Abstract
Reconfigurable manufacturing system (RMS) has emerged as a cost effective mechanism that helps the manufacturing organizations to stay competitive in a global scenario where economic pressures and varying product and production demands are perpetually changing in a fiercely dynamic environment. In this context, RMS is seen as one of the current manufacturing structures, which rapidly adjusts to nuances of production capacity and functionality and is capable of producing variety of products, as and when needed, by incorporating principles: some, which are developed and the others that are in an evolutionary stage. This manuscript attempts to survey the characterization of RMS and evolution of research to improve reconfigurability. To facilitate this, an extensive literature review is carried out and an attempt is made to identify the unexplored research areas and proposes directions for future research. It is expected that, this will help researchers, designers and practicing engineers by making them aware of current trends in this area that has become a necessity for the very survival of the manufacturing sector.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abdi MR, Labib AW (2003) A design strategy for reconfigurable manufacturing systems (RMSs) using analytical hierarchical process (AHP): a case study. Int J Prod Res 41(10):2273–2299
Abdi MR, Labib AW (2004a) Feasibility study of the tactical design justification for reconfigurable manufacturing systems using the fuzzy analytical hierarchical process. Int J Prod Res 42(15):3055–3076
Abdi MR, Labib AW (2004b) Grouping and selecting products: the design key of reconfigurable manufacturing systems (RMSs). Int J Prod Res 42(3):521–546
Ali M, Wadhwa S (2005) Performance analysis of partial flexible manufacturing systems. Glob J Flex Syst Manag 6(1):9–19
Ariafara S, Ismail N (2009) An improved algorithm for layout design in cellular manufacturing system. J Manuf Syst 28(4):132–139
Asjad M, Kulkarni MS, Gandhi OP (2015) Optimal support strategy for mechanical systems under contract realm. Benchmarking 22(7):1395–1416
Azab A, ElMaraghy H, Nyhuis P, Pachow-Frauenhofer J, Schmidt M (2013) Mechanics of change: a framework to reconfigure manufacturing systems. CIRP J Manuf Sci Technol 6(2):110–119
Barad M, Sapir DE (2003) Flexibility in logistic systems—modeling and performance evaluation. Int J Prod Econ 85(2):155–170
Bey N, Hauschild MZ, McAloone TC (2013) Drivers and barriers for implementation of environmental strategies in manufacturing companies. CIRP Ann Manuf Technol 62(1):43–46
Bi Z, Xu LD, Wang C (2014) Internet of things for enterprise systems of modern manufacturing. IEEE Trans Ind Inf 10(2):1537–1546
Boër CR, Jorane F (1996) Towards a new model of sustainable production: ManuFuturing. CIRP Ann Manuf Technol 45(1):415–420
Caprihan R, Wadhwa S (1997) Impact of routing flexibility on the performance of an FMS: a simulation study. Int J Flex Manuf Syst 9(3):273–298
Da Xu L (2016) An internet-of-things initiative for one belt one road (OBOR). Front Eng Manag 3(3):206–223
Deif AM (2015) A system dynamic approach to manage changeability in manufacturing systems. In: 2nd international materials, industrial, and manufacturing engineering conference, vol 2. Procedia Manufacturing, Bali, 4–6 Feb 2015, pp 543–549
Deif AM, ElMaraghy W (2006) Effect of reconfiguration costs on planning for capacity scalability in reconfigurable manufacturing systems. Int J Flex Manuf Syst 18(3):225–238
Deif AM, ElMaraghy HA (2007) Assessing capacity scalability policies in RMS using system dynamics. Int J Flex Manuf Syst 19(3):128–150
Deif AM, ElMaraghy HA (2011) A multiple performance analysis of market-capacity integration policies. Int J Manuf Res 6(3):191–214
Desai P, Kekre S, Radhakrishnan K, Srinivasan K (2001) Product differentiation: balancing revenues and cost drivers. Manag Sci 47(1):37–51
