Smart manufacturing explained

Smart manufacturing[1] is a broad category of manufacturing that employs computer-integrated manufacturing, high levels of adaptability and rapid design changes, digital information technology, and more flexible technical workforce training.[2] Other goals sometimes include fast changes in production levels based on demand,[3] [1] optimization of the supply chain,[3] efficient production and recyclability.[4] In this concept, as smart factory has interoperable systems, multi-scale dynamic modelling and simulation, intelligent automation, strong cyber security, and networked sensors.

The broad definition of smart manufacturing covers many different technologies. Some of the key technologies in the smart manufacturing movement include big data processing capabilities, industrial connectivity devices and services, and advanced robotics.[5]

Big data processing

Smart manufacturing leverages big data analytics to optimize complex production processes and enhance supply chain management.[6] Big data analytics refers to a method for gathering and understanding large data sets in terms of what are known as the three V's, velocity, variety and volume. Velocity informs the frequency of data acquisition, which can be concurrent with the application of previous data. Variety describes the different types of data that may be handled. Volume represents the amount of data.[7] Big data analytics allows an enterprise to use smart manufacturing to predict demand and the need for design changes rather than reacting to orders placed.

Some products have embedded sensors, which produce large amounts of data that can be used to understand consumer behavior and improve future versions of the product.[8] [9] [10]

Advanced robotics

Advanced industrial robots, also known as smart machines, operate autonomously and can communicate directly with manufacturing systems. In some advanced manufacturing contexts, they can work with humans for co-assembly tasks.[11] By evaluating sensory input and distinguishing between different product configurations, these machines are able to solve problems and make decisions independent of people. These robots are able to complete work beyond what they were initially programmed to do and have artificial intelligence that allows them to learn from experience. These machines have the flexibility to be reconfigured and re-purposed. This gives them the ability to respond rapidly to design changes and innovation, which is a competitive advantage over more traditional manufacturing processes.[12] An area of concern surrounding advanced robotics is the safety and well-being of the human workers who interact with robotic systems. Traditionally, measures have been taken to segregate robots from the human workforce, but advances in robotic cognitive ability have opened up opportunities, such as cobots, for robots to work collaboratively with people.[13]

Cloud computing allows large amounts of data storage or computational power to be rapidly applied to manufacturing, and allow a large amount of data on machine performance and output quality to be collected. This can improve machine configuration, predictive maintenance, and fault analysis. Better predictions can facilitate better strategies for ordering raw materials or scheduling production runs.

3D printing

As of 2019, 3D printing is mainly used in rapid prototyping, design iteration, and small-scale production. Improvements in speed, quality, and materials could make it useful in mass production[14] [15] and mass customization.

However, 3D printing developed so much in recent years that it is no longer used just as technology for prototyping. 3D printing sector is moving beyond prototyping especially it is becoming increasingly widespread in supply chains. The industries where digital manufacturing with 3D printing is the most seen are automotive, industrial and medical. In the auto industry, 3D printing is used not only for prototyping but also for the full production of final parts and products. 3D printing has also been used by suppliers and digital manufacturers coming together to help fight COVID-19.[16]

3D printing allows to prototype more successfully, thus companies are saving time and money as significant volumes of parts can be produced in a short period. There is great potential for 3D printing to revolutionise supply chains, hence more companies are using it. The main challenge that 3D printing faces is the change of people's mindset. Moreover, some workers will need to re-learn a set of new skills to manage 3D printing technology.[16]

Eliminating workplace inefficiencies and hazards

Smart manufacturing can also be attributed to surveying workplace inefficiencies and assisting in worker safety. Efficiency optimization is a huge focus for adopters of "smart" systems, which is done through data research and intelligent learning automation. For instance operators can be given personal access cards with inbuilt Wi-Fi and Bluetooth, which can connect to the machines and a Cloud platform to determine which operator is working on which machine in real time.[17] An intelligent, interconnected 'smart' system can be established to set a performance target, determine if the target is obtainable, and identify inefficiencies through failed or delayed performance targets.[18] In general, automation may alleviate inefficiencies due to human error. And in general, evolving AI eliminates the inefficiencies of its predecessors.

As robots take on more of the physical tasks of manufacturing, workers no longer need to be present and are exposed to fewer hazards.[19]

Impact of Industry 4.0

Industry 4.0 is a project in the high-tech strategy of the German government that promotes the computerization of traditional industries such as manufacturing. The goal is the intelligent factory (Smart Factory) that is characterized by adaptability, resource efficiency, and ergonomics, as well as the integration of customers and business partners in business and value processes. Its technological foundation consists of cyber-physical systems and the Internet of Things.[20]

This kind of "intelligent manufacturing" makes a great use of:

European Roadmap "Factories of the Future" and German one "Industrie 4.0″ illustrate several of the action lines to undertake and the related benefits. Some examples are:

