Manufacturing systems need to be designed to cope with products’ variety and frequent changes in market requirements. Switching between product families in different production periods often requires reconfiguration of the manufacturing system with associated additional cost and interruption of production. A mixed integer linear programing (MILP) model is proposed to synthesize manufacturing systems based on the co-platforming methodology taking into consideration machine level changes including addition or removal of machine axes and changing setup as well as system level changes such as addition or removal of machines. The objective is to minimize the cost of change needed for transition between product families and production periods. An illustrative numerical example and an industrial case study from tier I automotive supplier are used for verification. Finally, the effect of maintaining a common core of machines in the manufacturing system on the total capital and change cost is investigated. It has been demonstrated that synthesizing manufacturing systems designed using the co-platforming strategy reduces the total investment cost including initial cost of machines and cost of reconfiguration.
Issue Section:
Design for Manufacture and the Life Cycle
References
1.
Simpson
, T. W.
, Jiao
, J. R.
, Siddique
, Z.
, and Hölttä-Otto
, K.
, 2014
, Advances in Product Family and Product Platform Design
, Springer
, New York
.2.
ElMaraghy
, H.
, and Abbas
, M.
, 2015
, “Products-Manufacturing Systems Co-Platforming
,” CIRP Ann. Manuf. Technol.
, 64
(1
), pp. 407
–410
.3.
Abbas
, M.
, and ElMaraghy
, H.
, 2016
, “Functional Synthesis of Manufacturing Systems Using Co-Platforming
,” Procedia CIRP
, 52
, pp. 102
–107
.4.
ASME
, 2004
, “Mathematical Definition of Dimensioning and Tolerancing Principles
,” American Society of Mechanical Engineers
, New York
, Standard No. Y14.5.1M-1994
.https://www.asme.org/products/codes-standards/y1451m-1994-mathematical-definition-dimensioning5.
Shah
, J. J.
, and Rogers
, M. T.
, 1988
, “Functional Requirements and Conceptual Design of the Feature-Based Modelling System
,” Comput. Aided Eng. J.
, 5
(1
), pp. 9
–15
.6.
ElMaraghy
, H.
, 1991
, Intelligent Product Design and Manufacture, Artificial Intelligence in Design
, Springer
, Berlin, pp. 147
–168
.7.
Bernardi
, A.
, Legleitner
, R.
, and Klauck
, C.
, 1993
, “PIM—Skeletal Plan-Based CAPP
,” Comput. Ind.
, 23
(1
), pp. 87
–97
.8.
Han
, J.
, 1996
, “Survey of Feature Research
,” University of Southern California, Los Angeles, CA, Technical Report No. IRIS-96-346
.http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.73.82679.
Abbas
, M.
, and ElMaraghy
, H.
, 2016
, “Design Synthesis of Machining Systems Using Co‐Platforming
,” J. Manuf. Syst.
, 41
, pp. 299
–313
.10.
ElMaraghy
, H.
, and Kashkoush
, M.
, 2015
, “Assembly System Synthesis Using Association Rule Discovery
,” Int. J. Adv. Manuf. Technol.
, 81
(9–12
), pp. 1705
–1722
.11.
Hanafy
, M.
, and ElMaraghy
, H.
, 2017
, “Modular Product Platform Configuration and Co-Planning of Assembly Lines Using Assembly and Disassembly
,” J. Manuf. Syst.
, 42
, pp. 289
–305
.12.
Bryan
, A.
, Wang
, H.
, and Abell
, J.
, 2013
, “Concurrent Design of Product Families and Reconfigurable Assembly Systems
,” ASME J. Mech. Des.
, 135
(5
), p. 051001
.13.
Bryan
, A.
, Hu
, S. J.
, and Koren
, Y.
, 2013
, “Assembly System Reconfiguration Planning
,” ASME J. Manuf. Sci. Eng.
, 135
(4
), p. 041005
.14.
Saxena
, L. K.
, and Jain
, P. K.
, 2012
, “A Model and Optimisation Approach for Reconfigurable Manufacturing System Configuration Design
,” Int. J. Prod. Res.
, 50
(12
), pp. 3359
–3381
.15.
AlGeddawy
, T.
, and ElMaraghy
, H.
