Abstract
Industrial robots can be made compliant to the environment when the control loop gains are reduced, creating a so-called soft servo capability. This allows industrial robots to be used for assemblies with limited contact requirements. In this paper, we propose an assembly method using soft servo to perform certain assembly tasks where part location errors typically require the use of force control or remote center of compliance (RCC) methods. A typical industrial application, valve body assembly, was used to validate the developed method. This assembly was chosen because it is simple, yet requires compliance in all directions. Lab experiments were performed and the assembly operations were consistently successful enough to show that the developed soft servo strategy can perform certain assembly tasks with small part location errors. Therefore, the soft servo strategy may open a new door for low-cost industrial assembly. Experiments with force control were also performed to compare the performance between soft servo and force control. We found that the force control method is much more sensitive to environmental contact, that the contact forces can be controlled directly, and that greater part location errors can be tolerated. Conversely, assembly with soft servo may either fail to assemble the parts or generate bigger contact forces than allowed. Thus, applications of soft servo are more limited while force control can be successfully used in most all applications. Further investigation is needed to determine the practical industrial use of soft servo for particular types of precision assembly.
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References
Meyer F, Spröwitz A, Berthouze L (2006) Passive compliance for a RC servo-controlled bouncing robot. Advanced Robotics 20(8):953–961 (9)
Sturges RH, Laowattana S (1994) Passive assembly of non-axisymmetric rigid parts. Intelligent Robots and Systems '94, vol 2, pp 1218–1225, Munich, Germany
Xu Y, Paul RP (1990) A robot compliant wrist system for automated assembly. Proc IEEE Int Conf Robot Autom 3:1750–1755. doi:10.1109/ROBOT.1990.126262
Gottschlich SN, Kak AC (1989) A dynamic approach to high-precision parts mating. IEEE Trans Syst Man Cybern 19(4):797–810
Wapenhans H, Seyfferth W, Pfeiffer F (1993) Robotic force control for flexible assembly. IEEE International Conference on Robotics and Automation, vol 1, pp 225–231. Atlanta, GA, USA
Newman WS, Zhao Y, Pao Y-H (2001) Interpretation of force and moment signals for compliant peg-in-hole assembly. Proceedings of the IEEE International Conference on Robotics and Automation, 2001. ICRA, vol 1, pp 571–576
Gravel D, Newman WS (2001) Flexible robotic assembly efforts at ford motor company. The Proceedings of the 2001 IEEE International Symposium on Intelligent Control, pp 173–182
Zhang H, Gan Z, Brogardh T, Wang J, Isaksson M (2004) Robotics technology in automotive powertrain assembly. ABB Rev 1:13–16
Robotics application manual—force control for assembly. ABB Automation Technologies BA, Robotics, SE-721 68, Vasteras, Sweden
Chen H, Zhang G, Zhang H, Fuhlbrigge T (2007) Integrated robotic system for high precision assembly in a semi-structured environment. Assembly Autom 27(3):247–252. doi:10.1108/01445150710763277
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Chen, H., Wang, J., Zhang, G. et al. High-precision assembly automation based on robot compliance. Int J Adv Manuf Technol 45, 999–1006 (2009). https://doi.org/10.1007/s00170-009-2041-8
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DOI: https://doi.org/10.1007/s00170-009-2041-8