Generation Method of Dimension Correlation Change Propagation Paths

doi:10.3969/j.issn.1004-132X.2021.13.003

Abstract

Abstract: From the view point of dimension change propagation among parts and parts related dimensions， a searching method of dimension change propagation paths was discussed based on correlation. The dimension correlation model for change propagation was established to describe the hierarchical and logical relationship between dimension characteristics. By using matrix operation method， the correlation change propagation network with parts as nodes was established based on dimension correlation. The dimension change propagation coefficient was used as the evaluation index to optimize the paths. The set value matrix， intermediate transformation matrix and vector value matrix were established for representing the correlation between the dimension parameters of the changed parts and the affected parts. By using the inner product operation， the correlation mapping relationship between the changed dimensions and the dimension parameters of the affected parts was established， and the propagating processes and paths of changed dimension in products were determined. Finally， an example for size change in propagation processes of paper printing and laminating machine was given to verify the effectiveness of the proposed method.

Key words: dimension correlation, change propagation path, dimension logic unit, change propagation coefficient

摘要： 从更改尺寸在零件间以及零件相关尺寸间传播的角度，探讨了基于关联的尺寸更改传播路径搜索方法。建立了尺寸关联更改传播模型，用以描述尺寸特性间的逻辑与层次关系；运用矩阵运算方法，基于零件间的尺寸关联，建立了以零件为节点的关联更改传播网络，将尺寸更改传播系数作为路径评价指标对路径进行了优选；建立了表征更改零件的尺寸参数与被影响零件之间关联的集值矩阵、中间转换矩阵及向量值矩阵;采用内积运算方法，建立了更改尺寸与被影响零件尺寸参数间的关联映射关系，确定了更改尺寸在产品中的传递过程与路径；最后，以尺寸更改在印纸覆膜机中的传播过程为例验证了本方法的有效性。

关键词: 尺寸关联, 更改传播路径, 尺寸逻辑元, 更改传播系数

CLC Number:

TP391

YANG Bo, SHANG Junzhi, MA NingGAO Changqing. Generation Method of Dimension Correlation Change Propagation Paths[J]. China Mechanical Engineering, 2021, 32(13): 1530-1538.

杨波, 尚俊芝, 马宁, 高常青. 尺寸关联更改传播路径生成方法[J]. 中国机械工程, 2021, 32(13): 1530-1538.