Drucker P (1990) The emerging theory of manufacturing. Harvard Bus Rev 68(3):94–102
ElMaraghy HA (2005) Flexible and reconfigurable manufacturing systems paradigms. Int J Flex Manuf Syst 17(4):261–276
Elmasry SS, Youssef AMA, Shalaby MA (2015) A cost-based model to select best capacity scaling policy for reconfigurable manufacturing systems. Int J Manuf Res 10(2):162–183
Esmaeilian B, Behdad S, Wang B (2016) The evolution and future of manufacturing: a review. J Manuf Syst 39(April):79–100
Farid AM (2008) Facilitating ease of system reconfiguration through measures of manufacturing modularity. Proc Inst Mech Eng B: J Eng Manuf 222(10):1275–1288
Farid AM (2017) Measures of reconfigurability and its key characteristics in intelligent manufacturing systems. J Intell Manuf 28(2):353–369
Farid MM, McFarlane DC (2007) A design structure matrix based method for reconfigurability measurement of distributed manufacturing systems. Int J Intell Control Syst 1(1):1–12
Freiheit T, Wang W, Spicer P (2007) A case study in productivity-cost trade-off in the design of paced parallel production systems. Int J Prod Res 45(14):3263–3288
Goyal KK, Jain PK, Jain M (2011) A novel approach to measure machine reconfigurability in reconfigurable manufacturing system. In: Katalinic B (ed) Annals of DAAAM for 2011 and proceedings of the 22nd international DAAAM symposium, vol 1. DAAAM International, Vienna, EU 22, pp 959–960
Gu P, Hashemian M, Sosale S, Rivin E (1997) An integrated modular design methodology for life-cycle engineering. CIRP Ann Manuf Technol 46(1):71–74
Gupta P, Gandhi OP (2014) Equipment redesign feasibility through maintenance-work-order records using fuzzy cognitive maps. Int J Syst Assur Eng Manag 5(1):21–31
Gupta YP, Goyal S (1989) Flexibility of manufacturing systems: concepts and Measurements. Eur J Oper Res 43(2):119–135
Gupta P, Gupta S, Gandhi OP (2013) Modeling and evaluation of MTTR at product design stage based on contextual criteria. J Eng Des 24(7):499–523
Gyulai D, Pfeiffera A, Kàdàr B, Monostori L (2016) Simulation-based production planning and execution control for reconfigurable assembly cells. In: Factories of the future in the digital environment—proceedings of the 49th CIRP conference on manufacturing systems, vol 57, pp 445–450. doi:10.1016/j.procir.2016.11.077
Hankammer S, Jiang R, Kleer R, Schymanietz M (2016) From phonebloks to Google project ara. A case study of the application of sustainable mass customization. Proc CIRP 51(December):72–78
Hasan F, Jain PK, Kumar D (2014) DAAAM international scientific book. In: Chapter 24 titled “Performance issues in reconfigurable manufacturing system”. DAAAM International, Vienna, pp 295–310
Hauschild MZ, Jeswiet J, Alting L (2004) Design for environment—do we get the focus right? CIRP Ann Manuf Technol 53(1):1–4
Hauschild MZ, Jeswiet J, Alting L (2005) From life cycle assessment to sustainable production: status and perspectives. CIRP Ann Manuf Technol 54(2):1–21
Heinzl B, Rossler M, Popper N, Leobner I, Ponweiser K, Kastner W, Dur F, Bleicher F, Breitenecker F (2013) Interdisciplinary strategies for simulation-based optimization of energy efficiency in production facilities. In: Al-Dabass D, Orsoni AYJ, Cand R, Ibrahim Z (eds) UKSim 15th international conference on computer modelling and simulation, pp 304–309
Jandaurek K, Johst M (2017) Development trends and innovations in aerospace system testing using the example of high-lift. In: 55th AIAA aerospace sciences meeting, Grapevive. doi:10.2514/6.2017-0548
Joseph OA, Sridharan R (2011) Effects of routing flexibility, sequencing flexibility and scheduling decision rules on the performance of a flexible manufacturing system. Int J Adv Manuf Technol 56(1–4):291–306