Statistics

The Ministry of Economy, Trade and Industry in South Korea announced on 10 March 2016 that it had aided the construction of smart factories in 1,240 small and medium enterprises, which it said resulted in an average 27.6% decrease in defective products, 7.1% faster production of prototypes, and 29.2% lower cost.[21]

See also

External links

Notes and References

  1. Lu. Yuqian. Xu. Xun. Wang. Lihui. July 2020. Smart manufacturing process and system automation – A critical review of the standards and envisioned scenarios. Journal of Manufacturing Systems. en. 56. 312–325. 10.1016/j.jmsy.2020.06.010. 225557967.
  2. Smart manufacturing, manufacturing intelligence and demand-dynamic performance. Computers & Chemical Engineering. 2012-12-20. 145–156. 47. FOCAPO 2012. 10.1016/j.compchemeng.2012.06.037. Jim. Davis. Thomas. Edgar. James. Porter. John. Bernaden. Michael. Sarli.
  3. SMLC 2011
  4. Web site: Emerging Global Trends in Advanced Manufacturing. Shipp. Stephanie S.. Stephanie Shipp. March 2012. Emerging Global Trends in Advanced Manufacturing. Institute for Defense Analysis . dead . https://web.archive.org/web/20120606110910/https://www.wilsoncenter.org/sites/default/files/Emerging_Global_Trends_in_Advanced_Manufacturing.pdf . 2012-06-06 . 2020-04-12.
  5. Web site: On the Journey to a Smart Manufacturing Revolution . www.industryweek.com . 2016-02-17 . 2015-12-30.
  6. Web site: Smart Manufacturing Systems Design and Analysis. Rachuri. Sudarsan. February 4, 2014. National Institute of Standards and Technology . February 16, 2016.
  7. Book: 2014-12-01. 918–922. 10.1109/IEEM.2014.7058772. J.. Leveling. M.. Edelbrock. B.. Otto. 2014 IEEE International Conference on Industrial Engineering and Engineering Management . Big data analytics for supply chain management . 978-1-4799-6410-9. 31872187.
  8. Yang . Chen . Shen . Weiming . Wang . Xianbin . The Internet of Things in Manufacturing: Key Issues and Potential Applications . IEEE Systems, Man, and Cybernetics Magazine . January 2018 . 4 . 1 . 6–15 . 10.1109/MSMC.2017.2702391. 42651835 .
  9. How Smart, Connected Products Are Transforming Competition. Porter. Michael E.. November 2014. Harvard Business Review. April 2016.
  10. Web site: Building Smarter Manufacturing With The Internet of Things (IoT). 2014. IT World Canada. Lopez Research . 2020-04-12.
  11. W. . Wang . R. . Li . Y. . Chen . Z. . Diekel . Y. . Jia . Facilitating Human-Robot Collaborative Tasks by Teaching-Learning-Collaboration From Human Demonstrations. IEEE Transactions on Automation Science and Engineering. en-US. 16. 2. 640–653. 10.1109/tase.2018.2840345. 1545-5955. 2019. free.
  12. Web site: Robotic Systems for Smart Manufacturing. US Department of Commerce. www.nist.gov. EN-US. 2016-03-04. October 2013.
  13. Book: Springer Handbook of Robotics. Bicchi. Antonio. Peshkin. Michael A.. Colgate. J. Edward. Safety for Physical Human–Robot Interaction . 2008-01-01. Springer Berlin Heidelberg. 9783540239574. Siciliano. Bruno . 1335–1348. en. Khatib. Oussama Khatib. 10.1007/978-3-540-30301-5_58.
  14. Web site: Zimmermann . Stefan . Industry 4.0 – 3D Printing in Manufacturing Industries . March 26, 2018 . Atos Blog . Atos SE . 2019-06-09.
  15. Web site: Industry 4.0 is About More Than Data: 3D Printing in Manufacturing . Hughes . Andrew . Mar 23, 2017 . Digital Transformation and Operational Excellence Blog . LNS Research . 2019-06-09.
  16. Wilson . Georgia . The evolution of 3D printing in manufacturing . May 16, 2020 . Manufacturing Global . BizClick Medial Limited . 2021-06-04.
  17. Web site: ThingTrax. ThingTrax Connected Manufacturing . London. https://web.archive.org/web/20170412085445/http://www.thingtrax.com/devicenew/. 2017-04-12. dead . 2020-04-12.
  18. Jung. Kiwook. 2015-03-16. Mapping Strategic Goals and Operational Performance Metrics for Smart Manufacturing Systems. Procedia Computer Science. 44. 44 p.184–193. 184–193. 10.1016/j.procs.2015.03.051. free.
  19. Web site: From Smart Manufacturing to Manufacturing Smart. Louchez. Alain. January 6, 2014. www.automationworld.com. Automation World. 2016-03-04.
  20. Web site: Smart Manufacturing? Industry 4.0? What's It All About?. Jacinto. Joan. July 31, 2014. The Vault - Siemens Totally Integrated Automation.
  21. News: Smart Factories Improving Productivity of SMEs . Jung Min-hee . March 11, 2016.