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The International Journal of Advanced Manufacturing Technology

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12.03.2020 | ORIGINAL ARTICLE

Information modeling for cyber-physical production system based on digital twin and AutomationML

verfasst von: Haijun Zhang, Qiong Yan, Zhenghua Wen

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 3-4/2020

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Abstract

Production systems play an important role in intelligent manufacturing. A large number of manufacturing resources are designed and developed with virtual (digital) ones, which will be associated with the physical ones throughout their lifecycle. With the recent emergence of information and communications technologies (ICTs), such as internet of things, big data, virtual reality, artificial intelligence, and 5G, the interconnection and interaction between physical resources and virtual ones become possible in production systems. Digital twin (DT) shows great potential to realize the cyber-physical production system (CPPS) in the era of Industry 4.0. In this paper, we present our vision on integrating various physical resources into CPPS via DT and AutomationML. To elaborate on how to apply ICTs, this paper firstly explores a generic architecture of CPPS based on DT. DT is a virtual and authoritative representation of physical manufacturing resource, since DT includes various models and manufacturing big data of resource. The proposed architecture is illustrated in detail as follows: (1) physical layer, (2) network layer, (3) virtual layer, and (4) application layer. A case of expert fault diagnose for aircraft engine is presented using the proposed information fusion in the architecture. Secondly, this paper proposes an approach of information modeling for CPPS based on AutomationML. Various manufacturing services can be encapsulated and defined in the standardized format (AutomationML), and then the corresponding virtual manufacturing resources (DTs) will be integrated into CPPS. Finally, this paper describes a case of information modeling for blisk machining and demonstrates the modeling approach in real-life scenarios for support manufacturing resource sharing via DT. Furthermore, the conclusion and further work is briefly summarized.

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Schuja A, Bartelt M, Kuhlenkotter B (2014) From conception phase up to virtual verification using AutomationML. Procedia CIRP 23:171–177

Keller M, Rosenberg M, Brettel M, Friederichsen N (2014) How virtualization, decentralization and network building change the manufacturing landscape: an industry 4.0 perspective. Int J Mech Aerosp Ind Mechatron Manuf Eng 8:37–44

Posada J, Toro C, Barandiaran I, Oyarzun D, Stricker D, De Amicis R, Pinto EB, Eisert P, Döllner J, Vallarino I (2015) Visual computing as key enabling technology for industry 4.0 and industrial internet. IEEE Comput Graph Appl 35(2):26–40

Koren Y, Shpitalni M (2010) Design of reconfiguration manufacturing systems. J Manuf Syst 29(1):30–41

Lu Y, Xu X (2018) Resource virtualization: a core technology for developing cyber-physical production systems. J Manuf Syst 47:128–140

Zhang Y, Qian C, Lv J, Liu Y (2016) Agent and cyber-physical system based self-organizing and self-adaptive intelligent shopfloor. IEEE Trans Ind Inf 13(2):737–747

Danny Anandan P, Ferreira P, Lohse N, Guedes M (2017) An AutomationML model for plug-and-produce assembly systems. In: IEEE Int Conf Ind Inf, Emden, Germany, pp 849–854

Haag S, Anderl R (2018) Digital twin-proof of concept. Manuf Let 15(Part B):64–66

Buckholtz B, Ragai I, Wang L (2015) Cloud manufacturing: current trends and future implementations. J Manuf Sci Eng 137(4):1–46

10.

Colombo AW, Karnouskos S, Bangemann T (2014) IMC-AESOP outcomes: paving the way to collaborative manufacturing systems. In: IEEE Int Conf Ind Inform, Porto Alegre, RS, Brazil, pp 255–260

11.

Morgan J, O’Donnel GE (2015) The cyber physical implementation of cloud manufacturing monitoring systems. Procedia CIRP 33:29–34

12.

Wang XV, Wang L (2017) A cloud-based production system for information and service integration: an internet of things case study on waste electronics. Enterp Inf Syst 11(7):952–968

13.

