Abstract
Industrial Revolution emerged many improvements in manufacturing and service systems. Because of remarkable and rapid changes appeared in manufacturing and information technology, synergy aroused from the integration of the advancements in information technology, services and manufacturing were realized. These advancements conduced to the increasing productivity both in service systems and manufacturing environment. In recent years, manufacturing companies and service systems have been faced substantial challenges due to the necessity in the coordination and connection of disruptive concepts such as communication and networking (Industrial Internet) , embedded systems (Cyber Physical Systems), adaptive robotics , cyber security, data analytics and artificial intelligence , and additive manufacturing. These advancements caused the extension of the developments in manufacturing and information technology, and these coordinated and communicative technologies are constituted to the term, Industry 4.0 which was first announced from German government as one of the key initiatives and highlights a new industrial revolution. As a result, Industry 4.0 indicates more productive systems; companies have been searching the right adaptation of this term. On the other hand, the achievement criteria and performance measurements of the transformation to Industry 4.0 are still uncertain. Additionally, a structured and systematic implementation roadmap is still not clear. Thus, in this study, the fundamental relevance between design principles and technologies is given and conceptual framework for Industry 4.0 is proposed concerning fundamentals of smart products and smart processes development.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Similar content being viewed by others
References
ABB Contact (2014) Connecting the world—Industry 4.0, Customer news magazine by ABB
Acatech (2015) Final report of the Industrie 4.0 Working Group. Technical Report. http://www.gtai.de/GTAI/Content/EN/Invest/_SharedDocs/Downloads/GTAI/Brochures/Industries/industrie4.0-smart-manufacturing-for-the-future-en.pdf
Bagheri B, Yang S, Kao H, Lee J (2015) Cyber-physical systems architecture for self-aware machines in Industry 4.0 environment. IFAC-Pap Online 48–3:1622–1627
Biegelbauer G, Vincze M, Noehmayer H, Eberst C (2004) Sensor based robotics for fully automated inspection of bores at low volume high variant parts. IEEE International Conference on Robotics and Automation, vol 5, pp 4852–4857, 26 April–1 May 2004
Bitkom, VDMA, ZVEI (2016) Implementation strategy Industrie 4.0: report on the results of the Industrie 4.0 Platform
Blanchet M, Rinn T, von Thaden G, de Thieulloy G (2014) Industry 4.0: the new industrial revolution. How Europe will succeed. In: Think Act, Roland Berger Strategy Consultants GmbH
Borgia E (2014) The internet of things vision: key features, applications and open issues. Comput Commun 54:1–31
Deloitte AG (2015) Industry 4.0: challengers and solutions for the digital transformation and use of exponential technologies
DHL Report (2015) Internet of things in logistics: a collaborative report by DHL and Cisco on implications and use cases for the logistics industry. http://www.dpdhl.com/content/dam/dpdhl/presse/pdf/2015/DHLTrendReport_Internet_of_things.pdf
European Commission (2015) Factories of the Future. http://ec.europa.eu/research/industrial_technologies/factories-of-thefuture_en.html. Viewed 12 May 2017
Ford SLN (2014) Additive manufacturing technology: potential implications for U.S. manufacturing competitiveness. J Int Commer Econ. http://www.usitc.gov/journals
Gaub H (2015) Customization of mass-produced parts by combining injection molding and additive manufacturing with Industry 4.0 technologies, reinforced plastics, vol 00, Number 00. doi:10.1016/j.repl.2015.09.004
Hermann M, Pentek T, Otto B (2015) Design principles for Industrie 4.0 scenarios: a literature review, Technische Universität Dortmund, Fakultät Maschinenbau, Audi Stiftungslehrstuhl Supply Net Order Management, White Paper
IERC (2011) Internet of things: strategic research roadmap [WWW Document]. URL: http://www.internet-of-things-research.eu/about_iot.htm. Accessed 26 April 17
Jazdi N (2014) Cyber physical systems in the context of Industry 4.0. 2014 IEEE international conference on automation, quality and testing, robotics. doi:10.1109/AQTR.2014.6857843
Kühn W (2006) Digital factory—simulation enhancing the product and production engineering process. In: Perrone LF, Wieland FP, Liu J, Lawson BG, Nicol DM, Fujimoto RM (eds) Proceedings of the 2006 winter simulation conference, pp 1899–1906
Lasi H, Fettke P, Feld T, Hoffmann M (2014) Industry 4.0. Bus Inf Syst Eng 6(4):239–242
Lee J, Bagheri B, Kao H (2015) A cyber-physical systems architecture for Industry 4.0-based manufacturing systems. Manufact Lett 3:18–23
Li X, Li D, Wan J, Vasilakos AV, Lai CF, Wang S (2015a) A review of industrial wireless networks in the context of Industry 4.0. Wirel Netw. doi:10.1007/s11276-015-1133-7
