Reconfigurable manufacturing systems: journey and the road ahead

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