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A vibratory sensor for locating parts

Published online by Cambridge University Press:  09 March 2009

D. T. Pham
Affiliation:
Intelligent Systems Research Group, School of Electrical, Electronic and Systems Engineering, University of Wales, Cardiff, CF1 3YH (UK).
M. W. M. G. Dissanayake
Affiliation:
Department of Mechanical Engineering, University of Sydney, NSW 2006, (Australia).

Summary

A vibratory sensor capable of locating parts by measuring their inertial properties is described in this paper. The sensor is designed to be fitted to the wrist of a robot and used to acquire parts from a stack or a tray. The initial coordinates of the parts need only be approximately known (say to ±25 mm and ±45°). The robot is thus said to operate in a “semi-ordered” environment which can be realised inexpensively as accurate pallets, fixtures or other parts presentation equipment are not required. Furthermore, the absence of complete disorder, as would exist with a “bin-picking” approach where parts are allowed to lie at random in a bin, reduces the degree of sophistication demanded of the sensor system. Consequently, the cost of the latter can also be kept low.

The proposed sensor has a circular platform mounted on the shaft of a motor such that the shaft is normal to the platform. The part whose location is to be determined is held on the platform by magnetic or other means. The assembly consisting of the part, platform and motor is constrained to vibrate about an axis parallel to the platform. Two methods for computing the location of the part relative to the platform are described. Both methods require the natural frequencies of vibration of the part-platform-motor assembly for various angular positions of the platform. A simulation study to examine the effect of various design and operational parameters (inertias of the platform and part, stiffness of the spring restraining the movements of the vibrating assembly, location of part on platform, accuracy of frequency measurements) on the accuracy of the location computed is presented. The simulation results clearly demonstrate the feasibility of the sensor.

Type
Article
Copyright
Copyright © Cambridge University Press 1992

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References

1.Pham, D.T. and Dissanayake, M.W.M.G., “Feasibility study of a vibratory sensor for locating 3-D objects”, Proc. 25th Int. MTDR Conf.,Birmingham (1985) pp. 201211.Google Scholar
2.Pham, D.T. and Dissanayake, M.W.M.G., “A three-degree-of-freedom inertial sensor for locating partsProc. 15th Int. Symp. Ind. Rob.,Tokyo (1985) pp. 613629.Google Scholar
3.Pham, D.T. and Dissanayake, M.W.M.G., “Inertia-based methods for locating 3-D objectsProc. 5th Int. Conf. on Robot Vision and Sensory Control,Amsterdam (1985) pp. 223237.Google Scholar
4.Pham, D.T. and Menéndez, J., “A vibratory device for locating objects: theory and experimental resultsProc. Int. Conf. on Computer-Aided Design, Manufacture and Operations in the Automotive Industries,Geneva (1987) pp. 121137.Google Scholar
5.Pham, D.T. and Menéndez, J., “A six-degree-of-freedom inertial sensor for locating partsProc. 7th World Congress on the Theory of Machines and Mechanisms,Seville (1987) pp. 929934.Google Scholar
6.Pham, D.T. and Menéndez, J., “Development of a six-degree-of-freedom vibratory device for locating objectsInt. J. Mach. Tools and Manufacture 28, No. 3, 197205 (1988).CrossRefGoogle Scholar
7.Pham, D.T., Hu, H.S. and Pote, J., “A transputer-based system for locating parts and controlling an industrial robotRobotica 8, part 2, 97103 (1990).CrossRefGoogle Scholar
8.Kelley, R., Birk, J., Duncan, D., Martins, H. and Tella, R., “A robot system which feeds work pieces from bins to machines” Proc. 9th Int Symp. Ind. Rob., Washington DC (1979) pp. 339355.Google Scholar
9.Pugh, A. (ed.), Robot Sensors, Vols 1 and 2 (IFS, Bedford and Springer-Verlag, Berlin 1986).Google Scholar
10.Ruocco, S.R., Robot Sensors and Transducers, (Open University Press, Milton Keynes, 1988).CrossRefGoogle Scholar
11.McCallion, H., Vibration of Linear Mechanical Systems (Longman, London, 1973).Google Scholar