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�b��еĲ��f�{��w��a�е��Ҫì�ܺ��Ć��}��Qԓ��}�Ǳ��C�w��/�b��|��ǰ��ᘌ��һ��w��ĸ��OӋ��b��Ҫ��ϵ�y��B��w��ֻ��b��f�{��g��b��|��Ƽ��g�ĿƌW��Փ�c��̷��Ҫ��ڔ��օf�{ģ�͵��w��b�乤��aƷ�P�I�f�{��R�e��b�乤�bϵ�y��λ��ȵľ��ʱ��ϡ��b��`��Ă��f�c�f�{�`��ߴ�朵Ę��b��|��]�h��c��ɿ��ȃ��һ��Y��*��о��Mչ��Ծ��w��b��f�{�|��l�c��b�乤ˇ�c�f�{��g�M��ϵ�y�Ľ��һ��w��Ĺ�ˇ�^�̞��ģ��Փ�о��c��̬F��ľC�ϑ��x�߸��õ��w��b��f�{��g��Փ�� S��ɹ��պ��ƌW�c��g�W�ƵĽ̎��͌W��Լ��b��|��P�Ŀ��ˆT�c��̼��g�ˆT��ʹ�� Inconsistency in assembly is the main contradiction and central issue in aeronautical production, and resolving this inconsistency is a prerequisite for ensuring the quality of aeronautical manufacturing and assembly. Focusing on the high performance requirements for design and manufacturing and assembly, this book systematically introduces the scientific theory and engineering methods of full digital assembly coordination technology and assembly quality control technology. Specific content includes aircraft assembly work methods based on digital coordination models, quantitative identification of key coordination features for products, precise guarantees of positioning accuracy for flexible assembly tooling systems, transmission of assembly errors and construction of coordination error chains, closed-loop control of assembly quality and improvement of its reliability. On the one hand, based on the latest research progress and taking the specific assembly coordination quality control requirements as the starting point, a systematic review on assembly processes and coordination technologies is conducted. On the other hand, focusing on the manufacturing process of aeronautical products and strengthening the comprehensive application of theoretical research and practical engineering, readers will gain an understanding of the theoretical methods of aeronautical assembly coordination technology. For the assembly process design and assembly coordination assurance, this book provides a rich and in-depth introduction. It can be used as a reference for teachers and students in aerospace science and technology majors, as well as the researchers and engineering technicians related to assembly quality.

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For the new generation aeronautical products, their manufacturing and assembly quality affects the service performance even more directly. In assembly work, key quality indexes, such as profile flush, gap, the convex-concave value of the fastener joint’s head, have been enhanced nearly an order of magnitude compared to previous aviation type, namely, the assembly quality requirements have reached the sub-millimeter level. And the assembly coordination accuracy is generally even tighter than individual parts’ manufacturing errors. For example, �� the assembly steps between different skin panels along the flight direction are not permitted for modern aircraft, �� the gaps between different skin sections are smaller than the forming/manufacturing accuracy of the sheet parts, especially for the carbon fiber reinforced polymer (CFRP) parts with relatively low manufacturing accuracy. As a result, the assurance on assembly and coordination accuracy is of great concern to the design and manufacturing departments in the modern aviation industry.For the new generation aeronautical products, their manufacturing and assembly quality affects the service performance even more directly. In assembly work, key quality indexes, such as profile flush, gap, the convex-concave value of the fastener joint’s head, have been enhanced nearly an order of magnitude compared to previous aviation type, namely, the assembly quality requirements have reached the sub-millimeter level. And the assembly coordination accuracy is generally even tighter than individual parts’ manufacturing errors. For example, �� the assembly steps between different skin panels along the flight direction are not permitted for modern aircraft, �� the gaps between different skin sections are smaller than the forming/manufacturing accuracy of the sheet parts, especially for the carbon fiber reinforced polymer (CFRP) parts with relatively low manufacturing accuracy. As a result, the assurance on assembly and coordination accuracy is of great concern to the design and manufacturing departments in the modern aviation industry. As a key technology in aircraft manufacturing, assembly coordination technology is important for improving the competitiveness and manufacturing capabilities. The main topics of this book are as follows. �� The working mode based on digital coordination model (DCM), which provides an overall guiding line for digital assembly coordination theory. �� The assembly quality analysis and control technical system, which enhances accuracy reliability and ensures assembly accuracy within the required range, and lays a precision foundation for products’service performance. This book contains six chapters. Some content was published in the Journal of Manufacturing Systems, Composite Structures, Robotics and Computer-Integrated Manufacturing, Advanced Engineering Informatics, International Journal of Advanced Manufacturing Technology, Assembly Automation, IEEE Access, Proceedings of the Institution of Mechanical Engineers Part B-Journal of Engineering Manufacture, and others. This book could open a door for readers to gain a deeper understanding of the assembly process and quality control technology for aviation thinwalled components. This book could also serve as a reference for teachers and students majoring in aerospace manufacturing engineering, mechanical engineering, automotive engineering, and related fields, as well as researchers and engineering technicians. We express our special thanks for the support of the National Natural Science Foundation of China (52175450, 51805502), the National Defense Basic Scientific Research Foundation (JCKY 2023205B006), and the Aerospace Science Research Foundation (2017ZE25005). As a result of research, some content in this book may inevitably be incomplete, contain inappropriate expressions or biased opinions. We sincerely welcome feedback and corrections from experts and readers.