Tao F, Cheng Y, Xu L, Zhang L, Li BH (2014) CCIoT-CMfg: cloud computing and internet of things-based cloud manufacturing service system. IEEE Trans Ind Inf 10(2):1435–1442

14.

Ashton K (2009) That ‘internet of things’ thing. RFiD J 22:97–114

15.

Wang S, Zhang G, Shen B, Xie X (2011) An integrated scheme for cyber-physical building energy management system. Procedia Eng 15:3616–3620

16.

Rudtsch V, Gausemeier J, Gesing J, Mittag T, Peter S (2014) Pattern-based business model development for cyber-physical production systems. Procedia CIRP 25:313–319

17.

Cardin O (2019) Classification of cyber-physical production systems applications: proposition of an analysis framework. Comput Ind 104:11–21

18.

Monostori L (2014) Cyber-physical production systems: roots expectations and R&D challenges. Procedia CIRP 17:9–13

19.

Um J, Weyer S, Quint F (2017) Plug and simulate within modular assembly line enabled by digital twins and the use of Automationml. IFAC Proc 50(1):15904–15909

20.

Talkhestania BA, Jazdib N, Schloeglc W, Weyrichb M (2018) Consistency check to synchronize the digital twin of manufacturing automation based on anchor points. Procedia CIRP 72:159–164

21.

Uhlemann TH, Lehmann C, Steinhilper R (2017) The digital twin realizing the cyber physical production system for industry 4.0. Procedia CIRP 61:335–340

22.

Terkaj W, Urgo M(2014)Ontology-based modeling of production systems for design and performance evaluation. In: IEEE Int Conf Ind Informatics, Porto Alegre, Brazil, pp 748–753

23.

Zhang HJ, Yan Q, Liu YP, Jiang ZQ (2016) An integer-coded differential evolution algorithm for simple assembly line balancing problem of type 2. Assem Autom 36(3):246–261

24.

Zhang HJ, Zhang GH, Yan Q (2018) Digital twin-driven cyber-physical production system towards smart shop-floor. J Ambient Intell Humanized Comput 10:4439–4453. https://doi.org/10.1007/s12652-018-1125-4 CrossRef

25.

Hatvany J, Nemes L (1978) Intelligent manufacturing systems-a tentative forecast. IFAC Proc 11(1):895–899

26.

Ueda K, Vaario J (1998) The biological manufacturing system: adaptation to growing complexity and dynamics in manufacturing environment. CIRP J Manuf Syst 27(1):41–46

27.

Ueda K, Vaario J, Ohkura K (1997) Modeling of biological manufacturing systems for dynamic reconfiguration. CIRP Ann Manuf Technol 46(1):343–346

28.

Koren Y, Heisel Z, Jovane F, Moriwaki T, Pritschow G, Ulsoy G, Van Brussel H (1999) Reconfigurable manufacturing systems. CIRP Ann Manuf Technol 48(2):527–540

29.

Kádár B, Lengyel A, Monostori L, Suginishi Y, Pfeiffer A, Nonaka Y (2010) Enhanced control of complex production structures by tight coupling of the digital and the physical worlds. CIRP Ann Manuf Technol 59(1):437–440

30.

Kádár B, Terkaj W, Sacco M (2013) Semantic virtual factory supporting interoperable modeling and evaluation of production systems. CIRP Ann Manuf Technol 52(1):443–446

31.

Maropoulos PG (2002) Digital enterprise technology-defining perspectives and research priorities. Int J Comput Integr Manuf 16(7–8):467–478

32.

Westkämper E, Von Briel R (2001) Continuous improvement and participative factory planning by computer systems. CIRP Ann Manuf Technol 50(1):347–352

33.

Bongaerts L, Monostori L, McFarlane D, Kádár B (2000) Hierarchy in distributed shop floor control. Comput Ind 43(2):123–137

34.

Márkus A, Kis T, Váncza J, Monostori L (1996) A market approach to holonic manufacturing. CIRP Ann Manuf Technol 45(1):433–436

35.

Monostori L, Váncza J, Kumara SRT (2006) Agent-based systems for manufacturing. CIRP Ann Manuf Technol 55(2):697–720

36.

