Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-24T11:30:19.095Z Has data issue: false hasContentIssue false

Sensory integrated fabric ply separation

Published online by Cambridge University Press:  09 March 2009

G. J. Monkman
Affiliation:
Fachbereich Elektrotechnik, Fachhochschule Regensberg, Regensburg, Germany

Summary

A knowledge of the fabric material and its properties, mechanisms of prehension and an understanding of sensor and manipulator integration are essential for even the most basic of robotic textile handling tasks. This paper considers individually, and as a combination, the aspects of mechanical and electrical hardware, software and logistics necessary in making automated fabric ply separation and positioning possible.

Type
Articles
Copyright
Copyright © Cambridge University Press 1996

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1.Taylor, P.M. and Gunner, M.B., “Mechatronics in Garment Manufacture” Mechatronics Design in Textile Engineering, NATO ASI Conference. Side,Turkey(April, 1992) pp. 271289.CrossRefGoogle Scholar
2.Monkman, G.J., “Robot Grippers for use with Fibrous Materials” Int. J. Robotics Research, 14, No. 2, 144151 (1995).CrossRefGoogle Scholar
3.Vercraene, F. and Esquirol, P. “Analysis of a ply separation gripper” In: Sensory Robotics for the Handling of Limp Materials (Ed. Taylor, P.M.), NATO ASI Series F (Springer-Verlag, Berlin, 1990) 64, pp. 127136.CrossRefGoogle Scholar
4.Murray, J.M., “Single-Ply Pick-up Devices” AAMA Apparel Research J. 8798 (December, 1975).Google Scholar
5.Kemp, D.R., Taylor, P.M. and Taylor, G.E., “An adaptive sensory gripper for fabric handling” Proc. 4th IASTED Symp. on Robotics & Automation, Amsterdam (1984).Google Scholar
6.Monkman, G.J., “Electrostatic Techniques for Fabric Hanlding” MSc. Thesis (University of Hull, 1987).Google Scholar
7.Monkman, G.J., “Robot Grippers for Packaging” 23rd Int'l. Symp. on Industrial Robots,Barcelona(October, 1992) pp. 579583.Google Scholar
8. Hesse, S., Greifer Praxis (Vogel, Würzburg, 1991).Google Scholar
9.Clapp, T.G. and Buchanan, D.R., “Limp Materials Research at North Carolina State University” Sensory Robotics for the Handling of Limp Materials (Ed. Taylor, P.M.), NATO ASI Series (Springer-Verlag, Berlin, 1990) 64, pp. 6984.CrossRefGoogle Scholar
10.Seesselberg, H.A., “A Challenge to Develop Fully Automated Garment Manufacturing” Sensory Robotics for the Handling of Limp Materials (Ed. Taylor, P.M.) NATO ASI Series F (Springer-Verlag, Berlin, 1990) 64, pp. 5367.CrossRefGoogle Scholar
11.Hall, M.K., “Feeding and Handling Aspects of an Automated System for Garment Manufacture” PhD Thesis (Leicester Polytechnic, 1989).Google Scholar
12.Monkman, G.J. and Shimmin, C., “Use of Permanently Pressure-sensitive Chemical Adhesives in Robot Gripping Devices” Int. J. Clothing Science & Technology, 3, No. 2, 622 (1991).CrossRefGoogle Scholar
13.Sutz, R.K., “Cryogenic Pick-up” U.S. Patent number 3611744 (1971).Google Scholar
14.Shultz, G., “Grippers for Flexible Textiles” 5th International Conf. on Advanced Robotics, IEEE,Pisa(June 1991) pp. 759764.CrossRefGoogle Scholar
15.Monkman, G.J., Taylor, P.M. and Farnworth, G.J., “Principles of Electroadhesion in Clothing Technology” Int. J. Clothing Science and Technology 1, No. 3, 1420 (1989).CrossRefGoogle Scholar
16.Banks-Lee, P., Barker, R.L., Clapp, T.G., Eischen, J.W., Gosh, T.K., Gupta, B.S., Hamouda, H., Little, T.J. and Buchanan, D.R., “The Interaction of Anisotropic Fabrics with Textile and Apparel Processes” 5th International Conf. on Advanced Robotics, IEEE,Pisa(June, 1991) pp. 781785.CrossRefGoogle Scholar
17.Gini, M., “The Future of Robot Programming” Robotica, 5, Part 3, 235246 (1987).CrossRefGoogle Scholar
18.Monkman, G.J., “Sensor Fusion in Robot Programming” IEE Colloquium on Principles and Applications of Data Fusion (February, 1991).Google Scholar
19.Monkman, G.J., “Robotic Workcell Analysis and Object Level Programming” PhD Thesis (University of Hull, 1990).Google Scholar
20.Gilbert, J.M., Taylor, P.M., Monkman, G.J. and Gunner, M.B., “Sensing in Garment Assembly” Mechatronics Design in Textile Engineering, NATO ASI Conference, Side,Turkey(April, 1992) pp. 291308.CrossRefGoogle Scholar
21. National Semiconductor, Data Conversion/Acquisition Data Book (National Semiconductor, 1980).Google Scholar
22.Taylor, P.M. and Bowden, P., “The use of multiple low cost vision sensors in fabric pick and place tasks” Proc. IFAC symp. on low cost automation,Valencia(1986) pp. 8995.Google Scholar
23.Norton-Wayne, L., “Automated garment inspection using machine vision” Proc. IEEE Int. Conf. on Systems Engineering,Pittsburg(1990) pp. 37483770.Google Scholar
24.Kelley, R.B., “Research on the Automated Handling of Garments for Pressing” 5th International Conf. on Advanced Robotics, IEEE,Pisa(June, 1991) pp. 796801.CrossRefGoogle Scholar
25.Blume, C. and Jacob, W., Programming Languages for Industrial Robots (Springer, Berlin, 1986).CrossRefGoogle Scholar
26.Gibson, I., Monkman, G.J., Palmer, G.S. and Taylor, P.M., “Adaptable Grippers for Garment Assembly” Proc. 22nd Intl. Symp. on Industrial Robots,Detroit(October, 1991) pp. 2/17–2/30.Google Scholar
27.Goldberg, K.Y., “Orienting polygonal parts without sensing” Algorithmica 10(2/3/4), 201225 (08, 09, 10, 1993).CrossRefGoogle Scholar