Abstract
Mass customization (MC) involves the challenge of high product proliferation and frequent production volumes change. Flexible manufacturing has been treated as the main solution for these challenges. However, without a flexible material handling system (MHS), flexible manufacturing cannot be implemented successfully. Therefore, the designing and planning of the flexible MHS has attracted intensive research. This chapter first reviews different types of MHS in MC. In order to evaluate the performance of MHS, qualitative and quantitative measures are proposed. Then a detailed designing and planning of a flexible MHS using free-ranging automated guided vehicle (AGV) with an indoor local positioning system (LPS) is illustrated. As a case study, the layout of the proposed flexible MHS in the apparel industry is designed. Then to assess the effectiveness of the proposed flexible MHS, Monte Carlo simulation and analytical models are formulated to compare its operational performance with that of the fixed-track systems commonly used in the apparel industry. Economic feasibility analysis is also included. Based on our analysis, the proposed flexible MHS has potential advantages over the fixed-track system in an MC environment.
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References
Aldrich, J. (1995). Flexible materials handling. Apparel Industry Magazine, 56(5):47–49.
Alford, D.S. (2000). Mass Customization – an automotive perspective. International Journal of Production Economics, 65:99–110.
Beamon, B. (1998). Performance, reliability, and performability of material handling systems. International Journal of Production Research, doi: 10.1080/002075498193796.
Beamon B.M., Chen V.C.P. (1998) Performability-based fleet sizing in a material handling system. The International Journal of Advanced Manufacturing Technology, 14:441–449.
Beason, M. (1999). Here’s a new material handling solution. Textile World, 149(2):61–63.
Bock, S.R., Rosenberg (2000). Supporting an efficient mass customization by planning adaptable assembly lines. Proceedings of the International ICSC Congress on Intelligent Systems and Applications ISA (pp. 2:944–951).
Chakraborthy, S.B., Banik D. (2006). Design of a material handling equipment selection model using analytic hierarchy process. International Journal of Advanced Manufacturing Technology, 28:1237–1245.
Cheung, W. (2005). A study of material handling system for apparel industry. M. Phil. thesis, Industrial Engineering and Engineering Management, Hong Kong University of Science and Technology.
Chin, K.S. Pun, K.F. Lau, H. Leung, Y.S. (2004). Adoption of automation systems and strategy choices for Hong Kong apparel practitioners. International Journal of Advanced Manufacturing Technology, doi: 10.1007/s00170-003-1592-3.
Chittratanawat, S.N. (1999). An integrated approach for facility layout, P/D locations and material handling system design. International Journal of Production Research, 37(3):683–706.
Cho, C. Egbelu, P.J. (2000). Design of a web-based integrated material handling system for manufacturing applications. International Journal of Production Research, 43(2):375–403(29).
Dai, J.L., Lee N.K.S., Cheung, W.S. (2008). Performance analysis of flexible material handling systems for the apparel industry. The International Journal of Advanced Manufacturing Technology, DOI 10.1007/s00170-008-1916-4.
Datamonitor (2007). Consumer durables and apparel industry profile: global. Retrieved April 6, 2008 from Business Source Premier Database.
Egbelu, P.J. Tanchoco, J.M.A. (1984). Characterization of automatic guided vehicle dispatching rules. International Journal of Production Research 22(3):359–374.
Fogarty, D. (1992). Work in process: performance measures. International Journal of Production Economics, 26(1–3):169–172.
Fonseca, D.U., Uppal, G., Greene, T.J. (2004). A knowledge-based system for conveyor equipment selection. Expert Systems with Applications, 26:615–623.
Hill, J. (1994). A study of the cost and benefits of a unit production system versus the progressive bundle system. Retrieved May 10, 2008, from Clemson Apparel Research Facility Pendleton SC: http://handle.dtic.mil/100.2/ADA299226.
Ip, W.H. Fung, R. Keung, K.W. (1999). An investigation of stochastic analysis of flexible manufacturing systems simulation. The International Journal of Advanced Manufacturing Technology, 15:244–250.
Jawahar, N. Aravindan, P. Ponnambalam, S.G. Suresh, P.K. (1998). AGV schedule integrated with production in flexible manufacturing systems. The International Journal of Advanced Manufacturing Technology, 14:428–440.
