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The International Journal of Advanced Manufacturing Technology

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27-02-2021 | ORIGINAL ARTICLE

Parallel disassembly approach with recycling rate calculation of industrial products

Authors: Imen Belhadj, Moncef Hammadi, Nizar Aifaoui

Published in: The International Journal of Advanced Manufacturing Technology | Issue 9-10/2021

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Abstract

Design activity is the initial step in manufacturing. In smart factory, these activities should be interconnected. The final cost of a product is affected by decisions which are made in these activities. Since 1980, Design for Manufacturing and Assembly (DFMA) approaches has been developed to guide planners to produce products which are easy to fabricate and assemble. Designing products for recyclability is constrained by environmental and economic targets. Numerous Design for Assembly (DFA) laws and parameters can be employed to measure the recyclability index of product designs. Parallel assembly and disassembly techniques using human and robot collaboration can also improve the design quality by choosing the shorter way to completely dismantle the product or to dismantle wear parts. The implementation of these approaches has created a revolution in today’s industry, by many improvements as reduce product cost, shorter time to market, better quality, and few suppliers of standard parts. In this paper, a novel method to parallel dismantle a product is presented. To improve the design quality of the product, a set of assessment metrics were considered as recyclability for reusing aspect, total disassembly time of the product, parallelism aspect, and design efficiency. A comparative example is used to demonstrate the added value of the proposed approach.

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Geda MW, Kwong CK, Jiang H (2018) Fastening method selection with simultaneous consideration of product assembly and disassembly from a remanufacturing perspective. The International Journal of Advanced Manufacturing Technology 101:1481–1493. https://doi.org/10.1007/s00170-018-3027-1CrossRef

EU (2000) Directive 2000/53/EC of the European parliament and of the council of 18 September 2000 on end-of-life vehicles. Official Journal of the European Union L269, 34–42. https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=CELEX%3A32000L0053. Accessed 29 May 2020

Directive 2002/95/EC (2003) European Parliament and the Council on restriction of the use of certain hazardous substances in electrical and electronic equipment (RoHS). Off J Eur Union 46:19–23

Umeda Y, Ishizuka K, Matsumoto M, Kishita Y (2017) Modeling competitive market of remanufactured products. CIRP Ann 66(1):61–64CrossRef

Bourjault A. (1984), Contribution d’une approche méthodologique de l’assemblage automatisé: élaboration automatique des séquences opératoires, Thèse d’Etat Université de Franche-Comté.

De Fazio T, Whitney D (1987) Simplified all mechanical assembly sequences. IEEE Journal of Robotics and Automation 3(6):640–658CrossRef

Wolter J. D. (1988), On the Automatic Generation of Plans for Mechanical Assembly, Ph.D thesis, Univ. of Michigan, Dep. of Computer, Information and Control Engineering, Sept

Ravani B, Roth B (1984) Mappings of Spatial Kinematics. Transaction of ASME, Journal of Mechanisms, Transmissions, and Automation in Design 106:341–347CrossRef

Liu Y, Popplestone R (1984) Planning for assembly from solid models. IEEE Int Conf Robot Automat 1:222–227

10.

Lui M.C.M. (1988) Generation and evaluation of mechanical assembly sequences using the liaison sequence method, S.M. Theses, M.I.T, Cambridge

11.

Baldwin DF, Thomas EA, Man-Cheung ML, Thomas L, Fazio D, Daniel EW (1991) An integrated computer aid for generating and evaluating assembly sequences for mechanical products. IEEE Transactions on Robotics and Automation 7(1):78–94CrossRef

12.

Dini G, Santochi M (1992) Automated Sequencing and Subassembly Detection in Assembly Planning. CIRP Annals - Manufacturing Technology 41(1):1–4CrossRef

13.

La Perrière L, El Maraghy HA (1996) GAPP: A Generative Assembly Process Planner. Journal of Manufacturing Systems 15(4):282–293CrossRef

14.

Cittolin A. (1997) Etude de filtres universels en vue d’une détermination et d’une sélection automatique de gammes d’assemblage de produits industriels, Thèse de doctorat, Ecole Polytechnique Fédérale de Lausanne

15.

Kendra E. M., Gungor A., Gupta S. M. (1998), A Petri Net Approach to Disassembly Process Planning, Journal of Computer Industrial Engineering, Vol. 35, n° 1-2, pp.165

16.

Subramani AK, Dewhurst P (1991) Automatic generation of product disassembly sequences. CIRP Annuals 40:115–118CrossRef

17.

Mascle C, Dupinet E, Maranzana R (1994) Feature modeling in assembly planning, Congrès de l'IFIP, modélisation et reconnaissance de caractéristiques en CFAO. Valenciennes, France

18.

Mattikali RS, Khosla PK (1991) Analysis of restraints to translational and rotational motion from the geometry of contact, Proceedings ASME winter annual meeting, DE-Vol. 39, Issues in Design Manufacture/Integration, Atlanta

19.

Milner JM, Graves SC, Whitney DE (1994) Using simulated annealing to select least-cost assembly sequences. Proceedings of IEEE International Conference on Robotics and Automation 2058-2063

20.

Motavalli S, Islam A (1997) Multi-criteria assembly sequencing. Comput Ind Eng 32(4):743–751CrossRef

21.

Zha XF, Samuel YE, Lim SC (1998) Integrated Knowledge-Based Assembly Sequence Planning. Int J Adv Manuf Technol 14:50–64CrossRef

22.

Wilson RH, Latombe JC (1994) Geometric reasoning about mechanical assembly. Artificial Intelligence 72(2)

23.