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Chapter 1 Introduction 001
1.1 Background and Research Requirements for Assembly Technology 001
1.2 Assembly Process Parameters Optimization 009
1.3 Assembly Error Transfer and Accumulation 020
1.4 Comprehensive Adjustment of Assembly Geometric Accuracy and Internal Stress 027
1.5 Virtual Assembly Simulation and Validation Tools and Methods 039
1.6 Structure of the Book 043
References 045

Chapter 2 Working Mode in Aeronautical Manufacturing Based on Digital Coordination Model 051
2.1 Introduction and Related Work 051
2.2 Coordination Accuracy Controlling Method 053
2.3 Principle of the Working Mode Based on Digital Coordination Model 055
2.4 Experimental Verification 071
2.5 Summary 079
References 080

Chapter 3 Comprehensive Identification of Coordination Features with Complete Importance Modeling 082
3.1 Introduction and Related Work 082
3.2 Hierarchical Decomposition of Coordination Features for Aeronautical Product 084
3.3 General Framework of the Comprehensive Identification of Coordination Features 087
3.4 Qualitative Identification of Coordination Features 089
3.5 Quantitative Identification of Coordination Features by Calculating Complete Importance 090
3.6 Experimental Verification 096
3.7 Summary 105
References 105

Chapter 4 Positioning Error Guarantee Modeling for Flexible Assembly Tooling 108
4.1 Introduction and Related Work. 108
4.2 Establishment of Assembly Measurement Field 113
4.3 Accurate Measurement of Actual Error Status and Assembly Conditions 114
4.4 Pre-compensation Stage Considering Actual Error Status and Mechanical Analysis. 117
4.5 Parameter Identification for Tooling and Locating Motion Model with Measured Sample Data 127
4.6 Accurate Compensation Stage Combining Mechanism Analysis and Measurement Data 136
4.7 Summary 141
References 142

Chapter 5 Assembly Error Propagation Modeling and Coordination Error Chain Construction for Aeronautical Structure 146
5.1 Introduction and Related Work. 146
5.2 Basic Error Sources Modeling in Assembly Process 150
5.3 Interaction Relationship among Different Basic Error Items 153
5.4 Error Modeling for Transformation Process of Coordination Datum 157
5.5 Coordination Error Chain Construction Based on Error Propagation Modeling 162
5.6 Experimental Verification 167
5.7 Summary 173
References 173

Chapter 6 Assembly Quality Control and Reliability improvement with Feedback Actions 176
6.1 Introduction and Related Work. 176
6.2 Probability Model of Assembly Error for Accuracy Reliability Evaluation 181
6.3 Probability Analysis and Precise Adjustment of Out-of-tolerance Event with LDP Method 187
6.4 Precise Optimization of Repair Quantity Based on Measured Data and IPSO Algorithm 195
6.5 SPC for Aeronautical Assembly Quality Control for Single Component 199
6.6 Assembly Station Flowing Fluctuation Analysis at Different Time Stages for Multiple Components 204
6.7 Experimental Verification: the First Case 207
6.8 Experimental Verification: the Second Case 217
6.9 Summary 225
References 226

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