Valckenaers P, Brussel HV (2015) Design for the unexpected from holonic manufacturing systems towards a humane mechatronics society. Elsevier, Amsterdam

37.

Valckenaers P, Van Brussel H (2005) Holonic manufacturing execution systems. CIRP Ann Manuf Technol 54(1):427–432

38.

Van Brussel H, Wyns J, Valckenaers P, Bongaerts L, Peeters P (1998) Reference architecture for holonic manufacturing systems: PROSA. Comput Ind 37:255–274

39.

Vogel-Heuser B, Lee J, Leitão P (2015) Agents enabling cyber-physical production systems. Automatisierungstechnik 63(10):777–789

40.

Givehchi O, Jasperneite J (2013) Industrial automation services as part of the cloud: first experiences. In: Proceedings of the Jahreskolloquium Kommunikation in der Automation, KommA Magdeburg, Germany, pp 1–10

41.

Gupta A, Kumar M, Hansel S, Saini A (2013) Future of all technologies-the cloud and cyber physical systems. Int J Enhanced Res Sci Tech Eng 2(2):1–6

42.

Mezgár I, Rauschecker U (2014) The challenge of networked enterprises for cloud computing interoperability. Comput Ind 65(4):657–674

43.

Schlechtendahl J, Kretschmer F, Lechler A, Verl A (2014) Communication mechanisms for cloud based machine controls. Procedia CIRP 17:830–834

44.

Schlechtendahl J, Kretschmer F, Sang Z, Lechler A, Xu X (2017) Extend study of network capability for cloud based control systems. Robot Comput Integr Manuf 43:89–95

45.

Wang LH, Törngren M, Onori M (2015) Current status and advancement of cyber-physical systems in manufacturing. J Manuf Syst 37:517–527

46.

Lee EA (2006) Cyber-physical systems-are computing foundations adequate? In: NSF Shop floor on Cyber-Phys Syst: Research Motivation, Techniques and Roadmap, Austin, TX, pp 1–9

47.

Rojas RA, Rauch E (2019) From a literature review to a conceptual framework of enablers for intelligent manufacturing control. Int J Adv Manuf Technol 104(1–4):517–533

48.

Woo J, Shin SJ, Seo W, Meilanitasari P (2018) Developing a big data analytics platform for manufacturing systems: architecture, method, and implementation. Int J Adv Manuf Technol 99(9–12):2193–2217

49.

Zhuang CB, Liu JH, Xiong H (2018) Digital twin-based smart production management and control framework for the complex product assembly shop-floor. Int J Adv Manuf Technol 96(1–4):1149–1163

50.

Schlechtendahl J, Keinert M, Kretschmer F, Lechler A, Verl A (2014) Making existing production systems industry 4.0-ready: holistic approach to the integration of existing production systems in industry 4.0 environments. Prod Eng 9(1):143–148

51.

Lee J, Bagheri B, Kao H-A (2015) A cyber-physical systems architecture for industry 4.0-based manufacturing systems. Manuf Let 3:18–23

52.

Monostori L, Kádár B, Bauernhanslcd T, Kondoh S, Kumara S, Reinhart G, Sauer O, Schuh G, Sihn W, Ueda K (2016) Cyber-physical systems in manufacturing. CIRP Ann 65(2):621–641

53.

Botond K, Terkaj W, Sacco M (2013) Semantic virtual factory supporting interoperable modeling and evaluation of production systems. CIRP Ann Manuf Technol 62(1):443–446

54.

Usländer T, Epple U (2015) Reference model of industrie 4.0 service architectures. Automatisierungstechnik 63(10):858–866

55.

Ma SY, Zhang YF, Lv JX, Yang HD, Wu JZ (2019) Energy-cyber-physical system enabled management for energy-intensive manufacturing industries. J Clean Prod 226:892–903

56.

Domingues P, Carreira P, Vieira R, Kastner W (2016) Building automation systems: concepts and technology review. Comput Stand Interfaces 45:1–12

57.

