Journal of Jilin University(Engineering and Technology Edition) ›› 2021, Vol. 51 ›› Issue (1): 370-378.doi: 10.13229/j.cnki.jdxbgxb20190838

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Global structural optimization design of collaborative robots using orthogonal design

Ming-wei HU1,2,3(),Hong-guang WANG1,2(),Xin-an PAN1,2   

  1. 1.State Key Laboratory of Robotics,Shenyang Institute of Automation,Chinese Academy of Sciences,Shenyang 110016,China
    2.Institutes for Robotics and Intelligent Manufacturing,Chinese Academy of Sciences,Shenyang 110169,China
    3.University of Chinese Academy of Sciences,Beijing 100049,China
  • Received:2019-08-24 Online:2021-01-01 Published:2021-01-20
  • Contact: Hong-guang WANG E-mail:mingweihu@yeah.net;hgwang@sia.cn

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Abstract:

To dispose of the influence of time-varying configurations and modeling accuracy on robot structural optimization, a Real-time Modal Analysis (RMA) method for collaborative robots was propose, which combines the finite element method and analytical method. This method could real-time obtain the natural frequencies and mode shapes of robots in any pose with high efficiency and precision. To reduce the calculating amount and realize global structure optimization, based on orthogonal design, a global structural optimization design method of collaborative robots was proposed with the structure parameters as optimization variables and the ratio of robot mass to the global first natural frequency index (M/GF) as optimization objective. The M/GF indexes of SHIR5 robot before and after optimization are calculated. The index after optimization is 9.90% higher than that before optimization, and the global first natural frequency index (GFNFI) is increased by 0.91Hz compared with that before optimization.

Key words: mechatronic engineering, orthogonal design, collaborative robots, natural frequency

CLC Number: 

  • TP241

Fig.1

SHIR5 collaborative robot and its modules"

Fig.2

Collaborative robots and its equivalent super-element model"

Fig.3

Flow chart of structural optimization design using orthogonal design"

Table 1

Influence factors and its level values"

水平T1T2T3T4T5T6T7T8T9T10T11L1L2
12.521.53.53.53.53.52.52.52.22.2223222
232.524444332.52.5203202
33.532.54.54.54.54.53.53.52.82.8183182

Table 2

L27(313) orthogonal array"

No.T1T2T3T4T5T6T7T8T9T10T11L1L2M/kgGFNFI/HzM/GF
1111111111111121.067.902.67
2111122222222221.628.212.63
3111133333333322.208.372.65
4122211122233321.417.892.71
5122222233311121.938.222.67
6122233311122221.848.262.64
7133311133322221.777.942.74
8133322211133321.678.012.71
9133333322211122.198.342.66
10212312313212321.737.972.73
11212323121323121.708.162.66
12212331232131221.858.232.65
13223112321331221.678.072.68
14223123132112321.758.332.61
15223131213223121.767.862.77
16231212332123121.788.232.64
17231223113231221.788.042.71
18231231221312321.728.182.66
19313213212313221.787.972.73
20313221323121321.938.082.72
21313232131232121.938.242.66
22321313223132121.898.182.68
23321321331213221.878.252.65
24321332112321321.878.042.72
25332113231221321.848.332.62
26332121312332121.867.882.77
27332132123113221.928.202.67
R0.140.090.270.110.110.370.040.540.380.290.190.100.06
Level71159831312461012
最优水平1111332311113
T0.320.111.090.180.202.310.036.772.421.343730.51200.1550.06
InfluenceNoNoNoNoNoNoNoYesNoNoNoNoNo
Significance level 方正汇总行α=0.1?????????Fα(r-1,n-r)=F0.1(2,24)=2.54

Fig.4

Trend chart of influence factors and its modules"

Table 3

Optimal levels of influence factors and optimization results"

T1T2T3T4T5T6T7T8T9T10T11L1L2M/kgGFNFI/HzM/GF
原始值332.54.53.53.53.52.53.52.82.818322221.607.652.82
优化值2.521.53.54.54.543.52.52.22.222318221.788.562.54

Fig.5

Comparison of global natural frequency index before and after optimization"

Fig.6

First order mode of vibration for poses P1-P5 of cobot SHIR5"

Fig.7

Physical prototype of SHIR5 collaborative robot"

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