Li S, Xu LD, Zhao S (2015b) The internet of things: a survey. Inf Syst Front 17:243–259
Liggan P, Lyons D (2011) Applying predictive maintenance techniques to utility systems. Pharm Eng 31(6):1–7
McKinsey Digital (2016) Industry 4.0 after the initial hype: where manufacturers are finding value and how they can best capture it
Obitko, M, Jirkovský V (2015) Big data semantics in Industry 4.0. In: Mařík V et al (eds) HoloMAS 2015, LNAI 9266, pp 217–229
Paelke V (2014) Augmented reality in the smart factory supporting workers in an Industry 4.0. Environment. IEEE Emerging Technology and Factory Automation (ETFA)
Pittaway L, Robertson M, Munir K, Denyer D, Neely A (2004) Networking and innova tion: a systematic review of the evidence. Int J Manag Rev 5:137–168
Porter M, Heppelmann J (2015) How smart connected products are transforming companies. Harvard Business School Publishing
Qin J, Liu Y, Grosvenor R (2016) A categorical framework of manufacturing for Industry 4.0 and beyond. Procedia CIRP 52:173–178
Rüßmann M, Lorenz M, Gerbert P, Waldner M, Justus J, Engel P, Harnisch M (2015) Industry 4.0: the future of productivity and growth in manufacturing industries. https://www.bcgperspectives.com/content/articles/engineered_products_project_business_industry_40_future_productivity_growth_manufacturing_industries/
Saldivar AAF, Li Y, Chen W, Zhan Z, Zhang J, Chen LY (2015) Industry 4.0 with cyber-physical integration: a design and manufacture perspective. Proceedings of the 21st international conference on automation & computing, Glasgow, UK, September 2015
Segovia D, Mendoza M, Mendoza E, González E (2015) Augmented reality as a tool for production and quality monitoring. 2015 international conference on virtual and augmented reality in education. Procedia Comput Sci 75:291–300
Syberfeldt A, Holm M, Danielsson O, Wang L, Brewster RL (2016) Support systems on the industrial shop-floors of the future—operators’ perspective on augmented reality. 6th CIRP Conference on Assembly Technologies and Systems (CATS). Procedia CIRP 44, pp 108–113
Thames JL, Schaefer D (2017) Cybersecurity for Industry 4.0 and advanced manufacturing environments with ensemble intelligence. In: Thames L, Schaefer D (eds) Cybersecurity for Industry 4.0.1. Springer (Springer Series in Advanced Manufacturing), Berlin, pp 243–265
Thames JL, Schaefer D (2017) Industry 4.0: an overview of key benefits, technologies, and challenges. In: Thames, L, Schaefer D (eds) Cybersecurity for Industry 4.0.1. Springer (Springer Series in Advanced Manufacturing), Berlin, pp 1–33
Tideman M, van der Voort MC, van Houten FJAM (2008) A new product design method based on virtual reality, gaming and scenarios. Int J Interact Des Manuf (IJIDeM) 2(4):195–205. doi:10.1007/s12008-008-0049-1
Uckelmann D, Harrison M, Michahelles F (2011) An architectural approach towards the future internet of things. In: Uckelmann D et al (eds) Architecting the internet of things. doi:10.1007/978-3-642-19157-2_1
Uckelmann D (2008) A definition approach to smart logistics. In: Balandin S, Moltchanov D, Koucheryavy Y (eds) Next generation teletraffic and wired/wireless advanced networking. NEW2AN 2008. Lecture Notes in Computer Science, vol 5174. Springer, Berlin
VDMA (2016) Industrie 4.0 in practice—Solutions for industrial applications. Industry 4.0 Forum
Wang L, Wang G (2016) Big data in cyber-physical systems, digital manufacturing and Industry 4.0. Int J Eng Manufact 4: 1–8
Wang S, Wan J, Zhang D, Li D, Zhang C (2016) Towards smart factory for Industry 4.0: a self-organized multi-agent system with big data based feedback and coordination. Comput Netw 000:1–11
Wittenberg C (2015) Cause the trend Industry 4.0 in the automated industry to new requirements on user interface. In: Kurosu M (ed) Human-computer interaction, Part III, HCII 2015, LNCS, vol 9171, pp 238–245
Wu D, Rosen DW, Schaefer D (2014) Cloud-based design and manufacturing: status and promise. In: Schaefer, D (ed) Cloud-Based Design and Manufacturing (CBDM). Springer, Berlin, 1–24
Zhang Y, Ren S, Liu Y, Si S (2016) Big data analytics architecture for cleaner manufacturing and maintenance processes of complex products. J Cleaner Prod Volume 142 Part 2, 1–16
Zuehlke D (2010) Smart factory towards a factory-of-things. Ann Rev Control 34(1): 129–138. [Online]. Available: http://www.sciencedirect.com/science/article/pii/S1367578810000143
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Copyright information
© 2018 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Salkin, C., Oner, M., Ustundag, A., Cevikcan, E. (2018). A Conceptual Framework for Industry 4.0. In: Industry 4.0: Managing The Digital Transformation. Springer Series in Advanced Manufacturing. Springer, Cham. https://doi.org/10.1007/978-3-319-57870-5_1
Download citation
DOI: https://doi.org/10.1007/978-3-319-57870-5_1
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-57869-9
Online ISBN: 978-3-319-57870-5
eBook Packages: EngineeringEngineering (R0)