Morariu C, Morariu O, Borangiu T, Raileanu S (2012) Manufacturing service bus integration model for highly flexible and scalable manufacturing systems. IFAC Proc 14(1):1850–1855

58.

Zhang YF, Guo ZG, Lv JX, Liu Y (2018) A framework for smart production-logistics systems based on CPS and industrial IoT. IEEE Trans Ind Inf 14(9):4019–4031

59.

Ye X, Hong SH (2018) An AutomationML/OPC UA-based industry 4.0 solution for a manufacturing system. In: IEEE Int Conf Emerging Technol Factory Autom, Torino, Italy, pp 543–550

60.

Coronado PDU, Lynn R, Louhichi W, Parto M, Wescoat E, Kurfess T (2018) Part data integration in the shop floor digital twin: mobile and cloud technologies to enable a manufacturing execution system. J Manuf Syst 48:25–33

61.

Negri E, Fumagalli L, Macchi M (2017) A review of the roles of digital twin in cps-based production systems. Procedia Manuf 11:939–948

62.

Rosen R, Wichert G, Lo G, Bettenhausen KD (2015) About the importance of autonomy and digital twins for the future of manufacturing. IFAC Proc 48(3):67–72

63.

Wang J, Ma Y, Zhang L, Gao R, Wu D (2018) Deep learning for smart manufacturing: methods and applications. J Manuf Syst 48:144–156

64.

Lee J, Lapira E, Bagheri B, Kao H-A (2013) Recent advances and trends in predictive manufacturing systems in big data environment. Manuf Lett 1(1):38–41

65.

Uhlemann THJ, Schock C, Lehmann C, Freiberger S, Steinhilper R (2017) The digital twin: demonstrating the potential of real time data acquisition in production systems. Procedia Manuf 9:113–120

66.

Hochhalter J, Leser WP, Newman JA, Gupta VK, Yamakov V, Cornell SR, Willard SA, Heber G (2014) Coupling damage-sensing particles to the digital twin concept. NASA Center for Aerospace Information. https://ntrs.nasa.gov/search.jsp?R=20140006408. Accessed 27 Sept 2019

67.

Lightfoot H, Baines T, Smart P (2013) The servitization of manufacturing: a systematic literature review of interdependent trends. Int J Oper Prod Managt 33(11/12):1408–1434

68.

Xu X (2012) From cloud computing to cloud manufacturing, robotics and computer-integrated manufacturing. Robot Comput Integr Manuf 28(1):75–86

69.

Qi Q, Tao F, Zuo Y, Zhao D (2018) Digital twin service towards smart manufacturing. Procedia CIRP 72:237–242

70.

Pennington A, Alison McKay A, Susan Bloor MS (1996) A framework for product data, knowledge and data engineering. IEEE Trans Knowl Data Eng 8(5):825–838

71.

Schroeder GN, Steinmetz C, Pereira CE, Espindola DB (2016) Digital twin data modeling with AutomationML and a communication methodology for data exchange. IFAC Proc 49(30):12–17

72.

Choi S, Jung K, Kulvatunyou B, Morris KC (2016) An analysis of technologies and standards for designing smart manufacturing systems. J Res Natl Inst Stand Technol 121:422–433

73.

Luder A, Schmidt N, Rosendahl R, John M (2014) Integrating different information types within AutomationML. In: IEEE Int Conf Emer Technol Fact Autom, Barcelona, Spain, pp 1–5

74.

Drath R, Luder A, Peschke J, Hundt L (2008) AutomationML-the glue for seamless automation engineering. In: IEEE Int Conf Emerg Technol Fact Autom, Hamburg, Germany, pp 616–623

75.

Whitepaper OPC Unified architecture information model for AutomationML. https://www.automationml.org/o.red.c/news-173.html. Accessed 1 June 2019

Titel: Information modeling for cyber-physical production system based on digital twin and AutomationML
verfasst von: Haijun Zhang
Qiong Yan
Zhenghua Wen
Publikationsdatum: 12.03.2020
Verlag: Springer London
Erschienen in: The International Journal of Advanced Manufacturing Technology / Ausgabe 3-4/2020
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-020-05056-9

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