, 2011
, “Manufacturing Systems Synthesis Using Knowledge Discovery
,” CIRP Ann. Manuf. Technol.
, 60
(1
), pp. 437
–440
.16.
AlGeddawy
, T.
, and ElMaraghy
, H.
, 2010
, “Design of Single Assembly Line for the Delayed Differentiation of Product Variants
,” Flexible Serv. Manuf. J.
, 22
(3–4
), pp. 163
–182
.17.
Ko
, J.
, and Hu
, S. J.
, 2009
, “Manufacturing System Design Considering Stochastic Product Evolution and Task Recurrence
,” ASME J. Manuf. Sci. Eng.
, 131
(5
), p. 051012
.18.
Youssef
, A. M. A.
, and ElMaraghy
, H. A.
, 2006
, “Modelling and Optimization of Multiple-Aspect RMS Configurations
,” Int. J. Prod. Res.
, 44
(22
), pp. 4929
–4958
.19.
Michalek
, J. J.
, Ceryan
, O.
, Papalambros
, P. Y.
, and Koren
, Y.
, 2005
, “Manufacturing Investment and Allocation in Product Line Design Decision-Making,” ASME
Paper No. DETC2005-84812.20.
Li
, S.
, Wang
, H.
, Hu
, S. J.
, Lin
, Y.-T.
, and Abell
, J. A.
, 2011
, “Automatic Generation of Assembly System Configuration With Equipment Selection for Automotive Battery Manufacturing
,” J. Manuf. Syst.
, 30
(4
), pp. 188
–195
.21.
Wang
, H.
, Zhu
, X.
, Wang
, H.
, Hu
, S. J.
, Lin
, Z.
, and Chen
, G.
, 2011
, “Multi-Objective Optimization of Product Variety and Manufacturing Complexity in Mixed-Model Assembly Systems
,” J. Manuf. Syst.
, 30
(1
), pp. 16
–27
.22.
Shabaka
, A. I.
, and ElMaraghy
, H. A.
, 2007
, “Generation of Machine Configurations Based on Product Features
,” Int. J. Comput. Integr. Manuf.
, 20
(4
), pp. 355
–369
.23.
Chen
, L.
, Xi
, F. J.
, and Macwan
, A.
, 2005
, “Optimal Module Selection for Preliminary Design of Reconfigurable Machine Tools
,” ASME J. Manuf. Sci. Eng.
, 127
(1
), pp. 104
–115
.24.
Mesa
, J.
, Maury
, H.
, Turizo
, J.
, and Bula
, A.
, 2014
, “A Methodology to Define a Reconfigurable System Architecture for a Compact Heat Exchanger Assembly Machine
,” Int. J. Adv. Manuf. Technol.
, 70
(9–12
), pp. 2199
–2210
.25.
FICO
, 2009
, MIP Formulations and Linearization: A Quick Reference
, Fair Issac Corporation
, San Jose, CA
, pp. 1
–19
.26.
Kalpakjian
, S.
, Schmid, S., and Vijay Sekar, K. S., 2014
, Manufacturing Engineering and Technology
, 7th ed., Pearson Publications
, Singapore
.27.
Noritaka
, F.
, Tanaka
, Y.
, and Sugano
, T.
, 2006
, Ultra-Flexible Manufacturing Line with a Finishing Machining Center for Cylinder Blocks
, Vol. 43
, Mitsubishi Heavy Industries, Ltd.
, Tokyo, Japan
.28.
Gropp
, W.
, and More
, J. J.
, 1997
, “Optimization Environments and the NEOS Server
,” Argonne National Laboratory, Lemont, IL, Report No. ANL/MCS-P654-0397
.https://www.osti.gov/scitech/servlets/purl/56326429.
Czyzyk
, J.
, Mesnier
, M. P.
, and More
, J. J.
, 1998
, “The NEOS Server
,” IEEE J. Comput. Sci. Eng.
, 5
(3
), pp. 68
–75
.30.
Dolan
, E.
, 2001
, “The NEOS Server 4.0 Administrative Guide,” Argonne National Laboratory, Lemont, IL, Technical Memorandum No. ANL/MCS-TM-250
.http://www.mcs.anl.gov/papers/TM-250.pdfCopyright © 2018 by ASME
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