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Wdrażanie procedur lockout/tagout w systemach produkcyjnych Przemysłu 4.0

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Warianty tytułu
EN
Application of lockout/tagout procedures in production systems of Industry 4.0
Języki publikacji
PL
Abstrakty
PL
Celem badań było opracowanie wytycznych i materiałów szkoleniowych wspomagających wdrażanie procedur LOTO w przemyśle 4.0. Przeprowadzone analizy systemów wytwórczych Przemysłu 4.0 wykazały, że wymagania dotyczące procedur LOTO różnią się od procedur stosowanych w systemach klasycznych. Opracowane wytyczne i materiały szkoleniowe zostały zweryfikowane podczas szkolenia pilotażowego. Średnia wartość liczby punktów w skali Likerta przekracza 4,4 wskaźnik I-CVI przeważnie przyjmuje wartość 1, a najmniejsza jego wartość to 0,86. Analiza statystyczna z wykorzystaniem testu t – studenta potwierdziła, że wytyczne i materiały szkoleniowe mają doskonałą trafność merytoryczną na poziomie ufności 0,05. Dotyczy to ich zawartości, użyteczności oraz kompleksowości i kompletności.
EN
The aim of the research was to develop guidelines and training materials to support the implementation of LOTO procedures in Industry 4.0. The analysis of manufacturing systems of Industry 4.0 showed that the requirements for LOTO procedures differ from those used in classical systems. The developed guidelines and training materials were verified during the pilot training. The mean value of the Likert scale score exceeds 4.4. The I-CVI index is mostly 1 and the lowest value is 0.86. Statistical analysis using Student's t-test confirmed that the guidelines and training materials have excellent content validity at the 0.05 confidence level. This applies to their content, usefulness, comprehensiveness and completeness.
Czasopismo
Rocznik
Strony
137--148
Opis fizyczny
Bibliogr. 37 poz., rys.
Twórcy
  • Central Institute for Labour Protection (Centralny Instytut Ochrony Pracy – PIB)
Bibliografia
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  • 4. Badiane, A., Nadeau, S., Kenné, J.P., Polotski,V. Optimizing production while reducing machinery Lockout/Tagout circumvention possibilities. Journal of Quality in Maintenance Engineering, 22(2), 2014: pp.188-201.
  • 5. Badri, A., Boudreau-Trudel, B., Saâdeddine Souissi, A. Occupational health and safety in the industry 4.0 era: A cause for major concern? Safety Science 109 (2018) 403–411.
  • 6. Brettel, M., Klein, M., Friederichsen, N. The relevance of manufacturing flexibility in the context of Industrie 4.0. In: 48th CIRP Conference on Manufacturing Systems, 2016. Procedia CIRP 41. pp. 105–110.
  • 7. Bücker, I., Hermann, M., Pentek, T., Otto, B. Towards a methodology for Industrie 4.0 transformation. Lect. Notes Business Inform. Process. 2017. 255, 209–221.
  • 8. Bulzacchelli, M.T., Vernick, J.S., Sorock, G.S., Webster, D.W., Lees, P.S.J. Circumstances of fatal Lockout/Tagout-related injuries in manufacturing. American Journal of Industrial Medicine, 51, 2008, pp. 728-734.
  • 9. Campbell, T. LOTO remains problematic. Professional Safety, Vol 48(3), 2003: pp. 48-51.
  • 10. Consortium II. Fact Sheet, 2013. Dostępne z: http://www.iiconsortium.org/ docs/IIC_ FACT _ SHEET.pdf.
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  • 14. Dźwiarek, M., Łempiński T., Światowski. M. “Effectiveness investigation of the correlation algorithms applied in a Smart ID Card system to monitor the use of PPE”. in: Safety and Reliability – Safe Societies in a Changing World. Stein Haugen at. All (eds.) © Taylor & Francis Group, London, ISBN 978-1-351-17466-4, (2018): s.1965 – 1971.
  • 15. Dźwiarek, M., Strawiński, T., Łempiński, T., Światowski, M. „The simulation of the use of personal protective equipment in investigation of Smart ID Card system efficiency”, Journal of KONBIN. 43 (2017): s. 163 – 178, DOI 10.1515/jok-2017-0045.
  • 16. Hermann M., Pentek T., Otto B. Design principles for Industrie 4.0 scenarios, A Literature Review, in: 49th Hawaii International Conference on System Sciences (HICSS), IEEE, (2016), pp. 3928–3937.
  • 17. Kagermann H., Wahlster W., Helbig J. Securing the future of German manufacturing industry. Recommendations for implementing the strategic initiative Industrie 4.0, (2013). Final report of the Industrie 4.0 Working Group.
  • 18. Kaivo-Oja, J., Virtanen, P., Jalonen, H., Stenvall, J. “The effects of the internet of things and big data to organizations and their knowledge management practices”. Lect. Notes Business Inform. Process. 224 (2015): s. 495–513.
  • 19. Kiel, D., Arnold, C., Collisi, M., Voigt, K.-I. The impact of the industrial internet of things on established business models. In: 25th International Association for Management of Technology Conference 2016, Proceedings: Technology – Future Thinking. pp. 673–695.
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  • 21. Lynn, M.R. Determination and quantification of content validity. Nurse Research (1986), Vol. 35, ISSU 6, pp. 382–385.
  • 22. Mehrgani, B.E., Nadeau, S., Kenné, J.P. optimal Lockout/Tagout, preventive maintenance, human error and production policies. Journal of Quality in Maintenance Engineering, 20(4), 2014: pp.453-470.
  • 23. OSHA. Control of hazardous energy (Lockout/Tagout), U.S. Department of Labor & Occupational Safety and Health Administration, 2002. https://www.osha.gov/controlhazardous-energy/
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  • 25. Polit, D.F., Beck, C.T. The content validity index: Are you sure you know what’s being reported? Critique and recommendations. Res. Nurs. Health 2006, Vol. 29, pp. 489–497.
  • 26. Ravi, M., Sridharan, P., Senthilkumar V.K. Implementation strategy of lock out and tag out (LOTO) electrical systems for paper industry. International Journal of Applied Science and Engineering, 6(1), 2018: 01-10. DOI: 10.30954/2322-0465.1.2018.1.
  • 27. Reuter, M., Oberc, H., Wannöffel, M., Kreimeier, D., Klippert, J., Pawlicki, P., Kuhlenkötter, B. Learning factories ‘Trainings as an Enabler of Proactive Workers’ Participation Regarding Industrie 4.0. Procedia Manuf. 2017, 9, 354–360.
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  • 29. Samuel C. Yamin, L. Parker, Rodney Stanley. Self-audit of lockout/tagout in manufacturing workplaces: A pilot study. Am J Ind Med. 2017; 60:504–509.
  • 30. Simons, S., Abé, P., Neser, S. Learning in the AutFab – The fully automated Industrie 4.0. Learning factory of the University of Applied Sciences Darmstadt. Procedia Manuf. 9, 2017, 81–88.
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  • 37. ZHANG Hongjie, LIU Zhen-tang. Application of Lockout & Tagout System in the Coalmine. Industry. Procedia Engineering 26 (2011) 2065 – 2069
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-f5853146-801d-4b6b-92ba-af9371bf75e2
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