References

［1］JARRATT T， ECKERT C M， CALDWELL N， et al. Engineering Change：an Overview and Perspective on the Literature［J］. Research in Engineering Design， 2011， 22（2）：103-124.
［2］PASQUAL M C， WECK O. Multilayer Network Model for Analysis and Management of Change Propagation［J］. Research in Engineering Design， 2012， 23（4）：305-328.
［3］唐家鹏，席平，张德宇. 飞机翼面结构自顶向下关联设计［J］. 中国机械工程， 2015， 26（20）：22-26.
TANG Jiapeng， XI Ping， ZHANG Deyu. Top-down Associated Design of Aircraft Wing Structure［J］. China Mechanical Engineering， 2015， 26（20）：22-26.
［4］陈陌，杜纲，支华炜. 基于模块属性组合的产品族主从关联设计［J］. 中国机械工程， 2015， 26（1）：25-31.
CHEN Mo，DU Gang， ZHI Huawei. Leader-follower Joint Design of Product Family Based on Module Attribute Combination［J］. China Mechanical Engineering， 2015， 26（1）：25-31.
［5］程贤福，万冲，邱浩洋，等.模块化产品设计中模块间的关联分析与解耦策略［J］. 计算机集成制造系统， 2020，26（4）：1043-1051.
CHENG Xianfu， WAN Chong， QIU Haoyang， et al. Association Analysis between Modules and Decoupling Strategies in Modular Product Design［J］. Computer Integrated Manufacturing System， 2020，26（4）：1043-1051.
［6］吕盛坪，乔立红. 工程变更信息模型构建和变更过程控制［J］. 中国机械工程， 2014， 25（11）：1486-1492.
LYU Shengping，QIAO Lihong. Model for Engineering Change Information and Control for Change Process［J］. China Mechanical Engineering， 2014， 25（11）：1486-1492.
［7］刘振宇，周思杭，谭建荣，等.基于多准则修正的产品性能多参数关联分析与预测方法［J］. 机械工程学报， 2013， 49（15）：105-114.
LIU Zhenyu， ZHOU Sihang， TAN Jianrong， et al. Multiple Parameters Correlation Analysis and Prediction Method of Product Performance Based on Multi-criteria Modification［J］. Journal of Mechanical Engineering， 2013， 49（15）：105-114.
［8］徐新胜，陶西柱，祝天荣. 基于多重选择目标规划的产品变型设计［J］.计算机集成制造系统， 2013，19（1）：343-349.
XU Xinsheng， TAO Xizhu， ZHU Tianrong， et al. Product Variant Design Based on Multiple Selection Target Planning［J］. Computer Integrated Manufacturing System， 2013， 19（1）：343-349.
［9］彭翔，刘振宇，谭建荣，等. 基于多重耦合聚类的复杂产品多变量关联设计模型分解［J］. 机械工程学报， 2013， 49（3）：111-121.
PENG Xiang， LIU Zhenyu， TAN Jianrong， et al. Decomposition of Multivariate Association Design Model for Complex Products Based on Multiple Coupled Clustering［J］. Journal of Mechanical Engineering， 2013， 49（3）：111-121.
［10］BAUDOUI V， KLOTZ P， HIRIART-URRUTY J B， et al. Local Uncertainty Processing （LOUP） Method for Multidisciplinary Robust Design Optimization［J］. Structural and Multidisciplinary Optimization， 2012，46（5）：711-726 .
［11］杨帆，唐晓青，段桂江. 基于特性关联网络模型的机械产品工程更改传播路径搜索方法［J］. 机械工程学报，2011，47（19）：97-105.
YANG Fan， TANG Xiaoqing， DUAN Guijiang. Mechanical Product Engineering Change Propagation Path Search Method Based on Characteristic Association Network Model［J］. Journal of Mechanical Engineering， 2011，47（19）：97-105.
［12］YANG F， DUAN G. Developing a Parameter Linkage-based Method for Searching Change Propagation Paths［J］. Research in Engineering Design， 2012， 23（4）：353-372.
［13］MA S， JIANG Z， LIU W. Evaluation of a Design Property Network-based Change Propagation Routing Approach for Mechanical Product Development［J］. Advanced Engineering Informatics， 2016， 30（4）：633-642.
［14］陈进平，张树生，何卫平，等. 基于驱动参数建模的可行更改路径搜索和优选方法［J］. 上海交通大学学报， 2017， 51（10）：1220-1227.
CHEN Jinping， ZHANG Shusheng， HE Weiping， et al. Feasible Change Path Search and Optimization Method Based on Drive Parameter Modeling［J］. Journal of Shanghai Jiao Tong University， 2017， 51（10）：1220-1227.
［15］刘彦臣，刘玉斌，石亦琨，等.产品关联设计及变更影响分析［J］.中北大学学报（自然科学版），2017，38（3）：282-290.
LIU Yanchen， LIU Yubin， SHI Yikun， et al. Product Association Design and Change Impact Analysis［J］. Journal of North University of China（Natural Science Edition）， 2017，38（3）：282-290.
［16］TANG D， YIN L. Using an Engineering Change Propagation Method to Support Aircraft Assembly Tooling Design［J］. Industrial Engineering and Management Innovation， 2016， 10：939-951.
［17］YIN L， TANG D， ULLAH I， et al. Analyzing Engineering Change of Aircraft Assembly Tooling Considering Both Duration and Resource Consumption［J］. Advanced Engineering Informatics， 2017， 33：44-59.
［18］宫中伟，莫蓉，杨海成，等. 基于矩阵的工程变更雪崩传播预测方法［J］. 计算机集成制造系统， 2012，18（12）：43-51.
GONG Zhongwei， MO Rong， YANG Haicheng， et al. Method for Forecasting Avalanche Propagation of Engineering Change［J］. Computer Integrated Manufacturing System， 2012，18（12）：43-51.
［19］CLARKSON P J， SIMONS C， ECKERT C. Predicting Change Propagation in Complex Design［J］. Journal of Mechanical Design， 2004， 126（5）：788-797.