Kim, K.E., Eom, J.K. (1997). Expert system for selection of material handling and storage systems. International Journal of Industrial Engineering, 4:81–89.
Lee, S.E. Chen, J.C. (1999). Mass-customization methodology for an apparel industry with a future. Journal of Industrial Technology, 16(1): November 1999–January 2000.
Lee, S.E. Kunz, G. Fiore, A. Campbell, J.R. (2002). Acceptance of mass customization of apparel: merchandising issues associated with preference for product, process and place. Journal of Clothing and Textiles Research, 20(3):138–146.
Lu, R. Gross, L. (2001). Simulation modeling of a pull and push assemble-to-order system. The European Operational Research Conference, Rotterdam, The Netherlands.
Maione, B. Semeraro, Q. Turchiano, B. (1986). Closed analytical formulae for evaluating flexible manufacturing system performance measures. International Journal of Production Research, 24(3):583–592.
Paraschidis, K. Fahantidis, N. Petridis, V. Doulgeri, Z. Petrou, L. Hasapis, G. (1994). Robotic system for handling textile and non rigid flat materials. Computers in Industry, 26(3):303–313.
Qiao, G. McLean, C. Riddick, F. (2002). Simulation system modeling for mass customization manufacturing. Proceedings of the 2002 Winter Simulation Conference. San Diego, CA.
Rao, R. (2006). A decision-making framework model for evaluating flexible manufacturing systems using digraph and matrix methods. The International Journal of Advanced Manufacturing Technology, 30:1101–1110.
Rembold, B., Tanchoco, J.M.A. (1994). Material flow system model evaluation and improvement. International Journal of Production Research. 32(11):2585–2602.
Sameh, M.M., Mike, D.B. (1998). Comprehensive simulation analysis of a flexible hybrid assembly system. Integrated Manufacturing Systems, 9(3):156.
Savory, P.A. Mackulak, G.T. Cochran, J.K. (1991). Material handling in a flexible manufacturing system processing part families. Proceedings of the 1991 Winter Simulation Conference.
Sedehi, M.S. Farahani, R.Z. (2009). An integrated approach to determine the block layout, AGV flow path and the location of pick-up/delivery points in single-loop systems. International Journal of Production Research, 47(11): 3041–3061.
Silveira, D.B. (2001). Mass customization: Literature review and research directions. International Journal of Production Economics, 72(1):1–13.
Smith, J. (2003). Survey on the use of simulation for manufacturing system design and operation. Journal of Manufacturing Systems, 22(2):157–171.
Sujono, S.L. (2007). A multi-objective model of operation allocation and material handling system selection in FMS design. International Journal of Production Economics, 105:116–133.
Sule, D. (1994). Manufacturing facilities: location, planning and design. PWS Publishing, Boston.
Tait, N. (1996). Materials handling in the garment factory. Apparel International, 3.27(5):20–2.
Tompkins, J.A., White, J.A., Bozer, Y.A., Frazelle, EH., Tanchoco, J.M.A., Trevino, J. (2002). Facilities Planning. Wiley, New York.
Viswanadham, N. Narahari, Y. (1992). Performance Modeling of Automated Manufacturing Systems. Prentice-Hall, Englewood Cliffs, NJ.
Witt, C. (1995). Automated material handling: breakthrough in textile industry. Material Handling Engineering, 50(1):48–51.
Wong, W.K. Leung, S.Y.S. Au, K.F. (2005). Real-time GA-based rescheduling approach for the pre-sewing stage of an apparel manufacturing process. International Journal of Advanced Manufacturing Technology, Doi:10.1007/s00170-003-1819-3.
Wong, W.K. Mok, P.Y. Leung, S.Y.S. (2006). Developing a genetic optimization approach to bal-ance an apparel assembly line. International Journal of Advanced Manufacturing Technology, Doi:10.1007/s00170-004-23500-x.
Xiao, T. Qiao, Q.X. Dong, J.H. (2001). Implementing strategy and key technologies of mass customization in automotive manufacturing. World Congress on Mass Customization and Personalization. Hong Kong University of Science and Technology.
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Lee, N., Dai, J. (2011). Designing and Planning of Material Handling Systems for Mass Customization. In: Fogliatto, F., da Silveira, G. (eds) Mass Customization. Springer Series in Advanced Manufacturing. Springer, London. https://doi.org/10.1007/978-1-84996-489-0_11
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