基于特征约束关系的航天器大部件装配机器人机型设计方法及应用

doi:10.3901/JME.2023.16.233

机械工程学报 ›› 2023, Vol. 59 ›› Issue (16): 233-242.doi: 10.3901/JME.2023.16.233

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基于特征约束关系的航天器大部件装配机器人机型设计方法及应用

蔡大军^1,2, 姚建涛^1,3, 高炜骅¹, 易旺民⁴, 赵永生^1,3

1. 燕山大学河北省并联机器人与机电系统实验室秦皇岛 066004;
2. 燕山大学工程训练中心秦皇岛 066004;
3. 燕山大学先进锻压成形技术与科学教育部重点实验室秦皇岛 066004;
4. 北京卫星环境工程研究所北京 100094

收稿日期:2022-09-02 修回日期:2023-02-08 出版日期:2023-08-20 发布日期:2023-11-15
通讯作者: 姚建涛(通信作者),男,1980年出生,博士,教授,博士研究生导师。主要研究方向为仿生软体机器人前沿理论、机器人力感知与触觉技术、并联机器人理论及应用。E-mail:jtyao@ysu.edu.cn
作者简介:蔡大军,男,1989年出生,博士。主要研究方向为并联机构理论和机器人技术。E-mail:caidajun@ysu.edu.cn
基金资助:
国家自然科学基金资助项目(U2037202)。

Type Design Method and Application for Spacecraft Large Component Assembly Robot Based on Features Constraint Relationship

CAI Dajun^1,2, YAO Jiantao^1,3, GAO Weihua¹, YI Wangmin⁴, ZHAO Yongsheng^1,3

1. Parallel Robot and Mechatronic System Laboratory of Hebei Province, Yanshan University, Qinhuangdao 066004;
2. Engineering Training Center of Yanshan University, Qinhuangdao 066004;
3. Key Laboratory of Advanced Forging & Stamping Technology and Science, Ministry of Education of China, Yanshan University, Qinhuangdao 066004;
4. Beijing Institute of Spacecraft Environment Engineering, Beijing 100094

Received:2022-09-02 Revised:2023-02-08 Online:2023-08-20 Published:2023-11-15

摘要/Abstract

摘要： 面向狭长任务空间航天器大部件装配的定位调姿需求，提出一种装配机器人机型设计方法。该方法以大型构件装配对接过程中存在的主要特征为和空间约束为主要参考，结合空间自由曲面几何理论，总结装配过程中存在的多种典型特征，基于装配特征对应的数学描述，建立装配几何特征到机器人运动维度的映射关系；定义装配过程中轨迹规划涉及到的多种空间、位姿状态的表示方法，明确轨迹规划中的各类约束相互关系，确定机器人运动的边界范围。以典型作业环境空间站工作舱为例，研发基于PPRRPR构型的航天装配机器人。从机构构态和运动特征两个方面，结合串/并联机构的优势以及在对应约束空间下的行为特性，进一步提出基于机构行为特征的机器人优化设计方法，建立混联装配机器人的概念模型，为特定任务环境下装配及搬运大型装备的机构设计提供了一定的参考。

关键词: 装配特征, 空间约束, 行为特征, 机型设计, 混联

Abstract: A design method for the robot is proposed, which can localize and adjust poses to assemble large spacecraft components in long and narrow operation space. Considering the main features and spatial constraints in large components assembly and docking,and by combining geometric theories of spatial free-form surfaces, a variety of typical features existing in the assembly process is summarized. Based on the mathematical description of assembly features, mapping relations from the assembly geometric features to the robot motion dimensions are obtained. The methods for representing the multiple spaces and pose states involved in trajectory planning during assembly process are defined. The relations of constraints of different types in trajectory planning are analyzed and the motion boundaries of the robot are determined. Taking the example of the typical assembly applied in the working cabin of space stations, an aerospace assembly robot based on PPRRPR configuration is developed. Furthermore, considering mechanism state and motion characteristics, and combining the advantages of series/parallel mechanisms and the behavior characteristics under corresponding constraint space, a robot optimization method based on the mechanism behavioral characteristics is proposed, and the conceptual model for the hybrid assembly robots is also established, which provides ideas for designing mechanisms of assembly and handling robots used for large equipment in specific working environment.

Key words: assembly features, space constraints, behavioral characteristics, type design, hybrid

中图分类号:

TH161

蔡大军, 姚建涛, 高炜骅, 易旺民, 赵永生. 基于特征约束关系的航天器大部件装配机器人机型设计方法及应用[J]. 机械工程学报, 2023, 59(16): 233-242.

CAI Dajun, YAO Jiantao, GAO Weihua, YI Wangmin, ZHAO Yongsheng. Type Design Method and Application for Spacecraft Large Component Assembly Robot Based on Features Constraint Relationship[J]. Journal of Mechanical Engineering, 2023, 59(16): 233-242.