Juan AA, Faulin J, Grasman SE, Rabe M, Figueira G (2015) A review of simheuristics: extending metaheuristics to deal with stochastic combinatorial optimization problems. Oper Res Perspect 2(December 2015):62–72. doi:10.1016/j.orp.2015.03.001
Keddis N, Kainz G, Buckl C, Knoll A (2013) Towards adaptable manufacturing systems. In: 2013 IEEE international conference on industrial technology (ICIT). IEEE, pp 1410–1415
Kianfar K, Ghomi SF, Jadid AO (2012) Study of stochastic sequence-dependent flexible flow shop via developing a dispatching rule and a hybrid GA. Eng Appl Artif Intell 25(3):494–506
Kim J-H, Duffie NA (2005) Design and analysis of closed loop capacity control for a multi-workstation production system. CIRP Ann Manuf Technol 54(1):455–458
Koren Y (2010) The global manufacturing revolution: product-process-business integration and reconfigurable systems. Wiley, Hoboken, pp 170–174
Koren Y, Shpitalni M (2001) Design of reconfigurable manufacturing systems. J Manuf Syst 29(4):130–141
Koren Y, Jovane F, Heisel U, Moriwaki T, Pritschow G, Ulsoy G, Van Brussel H (1999) Reconfigurable manufacturing systems. A Keynote Pap CIRP Ann 48(2):527–540
Kühnle H (2001) A state-time model to measure the reconfigurability of manufacturing areas—key to performance. Integr Manuf Syst 12(7):493–499
Kuzgunkaya O, ElMaraghy H (2007) Economic and strategic perspectives on investing in RMS and FMS. Int J Flex Manuf Syst 19(3):217–246
Landers RG, Min BK, Koren Y (2001) Reconfigurable machine tools. CIRP Ann Manuf Technol 50(1):269–274
Li X, Wu Q, Holsapple CW (2015) Best-value supply chains and firms’ competitive performance: empirical studies of their linkage. Int J Oper Prod Manag 35(12):1688–1709
Liraviasl KK, ElMaraghy H, Hanafy M, Samy SN (2015) A framework for modelling reconfigurable manufacturing systems using hybridised discrete-event and agent based simulation. IFAC-Pap Online 48(3):1490–1495
Luss H (1982) Operations research and capacity expansion problems: a survey. Oper Res 30(5):907–947
Maier-Speredelozzi V, Koren Y, Hu SJ (2003) Convertibility measures for manufacturing systems. CIRP Ann Manuf Technol 52(1):367–370
Malhotra V (2014) Analysis of factors affecting the reconfigurable manufacturing system using an interpretive structural modelling technique. Int J Ind Syst Eng 16(3):396–413
Malhotra V, Raj T, Arora A (2009) Reconfigurable manufacturing system: an overview. Int J Mach Intell 1(2):38–46
Malhotra V, Raj T, Arora A (2010) Excellent techniques of manufacturing systems: RMS and FMS. Int J Eng Sci Technol 2(3):137–142
Matta A, Tomasella M, Clerici M, Silvia Sacconi S (2008) Optimal reconfiguration policy to react to product changes. Int J Prod Res 46(10):2651–2673
Matthews J, McIntosh R, Medland A, Mullineux G (2010) Late customisation: issues of mass customisation in the food industry. Int J Prod Res 48(6):1557–1574
Mehrabi MG, Ulsoy AG, Koren Y (2000) Reconfigurable manufacturing system: key to future manufacturing. J Intell Manuf 11(4):403–419
Niroomand I, Kuzgunkaya O, Bulgak AA (2012) Impact of reconfiguration characteristics for capacity investment strategies in manufacturing systems. Int J Prod Econ 139(1):288–301
Niroomand I, Kuzgunkaya O, Bulgak AA (2014) The effect of system configuration and ramp-up time on manufacturing system acquisition under uncertain demand. Comput Ind Eng 73(July 2014):61–74
Nourelfath M, Ait-kadi D, Soro WI (2003) Availability modelling and optimization of reconfigurable manufacturing systems. J Qual Maint Eng 9(3):284–302
Roh J, Hong P, Min H (2014) Implementation of a responsive supply chain strategy in global complexity: the case of manufacturing firms. Int J Prod Econ 147(January 2014):198–210
Singh R, Khilwani N, Tiwari M (2007) Justification for the selection of a reconfigurable manufacturing system: a fuzzy analytical hierarchy based approach. Int J Prod Res 45(14):3165–3190
