“Industry 4.0”的意思、由来-开放百科全书

Industry 4.0 fosters what has been called a "smart factory". Within modular structured smart factories, cyber-physical systems monitor physical processes, create a virtual copy of the physical world and make decentralized decisions. Over the Internet of Things, cyber-physical systems communicate and cooperate with each other and with humans in real-time both internally and across organizational services offered and used by participants of the value chain.^[1]

Name

The term "Industry 4.0", shortened to I4.0 or simply I4, originates from a project in the high-tech strategy of the German government, which promotes the computerization of manufacturing.^[6]

The term "Industry 4.0" was revived in 2011 at the Hannover Fair.^[7] In October 2012 the Working Group on Industry 4.0 presented a set of Industry 4.0 implementation recommendations to the German federal government. The Industry 4.0 workgroup members and partners are recognized as the founding fathers and driving force behind Industry 4.0.

On 8 April 2013 at the Hannover Fair, the final report of the Working Group Industry 4.0 was presented.^[8]. This working group was headed by Siegfried Dais (Robert Bosch GmbH) and Henning Kagermann (German Academy of Science and Engineering).

As Industry 4.0 principles have been applied by companies they have sometimes been re-branded, for example the aerospace parts manufacturer Meggitt PLC has branded its own Industry 4.0 research project M4. ^[9]

Design principles

There are four design principles in Industry 4.0. These principles support companies in identifying and implementing Industry 4.0 scenarios.^[1]

Meaning

The characteristics given for the German government's Industry 4.0 strategy are: the strong customization of products under the conditions of highly flexible (mass-) production.^[12] The required automation technology is improved by the introduction of methods of self-optimization, self-configuration,^[13] self-diagnosis, cognition and intelligent support of workers in their increasingly complex work.^[14] The largest project in Industry 4.0 as of July 2013 is the BMBF leading-edge cluster "Intelligent Technical Systems Ostwestfalen-Lippe (it's OWL)". Another major project is the BMBF project RES-COM,^[15] as well as the Cluster of Excellence "Integrative Production Technology for High-Wage Countries".^[16] In 2015, the European Commission started the international Horizon 2020 research project CREMA^[17] (Providing Cloud-based Rapid Elastic Manufacturing based on the XaaS and Cloud model) as a major initiative to foster the Industry 4.0 topic.

Effects

In June 2013, consultancy firm McKinsey^[18] released an interview featuring an expert discussion between executives at Robert Bosch – Siegfried Dais (Partner of the Robert Bosch Industrietreuhand KG) and Heinz Derenbach (CEO of Bosch Software Innovations GmbH) – and McKinsey experts. This interview addressed the prevalence of the Internet of Things in manufacturing and the consequent technology-driven changes which promise to trigger a new industrial revolution. At Bosch, and generally in Germany, this phenomenon is referred to as Industry 4.0. The basic principle of Industry 4.0 is that by connecting machines, work pieces and systems, businesses are creating intelligent networks along the entire value chain that can control each other autonomously.

Some examples for Industry 4.0 are machines which can predict failures and trigger maintenance processes autonomously or self-organized logistics which react to unexpected changes in production.

According to Dais, "it is highly likely that the world of production will become more and more networked until everything is interlinked with everything else". While this sounds like a fair assumption and the driving force behind the Internet of Things, it also means that the complexity of production and supplier networks will grow enormously. Networks and processes have so far been limited to one factory. But in an Industry 4.0 scenario, these boundaries of individual factories will most likely no longer exist. Instead, they will be lifted in order to interconnect multiple factories or even geographical regions.

There are differences between a typical traditional factory and an Industry 4.0 factory. In the current industry environment, providing high-end quality service or product with the least cost is the key to success and industrial factories are trying to achieve as much performance as possible to increase their profit as well as their reputation. In this way, various data sources are available to provide worthwhile information about different aspects of the factory. In this stage, the utilization of data for understanding current operating conditions and detecting faults and failures is an important topic to research. e.g. in production, there are various commercial tools available to provide overall equipment effectiveness (OEE) information to factory management in order to highlight the root causes of problems and possible faults in the system. In contrast, in an Industry 4.0 factory, in addition to condition monitoring and fault diagnosis, components and systems are able to gain self-awareness and self-predictiveness, which will provide management with more insight on the status of the factory. Furthermore, peer-to-peer comparison and fusion of health information from various components provides a precise health prediction in component and system levels and forces factory management to trigger required maintenance at the best possible time to reach just-in-time maintenance and gain near-zero downtime.^[19]

During EDP Open [https://expresso.sapo.pt/inciativaseprodutos/edp-open-innovation/2018-10-18-Dias-de-Energia-o-caminho-faz-se-passeando#gs.AsfMTFQ Innovation] conducted in Oct 2018 at Lisbon, Portugal, Industry 4.0 conceptualization was extended by Sensfix B.V. a Dutch company with introduction of M2S terminology. It essentially is characterizing upcoming service industry to cater to millions of machines, managed by the machines themselves, fortunately using Artificial intelligence developed by humans!

