Reconfigurable manufacturing system
A reconfigurable manufacturing system (RMS) is a system invented in 1998 that is designed for the outset of rapid change in its structure, as well as its hardware and software components, in order to quickly adjust its production capacity and functionality within a part family in response to sudden market changes or intrinsic system change.[1][2] A reconfigurable machine can have its features and parts machined.[3]
History
[edit]The RMS, as well as one of its components—the reconfigurable machine tool (RMT)—were invented in 1998 in the Engineering Research Center for Reconfigurable Manufacturing Systems (ERC/RMS) at the University of Michigan College of Engineering.[4][5][6] The term reconfigurability in manufacturing was likely coined by Kusiak and Lee.[7]
From 1996 to 2007, Yoram Koren received an NSF grant of $32.5 million to develop the RMS science base and its software and hardware tools.[8] RMS technology is based on an approach that consists of key elements, the compilation of which is called the RMS science base.
System operations
[edit]The system is composed of stages: 10, 20, 30, etc. Each stage consists of identical machines, such as CNC milling machines. The system produces one product. The manufactured product moves on the horizontal conveyor. Then Gantry-10 grips the product and brings it to one of CNC-10. When CNC-10 finishes the processing, Gantry-10 moves it back to the conveyor. The conveyor moves the product to Gantry-20, which grips the product and loads it on the RMT-20, and so on. Inspection machines are placed at several stages and at the end of the manufacturing system.
The product may move during its production in many production paths. In practice, there are small variations in the precision of identical machines, which create accumulated errors in the manufactured product; each path has its own "stream-of-variations" (a term coined by Y. Koren).[9][10]
Characteristics
[edit]Ideal reconfigurable manufacturing systems, according to professor Yoram Koren in 1995, possess six characteristics: modularity, integrability, customized flexibility, scalability, convertibility, and diagnosability.[5][11] Characteristics for its components are: reconfigurable machines, controllers, and system control software. An RMS does not necessarily have all of the charateristics.[12] These principles are called Koren's RMS principles. Supposedly, the more of these principles applicable to a given manufacturing system, the more reconfigurable that system is. The RMS principles are:
The components of RMS are CNC machines,[13] reconfigurable tools,[5][11] reconfigurable inspection machines,[14] and material transport systems (such as gantries and conveyors) that connect the machines to form the system. Different arrangements and configurations of these machines will affect the system's productivity.[15] A collection of mathematical tools, which are defined as the RMS science base, may be used to maximize system productivity with the smallest possible number of machines.
See also
[edit]References
[edit]- ^ Koren, Y., Jovane, F., Heisel, U., Moriwaki,, T., Pritschow G., Ulsoy G., and VanBrussel H.: Reconfigurable Manufacturing Systems. A Keynote paper. CIRP Annals, Vol. 48, No. 2, pp. 6–12, November 1999.
- ^ Michigan Engineering | About our ERC
- ^ Moon, YM and Kota, S.: Design of reconfigurable machine tools. Journal of Manufacturing Science and Engineering, Trans of the ASME, 124:22, pp. 480–483, May 2002.
- ^ Koren Y. and Kota, S.: Reconfigurable Machine Tool. US patent US 5943750; issue date: 8/31/1999.
- ^ a b c "Creating the new manufacturing paradigm exactly the functionality and capacity needed, exactly when needed". Engineering Research Center for Reconfigurable Machining Systems. Retrieved September 22, 2024.
- ^ Koren, Y. and Ulsoy, G,: Reconfigurable Manufacturing System Having a Method for Changing its Production Capacity. US patent # 6,349,237; issue date: 2/19/2002.
- ^ Kusiak, A. and Lee, G.H., Design of Components and Manufacturing Systems for Reconfigurability, Proceedings of the First World Conference on Integrated Design and Process Technology, Austin, TX, pp. 14–20, December 1995.
- ^ NSF Grant: Engineering Research Center for Reconfigurable Machining Systems
- ^ Jianjun Shi, J. Stream of Variation Modeling and Analysis for Multistage Manufacturing Processes. CRC Press, Taylor & Francis Group, 2006. ISBN 0-8493-2151-4.
- ^ Hu,, S. J. and Koren Y.: Stream of Variation Theory for Automotive Body Assembly. Annals of the CIRP, Vol. 46/1, pp.1–6. 1997.
- ^ a b Landers, R., Min, B.K., and Koren, Y.: Reconfigurable Machine Tools. CIRP Annals, Vol. 49, No. 1, pp. 269–274, July 2001.
- ^ Mehrabi, M. Ulsoy, G. and Koren Y.: Reconfigurable Manufacturing Systems: Key to Future Manufacturing. Journal of Intelligent Manufacturing, Vol. 11, No. 4, pp. 403–419, August 2000.
- ^ Koren, Y.: Computer Control of Manufacturing Systems. McGraw-Hill Book Co., New York, 1983. ISBN 0-07-035341-7
- ^ Koren, Y. and Katz, R.: Reconfigurable Apparatus for Inspection During a Manufacturing Process. US patent # 6,567,162 Issue date: 5/20/03.
- ^ Koren, Y., Hu J., and Weber T.: Impact of Manufacturing System Configuration on Performance. CIRP Annals, Vol. 1, pp. 689–698, August 1998.