Son SY, Olsen TL, Yip-Hoi D (2001) An approach to scalability and line balancing for reconfigurable manufacturing systems. Integr Manuf Syst 12(7):500–511
Spena PR, Holzner P, Rauch E, Vidoni R, Matt DT (2016) Requirements for the design of flexible and changeable manufacturing and assembly systems: a SME-survey. Proc CIRP 41(January):207–212. doi:10.1016/j.procir.2016.01.018
Spicer P, Carlo HJ (2007) Integrating reconfiguration cost into the design of multi-period scalable reconfigurable manufacturing systems. J Manuf Sci Eng 129(1):202–210
Spicer P, Yip-Hoi D, Koren Y (2005) Scalable reconfigurable equipment design principles. Int J Prod Res 43(22):4839–4852
Steward DV (1981) The design structure system: a method for managing the design of complex systems. IEEE Trans Eng Manag 28(3):71–74
Stump B, Badurdeen F (2012) Integrating lean and other strategies for mass customization manufacturing: a case study. J Intell Manuf 23(1):109–124
The World Commission on Environment and Development (1987) Our common future. Oxford University Press, New York
Tiwari MK, Gumasta K, Gupta SK, Benyoucef L (2011) Developing a reconfigurability index using multi-attribute utility theory. Int J Prod Res 49(6):1669–1683
Toni DE, Tonchia S (1998) Manufacturing flexibility: a literature review. Int J Prod Res 36(6):587–1617
Uhlmann E, Lang KD, Prasol L, Thom S, Peukert B, Benecke S, Wagner E, Sammler F, Richarz S, Nissen NF(2017) Sustainable solutions for machine tools. In: Sustainable manufacturing. Springer, pp 47–69. doi:10.1007/978-3-319-48514-0_4
Verein Deutscher Werkzeugmaschinenfabriken (2017) Looking into the future of production technology. Press note for EMO Hannover, 18–23 Sept 2017. http://www.vdw.de/web-bin/owa/homepage?p_sprache=e. Accessed 23 Jan 2017
Wang W, Koren Y (2012) Scalability planning for reconfigurable manufacturing systems. J Manuf Syst 31(2):83–91
Weber J, Stäbler M, Thielen S, Paetzold K (2016) Modularity as key enabler for scalability of final assembly units in the automotive sector. In: Factories of the future in the digital environment—proc. of the 49th CIRP conference on manufacturing systems, vol 57 (December 2016), pp 224–228. doi:10.1016/j.procir.2016.11.039
Westkämper E, Alting L, Arndt G (2001) Life cycle management and assessment: approaches and visions towards sustainable manufacturing. Proc Inst Mech Eng B: J Eng Manuf 215(5):599–626
Wiendahl HP, ElMaraghy HA, Nyhuis P, Zah MF, Wiendahl HH, Duffie N et al (2007) Changeable manufacturing-classification, design and operation. CIRP Ann Manuf Technol 56(2):783–809
Wu CH (2012) Product-design and pricing strategies with remanufacturing. Eur J Oper Res 222(2):204–215
Wulfsberg JP, Verl A, Wurst KH, Grimske S, Batke C, Heinze T (2013) Modularity in small machine tools. Prod Eng Res Devel 7(5):483–490
Yang S, Hu SJ (2000) Productivity analysis of a six CNC machine manufacturing system with different configurations. In: Proceedings of the 2000 Japan–USA flexible automation conference, July 2000, Michigan, pp 499–505
Youssef AMA, ElMaraghy HA (2008a) Availability consideration in the optimal selection of multiple-aspect RMS configurations. Int J Prod Res 46(21):5849–5882
Youssef AMA, ElMaraghy HA (2008b) Performance analysis of manufacturing systems composed of modular machines using the universal generating function. J Manuf Syst 27(2):55–69
Zhang D, Wang L, Gao Z (2010) An integrated approach for remote manipulation of a high-performance reconfigurable parallel kinematic machine. J Manuf Syst 294(4):164–172
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Singh, A., Gupta, S., Asjad, M. et al. Reconfigurable manufacturing systems: journey and the road ahead. Int J Syst Assur Eng Manag 8 (Suppl 2), 1849–1857 (2017). https://doi.org/10.1007/s13198-017-0610-z
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13198-017-0610-z