dong LU1,Yoong-ho JUNG2
1. State Key Laboratory of Fluid Power and Mechatronic Systems, School of Mechanical Engineering, Zhejiang University, Hangzhou 310027, China
2. School of Mechanical Engineering, Pusan National University, Busan 46241, S. Korea
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Abstract  

A voxel-based method of recognizing and visualizing the potential water leakage gaps of automobile assembly was proposed for finding the water leakage problem during the new car model design phase. Based on the voxelization of the automobile assembly, the boundary voxels representing the position of water leakage were determined by defining the gap voxels among neighboring parts, reconstructing triangular meshed surfaces and extracting the boundary edges of parts. The gap distances were calculated and the gap surfaces were constructed based on the presented algorithm of mapping points generation. The errors from the boundary edges of gap surfaces to part surfaces were reduced by the self-adaptive subdivision method controlled by the chordal height error, and the gap surfaces were visualized by the color map. The method can be used to precisely identify all the potential positions of water leakage and visually display the gap sizes, which provides a possibility for quickly verifying the reasonability of water tightness design, and thus avoiding the reputational and financial losses caused by the emergence of congenital design defects. The method can also be applied to the design of large-scale and complex products in other industries such as aircraft, ship and chemical engineering.

Key wordsautomobile      water leakage      assembly      triangular mesh      voxel      gap      visualization     
Received: 12 June 2019      Published: 10 March 2020
CLC:  U 462.1  
  TP 391.4  
Corresponding Authors: Jin WANG     E-mail: jhf@zju.edu.cn;dwjcom@zju.edu.cn
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Jian-hui FU
Jin WANG
Guo-dong LU
Yoong-ho JUNG
Cite this article:

Jian-hui FU,Jin WANG,Guo-dong LU,Yoong-ho JUNG. Voxel-based recognition and visualization of water leakage gaps for automobile assembly. Journal of ZheJiang University (Engineering Science), 2020, 54(2): 357-364.

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http://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2020.02.017     OR     http://www.zjujournals.com/eng/Y2020/V54/I2/357


基于体素的汽车装配体漏水缝隙识别与可视化

为了在新车型设计阶段发现漏水问题,提出基于体素的汽车装配体潜在漏水缝隙的识别与可视化方法. 在汽车装配体模型体素化的基础上,通过定义相邻零件之间的缝隙体素,重构三角网格曲面并提取零件的边界边,以确定表达漏水部位的边界体素;基于所提出的映射点生成算法计算缝隙间距并构建缝隙曲面;通过由弦高误差控制的自适应细分方法降低缝隙曲面边界到零件曲面的误差,利用彩色云图进行可视化显示. 该方法能够精确识别汽车的全部潜在漏水部位,并可以直观显示漏水部位的缝隙大小,以快速验证水密性设计的合理性,避免出现先天设计缺陷而造成声誉与经济损失. 该方法还可以应用于航空航天、造船、化工等行业的大型复杂产品设计.


关键词: 汽车,  漏水,  装配体,  三角网格,  体素,  缝隙,  可视化 
Fig.1 Algorithm overview of gap recognition and visualization for assembly
Fig.2 Process of gap surface construction
Fig.3 Flow chart of gap surface construction
Fig.4 Categories of triangle intersecting with gap voxel
Fig.5 Reconstruction of triangular meshed surface
Fig.6 Definition of shortest point, link point and reflection point
Fig.7 Schematic diagram of mapping point generation algorithm
Fig.8 Flow chart of mapping point generation algorithm
Fig.9 Schematic diagram of gap surface error
Fig.10 Schematic diagram of gap surface subdivision process
Fig.11 Potential water leakage position recognition of cars
Fig.12 Gap surface generation and visualization
Fig.13 Comparison of gap surfaces before and after optimization
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