Tönshoff HK, Menzel E, Park HS (1992) A Knowledge-Based System for Automated Assembly Planning. CIRP Annals - Manufacturing Technology 41(1):19–24CrossRef

24.

Oliver JH, Huang H-T (1994) Automated path planning for integrated assembly design. Computer-Aided Design 26(9):658–666CrossRef

25.

Fujimoto H, Sebaaly MF (1999) A New Sequence Evolution Approach to Assembly Planning. J. Manuf. Sci. Eng 122(1):198–205CrossRef

26.

Billatos S, Basaly N (1997) Green Technology and Design for the Environment. Taylor & Francis, Washington, DC

27.

Bonneville F, Henrioud J, Bourjault A (1994) Generation of assembly sequences with ternary operations. IEEE International Symposium on Assembly and Task Planning, pp 245–249. https://doi.org/10.1109/ISATP.1995.518778

28.

Boothroyd G (1994a) Product design for manufacture and assembly. Computer Aided Design 26(7):505–520CrossRef

29.

Boothroyd G (1994b) Product design for manufacture and assembly. Computer-Aided Design 26-7:505–521CrossRef

30.

Bowland NW, Gao JX, Sharma R (2003) A PDM- and CAD-integrated assembly modelling environment for manufacturing planning. Journal of Materials Processing Technology 138:82–88CrossRef

31.

Demoly F, Xiu-Tian Y, Benoît E, Louis R (2011) Samuel Gomes, An assembly oriented design framework for product structure engineering and assembly sequence planning. Robotics and Computer-Integrated Manufacturing 27:33–46CrossRef

32.

Ben Hadj R, Trigui M, Aifaoui N (2015) Toward an Integrated CAD Assembly Sequence Planning Solution. Journal of Mechanical Engineering Science Part C 229-16:2987–3001CrossRef

33.

Trigui M, Ben HR, Aifaoui N (2015) An interoperability CAD assembly sequence plan approach. The International Journal of Advanced Manufacturing Technology 79:1465–1476CrossRef

34.

Issaoui L, Aifaoui N, Benamara A (2015) Solution space reduction of disassembly sequences generated automatically via computer aids. Proc IMechE Part C J Mech Eng Sci 229(16):2977–2986. https://doi.org/10.1177/0954406214565803CrossRef

35.

Issaoui L, Aifaoui N, Benamara A (2016) Modelling and implementation of geometric and technological information for disassembly simulation in CAD environment. Int J Adv Manuf Technol 2016:1731–1741. https://doi.org/10.1007/s00170-016-9128-9CrossRef

36.

Shovala S, Efatmaneshnikb M, Michael JR (2017) Probabilistic Approach To Modular Assembly. IFAC conference 50(1):5688–5693

37.

Hsien-Pin H (2017) A Fuzzy Knowledge-Based Disassembly Process Planning System Based on Fuzzy Attributed and Timed Predicate/Transition Net. IEEE Transactions on Systems, Man, and Cybernetics: Systems 47(8):1800–1813CrossRef

38.

Yong W, Jihong L (2013) Subassembly identification for assembly sequence planning. Int J Adv Manuf Technol 68:781–793CrossRef

39.

Belhadj I, Trigui M, Benamara A (2016) Subassembly generation algorithm from a CAD model. Int J Adv Manuf Technol 9–12:2829–2840. https://doi.org/10.1007/s00170-016-8637-xCrossRef

40.

Trigui M, Belhadj I, Benamara A (2017) Disassembly plan approach based on subassembly concet. Int J Adv Manuf Technol 90:219–231. https://doi.org/10.1007/s00170-016-9363-0CrossRef

41.

Villalba G, Segarra M, Chimenos JM, Espiell F (2004) Using the recyclability index of materials as a tool for design for disassembly. Ecol. Econ. 50(3–4):195–200CrossRef

42.

Hagelüken C, Corti CW (2010) Recycling of gold from electronics: Cost-effective use through ‘Design for Recycling’. Gold Bull. 43(3):209–220CrossRef

43.

Fegade V, Shrivatsava RL, Kale AV (2015) Design for Remanufacturing: Methods and their Approaches. Mater. Today Proc. 2(4–5):1849–1858CrossRef

44.

Aluminum association (2011) Aluminum: The element of sustainability. A North Am. Alum. Ind. Sustain, The Aluminum Association 2011:2–57

45.

US EPA (2017) “Advancing sustainable materials management: facts and figures,” United States Environ Prot Agency. https://www.epa.gov/smm/advancing-sustainable-materials-management facts-and-figures-report. Accessed 25 Aug 2020

46.

Das SK, Naik S (2002) Process planning for product disassembly. Int. J. Prod. Res. 40(6):1335–1355CrossRef

47.

Soh SL, Ong SK, Nee AYC (2015) Application of Design for Disassembly from Remanufacturing Perspective. Procedia CIRP 26:577–582CrossRef

48.

Kang GJ, Lee D-H, Xirouchakis P, Persson J-G (2001) Parallel Disassembly Sequencing with Sequence-Dependent Operation Times. CIRP Annals 50-1:343–346CrossRef

49.

Detta D, WooT C (1995) Algorithm for Multiple Disassembly and Parallel Assemblies. Transaction of the ASME 117:102–109

50.

Chiodo J (2005) Design for disassembly guidelines. Act. Disassembly Res. 2(1):29–37

Title: Parallel disassembly approach with recycling rate calculation of industrial products
Authors: Imen Belhadj
Moncef Hammadi
Nizar Aifaoui
Publication date: 27-02-2021
Publisher: Springer London
Published in: The International Journal of Advanced Manufacturing Technology / Issue 9-10/2021
Print ISSN: 0268-3768
Electronic ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-021-06830-z

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