[1]	REN Jiaqi, XU Sixiang, DONG Binhui, TANG Ao, SONG Yuchen. Binocular Vision Localization and Measurement Based on Lightweight HRNet [J]. China Mechanical Engineering, 2026, 37(1): 201-208.
[2]	YUAN Yuan, BAI Yichao, ZHOU Lidong, MENG Wenjun, WANG Miao, QU Wenbin. Conveyor Belt Damages Detection Based on Improved YOLOv8 Algorithm [J]. China Mechanical Engineering, 2025, 36(12): 2829-2836.
[3]	Mengjie HU, Yuhang FANG, Xujia QIN, Zhengqiang WU. Automatic Tooth Alignment Method Based on Mesh Features [J]. China Mechanical Engineering, 2025, 36(11): 2738-2746.
[4]	Hongchen WU, Xiaorong CHEN, Baiyang LI. Multi-threaded Semi-global Stereo Matching Method for Internal Inspection of Workpieces [J]. China Mechanical Engineering, 2025, 36(11): 2783-2791.
[5]	Weihao JIA, Peng WANG, Kai CHEN, Fei TONG, Guobiao WANG. Research on Rapid Single-exposure HDR Defect Recognition Algorithm for Highly Reflective Metal Surfaces [J]. China Mechanical Engineering, 2025, 36(09): 2039-2046.
[6]	Tao YANG, Fang JIANG. Research on Evaluations of Cloud Manufacturing Collaborative Service Entities Based on R-GRA [J]. China Mechanical Engineering, 2025, 36(09): 2097-2107.
[7]	Jun WANG, Guibing GAO. A Method for Detecting Surface Defects on Wind Turbine Blades Based on Improved YOLOv5s [J]. China Mechanical Engineering, 2025, 36(09): 2108-2116.
[8]	XU Linlong1, JI Xiaogang1, 2, LI Huabin1, JIANG Hao1. Research on Tensile Failure Behaviors of Skin Suture Interfaces with Fractal Interlock Design [J]. China Mechanical Engineering, 2025, 36(07): 1442-1452.
[9]	GU Sunquan, ZHANG Haizhu, LI Rong, RAO BaWANG Hao. Quantitative Analysis of Correlation for Complex Product Design Indicator Decomposition Based on Lotka-Volterra Model [J]. China Mechanical Engineering, 2025, 36(07): 1479-1486.
[10]	ZHAO Yunjie, HE Yansong, ZHANG Zhifei, XU Zhongming. 3D Beamforming Map Compression Method Based on Generative Model [J]. China Mechanical Engineering, 2025, 36(07): 1520-1529.
[11]	WEN Xiaoyu1, ZHANG Hao1, ZHANG Yuyan1, LIU Siren2, JI Shuo1, GUO Weifei1, LI Hao1. Optimization of Laser Tracker Positions in Aircraft Assembly Processes under Digital Twin Environments [J]. China Mechanical Engineering, 2025, 36(07): 1573-1581,1635.
[12]	SHI Zhiyuan1, 2, KONG Zhiwei2, CHEN Junzhen3, WANG Shuying3. Research on Construction Techniques for Wind Power Equipment Contextual Knowledge Graphs [J]. China Mechanical Engineering, 2025, 36(06): 1206-1213.
[13]	LI Tao, DENG Linhui, MO Bin, SHI Feifan, LIU Weiwei. Prediction of Cracks and Optimization of Processing Parameters in Laser Cladding of Ni60 Based on HGA-ACO-RFA [J]. China Mechanical Engineering, 2025, 36(06): 1322-1328,1337.
[14]	LIU Quanquan1, FANG Xifeng1, CHENG Dejun1, ZHANG Shengwen1, LUO Lanzhen2, KONG Junlong1. Research on Information Completeness Checking Technique of 3D Model for MBD [J]. China Mechanical Engineering, 2025, 36(05): 1035-1043.
[15]	LUO Liang1, 2, LANG Xiao1, ZU Guoqing2, ZHANG Nong1, YANG Lin3, SHEN Xiongwei4. A Cylinder Liner Defect Detection Method Based on Improved YOLOv8n [J]. China Mechanical Engineering, 2025, 36(05): 1054-1064.