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工程设计学报
工程设计学报  2025, Vol. 32 Issue (5): 634-645    DOI: 10.3785/j.issn.1006-754X.2025.05.107
机器人与机构设计     
一种可变径多模式移动并联机器人的设计与分析
刘玉航(),张春燕(),田正雨,刘正阳
上海工程技术大学 机械与汽车工程学院,上海 201600
Design and analysis of a variable-diameter multi-mode mobile parallel robot
Yuhang LIU(),Chunyan ZHANG(),Zhengyu TIAN,Zhengyang LIU
School of Mechanical and Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201600, China
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摘要:

针对复杂非结构化环境下移动机器人的折展能力与多模式适应性不足的问题,提出了一种由可变径平台和4-URU并联机构组成的可变径多模式移动并联机器人。首先,基于凸轮机构的特性设计了由多根径向伸缩杆组成的可变径平台,并分析了其结构与受力特性。然后,结合可变径平台的伸缩特性,以4-URU并联机构为主体构建了多模式移动并联机器人,并基于螺旋理论对4-URU并联机构的自由度进行了分析,得到了不同运动模式下的自由度及切换方法。在此基础上,采用ZMP(zero moment point,零力矩点)理论对机器人在各模式下的稳定性进行了评估。最后,通过ADAMS仿真和样机实验验证了机器人在窄缝穿越、单环滚动及双轮越障等模式下的越障性能与稳定性。结果表明,所设计的移动并联机器人兼具良好的折展能力与多模式适应性,可为复杂环境下多功能移动机器人的设计与应用提供新思路。
关键词: 折展能力多模式移动并联机器人ADAMS仿真    
Abstract:

Aiming at the problem of insufficient folding and unfolding ability and multi-mode adaptability of mobile robots in complex unstructured environments, a variable-diameter multi-mode mobile parallel robot composed of a variable-diameter platform and a 4-URU parallel mechanism is proposed. Firstly, a variable-diameter platform with multiple radial telescopic rods was designed based on the cam mechanism characteristics, and its structure and force characteristics were analyzed. Then, combining the telescopic characteristics of the variable-diameter platform, a multi-mode mobile parallel robot was constructed with the 4-URU parallel mechanism as the main body. The degrees of freedom of the 4-URU parallel mechanism were analyzed by spiral theory, and the degrees of freedom and switching methods under different motion modes were obtained. On this basis, the ZMP (zero moment point) theory was used to evaluate the stability of the robot in various modes. Finally, the obstacle-crossing performance and stability of the robot in narrow-slit crossing, single-loop rolling and dual-wheel obstacle crossing modes were verified through ADAMS simulation and prototype experiments. The results show that the designed mobile parallel robot has good folding and unfolding ability and multi-mode adaptability, which can provide a new solution for the design and application of multi-functional mobile robots in complex environments.
Key words: folding and unfolding ability    multi-mode    mobile parallel robot    ADAMS simulation
收稿日期: 2025-01-17 出版日期: 2025-10-31
CLC:  TH 112  
基金资助: 国家重点研发计划“工业软件”重点专项(SQ2024YFB3300124)
通讯作者: 张春燕     E-mail: qcsjlyh@163.com;cyzhang@sues.edu.cn
作者简介: 刘玉航(1997—),男,硕士生,从事机器人机构学研究,E-mail: qcsjlyh@163.com
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引用本文:

刘玉航,张春燕,田正雨,刘正阳. 一种可变径多模式移动并联机器人的设计与分析[J]. 工程设计学报, 2025, 32(5): 634-645.

Yuhang LIU,Chunyan ZHANG,Zhengyu TIAN,Zhengyang LIU. Design and analysis of a variable-diameter multi-mode mobile parallel robot[J]. Chinese Journal of Engineering Design, 2025, 32(5): 634-645.

链接本文:

https://www.zjujournals.com/gcsjxb/CN/10.3785/j.issn.1006-754X.2025.05.107        https://www.zjujournals.com/gcsjxb/CN/Y2025/V32/I5/634

图1  可变径平台示意图
图2  2种空间内不同数量伸缩杆的受力情况
图3  可变径平台局部放大示意图
图4  伸缩杆运动轨迹变化
图5  可变径多模式移动并联机器人
图6  机器人多模式切换示意图
图7  4-URU并联机构简图
图8  URU支链螺旋分析
运动模式运动螺旋约束螺旋自由度运动性质
窄缝穿越模式$11=001;000$12=100;000$13=100;0e3f3$14=100;0e4f4$15=001;d5e50$1r=000;100$2r=000;0104沿XYZ轴的移动和绕Z轴的转动
单环滚动模式$11=100;000$12=100;0b2c2$13=100;0b3c3$14=100;000$1r=100;000$2r=000;010$3r=000;0013沿X轴的移动和绕YZ轴的转动
双轮越障模式1X轴转动
表1  不同模式下4-URU并联机构的自由度
图9  可变径平台折展原理
图10  URU支链折展原理
图11  机器人在收拢与展开状态下的体积包络示意图
图12  机器人体折展比变化曲线
图13  机器人的窄缝穿越步态
图14  单环滚动模式运动学模型
图15  机器人的单环滚动步态
图16  机器人的双轮越障步态
图17  机器人驱动电机分布图
运动模式窄缝穿越模式单环滚动模式双轮越障模式
电机状态
表2  不同模式下的驱动电机状态
图18  不同模式下机器人质心的运动趋向
图19  单环滚动模式下机器人质心的投影
参数数值
接触刚度/(N/mm)10 000
静摩擦因数0.4
动摩擦因数0.3
碰撞力指数1.5
最大穿透深度/mm0.1
表3  环境相关参数
图20  机器人窄缝穿越仿真结果
图21  窄缝穿越模式下机器人上平台质心的位移曲线
图22  机器人单环滚动仿真结果
图23  单环滚动模式下机器人质心位移曲线
图24  机器人双轮越障仿真结果
图25  双轮越障模式下机器人质心位移曲线
图26  机器人样机
参数属性和数值
整机尺寸/(mm×mm×mm)200×200×450
整机质量/kg2.35
材料PLA、铝合金、不锈钢
工作电压/V3.3(伺服舵机)、8(减速电机)
表4  机器人样机的基本参数
图27  机器人控制系统框图
图28  机器人窄缝穿越模式实验
图29  机器人单环滚动模式实验
图30  机器人双轮越障模式实验
  
  
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