Challenges

Role of big data and analytics

Modern information and communication technologies like cyber-physical system, big data analytics and cloud computing, will help early detection of defects and production failures, thus enabling their prevention and increasing productivity, quality, and agility benefits that have significant competitive value.

Big data analytics consists of 6Cs in the integrated Industry 4.0 and cyber physical systems environment.

In this scenario and in order to provide useful insight to the factory management, data has to be processed with advanced tools (analytics and algorithms) to generate meaningful information. Considering the presence of visible and invisible issues in an industrial factory, the information generation algorithm has to be capable of detecting and addressing invisible issues such as machine degradation, component wear, etc. in the factory floor.^[21]^[22]

Impact of Industry 4.0

The aerospace industry has sometimes been characterized as "too low volume for extensive automation" however Industry 4.0 principles have been investigated by several aerospace companies, technologies have been developed to improve productivity where the upfront cost of automation cannot be justified, one example of this is the aerospace parts manufacturer Meggitt PLC's project, M4. ^[25]

The discussion of how the shift to Industry 4.0, especially digitalization, will affect the labour market is being discussed in Germany under the topic of Work 4.0.^[26]

Technology road map for Industry 4.0

A "road map" enables whomsoever in industry to directly realize each move and what act need to be accomplish, who needs to make them and when. This method is decoded into a project plan, defining the characteristics of activity in each of the accompanying stages of formation. Considering an internationalized world, the need to actualize development strategies that can secure the sustainable competitiveness of establishments is the main issue. It is in this topic that Industry 4.0 road map grants itself as a visually pictured clear trail to boost the competitiveness of organizations.

The key benefits of technology road mapping

See also

References

1. ^¹²Hermann, Pentek, Otto, 2016: Design Principles for Industrie 4.0 Scenarios, accessed on 4 May 2016
2. ^Jürgen Jasperneite:Was hinter Begriffen wie Industrie 4.0 steckt in Computer & Automation, 19 December 2012 accessed on 23 December 2012
3. ^Kagermann, H., W. Wahlster and J. Helbig, eds., 2013: Recommendations for implementing the strategic initiative Industrie 4.0: Final report of the Industrie 4.0 Working Group
4. ^Heiner Lasi, Hans-Georg Kemper, Peter Fettke, Thomas Feld, Michael Hoffmann: Industry 4.0. In: Business & Information Systems Engineering 4 (6), pp. 239-242
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8. ^Industrie 4.0 Plattform Last download on 15. Juli 2013
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13. ^[https://www.youtube.com/watch?v=JtC3DAfLTxw Selbstkonfiguierende Automation für Intelligente Technische Systeme], Video, last download on 27. Dezember 2012
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18. ^{{cite web|author1=Markus Liffler |author2=Andreas Tschiesner |url=http://www.mckinsey.com/insights/business_technology/the_internet_of_things_and_the_future_of_manufacturing |title=The Internet of Things and the future of manufacturing | McKinsey & Company |website=Mckinsey.com |date=6 January 2013 |accessdate=2016-11-30}}
19. ^{{cite journal|title=Challenges and Requirements for the Application of Industry 4.0: A Special Insight with the Usage of Cyber-Physical System|journal=Chinese Journal of Mechanical Engineering|volume=30|issue=5|pages=1050–1057|doi=10.1007/s10033-017-0164-7|year = 2017|last1 = Mueller|first1 = Egon|last2=Chen|first2=Xiao-Li|last3=Riedel|first3=Ralph}}
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21. ^{{cite journal|last1=Lee|first1=Jay|last2=Bagheri|first2=Behrad|last3=Kao|first3=Hung-An|title=Recent Advances and Trends of Cyber-Physical Systems and Big Data Analytics in Industrial Informatics|journal=IEEE Int. Conference on Industrial Informatics (INDIN) 2014|date=2014|url=https://www.researchgate.net/publication/266375284|doi=10.13140/2.1.1464.1920}}
22. ^{{cite journal|last1=Lee|first1=Jay|last2=Lapira|first2=Edzel|last3=Bagheri|first3=Behrad|last4=Kao|first4=Hung-an|title=Recent advances and trends in predictive manufacturing systems in big data environment|journal=Manufacturing Letters|volume=1|issue=1|pages=38–41|doi=10.1016/j.mfglet.2013.09.005|date=October 2013}}
23. ^{{cite web|url=http://www.imscenter.net/IMS_news/cincinnati-mayor-proclaimed-cincinnati-to-be-industry-4-0-demonstration-city|title=Cincinnati Mayor Proclaimed "Cincinnati to be Industry 4.0 Demonstration City"|last=|first=|date=|website=Imscenter.net|access-date=2016-07-30}}
24. ^{{cite web|author=Anil K. Rajvanshi|url=http://www.thequint.com/business/2016/02/24/india-can-gain-by-leapfrogging-into-fourth-industrial-revolution |title=India Can Gain By Leapfrogging Into Fourth Industrial Revolution |publisher=The Quint |date=24 February 2016 |accessdate=2016-11-30}}
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26. ^Federal Ministry of Labour and Social Affairs of Germany (2015). Re-Imagining Work: White Paper Work 4.0.
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