参考文献

[1] 常家辉,祁萌,李良琦. 装配机器人在国外国防领域的应用进展[J]. 国防制造技术, 2018(4):10-19. CHANG Jiahui, QI Meng, LI Liangqi. Application progress of assembly robot in foreign national defense field[J]. Defense Manufacturing Technology, 2018(4):10-19.
[2] SCHWAKE K, WULFS J. Robot-based system for handing of aircraft shell parts[J]. Procedia CIRP, 2014, 23:104-109.
[3] 张学赛. 装配机械臂和末端执行机构的三维设计与分析[D]. 哈尔滨:哈尔滨工业大学, 2011. ZHANG Xuesai. Three-dimensional design and analysis of assembly arm and end actuator mechanism[D]. Harbin:Harbin Institute of Technology, 2011.
[4] CHU A M, CHI H L, PACKIANATHER M, et al. Novel robot arm design and implementation for hot forging press automation[J]. International Journal of Production Research, 2019, 57(14):4579-4593.
[5] CHU A M, CONG D N, VU M H, et al. Kinematic and dynamic modelling for a class of hybrid robots composed of local closed-loop linkages appended to an n-link serial manipulator[J]. Applied Sciences, 2020, 10(7):1-19.
[6] 邱铁成,张满,张立伟,等. 机器人在卫星舱板装配中的应用研究[J]. 航天器环境工程, 2012, 29(5):579-585. QIU Tiecheng, ZHANG Man, ZHANG Liwei, et al. The sate- llite board assembly with robot[J]. Spacecraft Environment Engineering, 2012, 29(5):579-585.
[7] 邱宝贵,蒋君侠,毕运波,等. 大型飞机机身调姿与对接试验系统[J]. 航空学报, 2011, 32(5):908-919. QIU Baogui, JIANG Junxia, BI Yunbo, et al. Poster alignment and joining test system for large aircraft fuselages[J]. Acta Aeronautica et Astronautica Sinica, 2011, 32(5):908-919.
[8] ZHU Yongguo, Huang Xiang, Li Shuanggao. A novel six degrees-of-freedom parallel manipulator for aircraft fuselage assemble and its trajectory planning[J]. Journal of the Chinese Institute of Engineers, 2015, 38(7):928-937.
[9] CHONG Zenghui, XIE Fugui, LIU Xinjun, et al. Design of the parallel mechanism for a hybrid mobile robot in wind turbine blades polishing[J]. Robotics and Computer-Integrated Manufacturing, 2020(61):1-9.
[10] SUN Tao, SONG Yimin, DONG Gang, et al. Optimal design of a parallel mechanism with three rotational degrees of freedom[J]. Robotics and Computer-Integrated Manufacturing, 2012, 28(4):500-508.
[11] 潘国威,陈文亮,王珉. 应用于飞机装配的并联机构技术发展综述[J]. 航空学报, 2018, 40(1):1-17. PAN Guowei, CHEN Wenliang, WANG Min. A review of parallel kinematic mechanism technology for aircraft assembly[J]. Acta Aeronautica et Astronautica Sinica,航空学报, 2018, 40(1):1-17.
[12] 谢福贵,梅斌,刘辛军,等. 一种大型复杂构件加工新模式及新装备探讨[J]. 机械工程学报, 2020, 56(19):83-91. XIE Fugui, MEI Bin, LIU Xinjun, et al. Novel mode and equipment for machining large complex components[J]. Journal of Mechanical Engineering, 2020, 56(19):83-91.
[13] 熊晶. 高速列车车厢总成装配路径规划方法研究[D]. 武汉:华中科技大学, 2016. XIONG Jing. Research on methods of assembly path planning for high-speed train carriages[D]. Wuhan:Huazhong University of Science and Technology, 2016.
[14] 邹东文. 装配特征识别技术在半挂车快速装配系统中的应用研究[D]. 太原:太原理工大学, 2015. ZOU Dongwen. Study on the application of assembly feature recognition in semi-trailer rapid assembly system[D]. Taiyuan:Taiyuan University of Technology, 2015.
[15] 刘密,刘检华,何永熹,等. 复杂结构条件下的装配路径求解与优化技术[J]. 机械工程学报, 2013, 49(9):97-105. LIU Mi, LIU Jianhua, HE Yongxi, et al. Research on assembly path planning and optimization of complex structures[J]. Journal of Mechanical Engineering, 2013, 49(9):97-105.
[16] 王皓,陈根良,黄顺舟,等. 面向最优匹配位置的大部件自动对接装配综合评价指标[J]. 机械工程学报, 2017, 53(23):137-146. WANG Hao, CHEN Genliang, HUANG Shunzhou, et al. Evaluation index framework of optimal matching position for large components automatic assembly[J]. Journal of Mechanical Engineering, 2017, 53(23):137-146.
[17] 沈惠平,赵海彬,邓嘉鸣,等. 基于自由度分配和方位特征集的混联机器人机型设计方法及应用[J]. 机械工程学报, 2011, 47(23):60-68. SHEN Huiping, ZHAO Haibin, DENG Jiaming, et al. Type design method and the application for hybrid robot based on freedom distribution and position and orientation characteristic set[J]. Journal of Mechanical Engineering, 2011, 47(23):60-68.
[18] 陈志军. 并联六足机器人的行为表达与规划研究[D]. 上海:上海交通大学, 2019. CHEN Zhijun. Behavior expression and planning of six-parallel-legged robots[D]. Shanghai:Shanghai Jiao Tong University, 2019.

基于特征约束关系的航天器大部件装配机器人机型设计方法及应用

Type Design Method and Application for Spacecraft Large Component Assembly Robot Based on Features Constraint Relationship

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