Failure Mode and Effects Analysis, FMEA, is a methodology frequently used in the commercial sector to investigate the numerous causes and repercussions that could result from a failure (defects that cause the object to lose its ability to perform functions). In this research paper, we will investigate why it is useful, as well as how this strategy could be used in the context of integrated services of local and regional importance. Organizations that provide services of local and regional importance will benefit if they can predict potential problems and failures of the management infrastructure. A process FMEA study shows discrepancies that impact product safety and quality.

Stamatis, D.H. Failure mode and effect analysis: FMEA from theory to execution. Quality Press, 2003

Oprean, C., Ţîţu, M. Quality management in the knowledge-based economy and organization (in Romanian) Ed. AGIR, ISBN 978-973-720-167-6, Bucureşti, 2008.

Giannetti, C., Ransing, M. R., Ransing, R. S., Bould, D. C., Gethin, D. T., Sienz, J. Product specific process knowledge discovery using co-linearity index and penalty functions to support process FMEA in the steel industry. In Proceedings of the 44th International Conference Computer Industrial Engineering, Istanbul, Turkey, pp. 14-16, 2014.

Banduka, N., Veza, I., Bilić, B. An integrated lean approach to process failure mode and effect analysis (PFMEA): A case study from automotive industry. Advances in Production Engineering And Management, ISSN 18546250, Kragujevac, Serbia, 2016.

Kovalenko, D., Semeryagina, M. Lean production in logistics - Problems of training professional personnel in logistics in the conditions of a global competitive environment, p. 70, Kiev, 2020.

Oprean, C., Țîțu, M., Bucur, V. Global management of the knowledge-based organization (In Romanian), Ed. AGIR, ISBN 978-973-720-363-2, București, 2011.

Krejci, L., Schindlerova, V., Bucko, M., Hlavaty, I., Mician, M. The Application of PFMEA for Roller Bearings Production. Manuf Technol, 19(3), 439-45, 2019, https://doi.org/10. 21062/ujep/310.2019/a/1213-2489/MT/19/3/439

Komatina, N., Tadić, D., Aleksić, A., Banduka, N. The integrated PFMEA approach with interval type-2 fuzzy sets and FBWM: A case study in the automotive industry. Proc Inst Mech Eng D J Automob Eng, 236(6), 1201-1212 2022, https://doi.org/10.1177/09544070211034799

Höfig, K., Klein, C., Rothbauer, S., Zeller, M., Vorderer, M., Koo, C.H. A meta-model for process failure mode and effects analysis (PFMEA). In 24th IEEE International Conf on Emerging Technologies and Factory Automation (ETFA), pp. 1199-202, IEEE, 2019, https://doi.org/10.1109/ETFA.2019.8869087

Ekmekçioğlu, M., Can Kutlu, A. A fuzzy hybrid approach for fuzzy process FMEA: An application to a spindle manufacturing process. Int J Comput Intell Syst, 5(4), 611-26, 2012, https://doi.org/10.1080/18756891.2012.718104

Parsana, T.S., Patel, M.T. A case study: A process FMEA tool to enhance quality and efficiency of manufacturing industry. Bonfring Int J Ind Eng Manag Sci, 4(3), 145-52, 2014, https://doi.org/10.9756/BIJIEMS.10350

Li, Y., Kang, R., Ma, L., Li, L. Application and improvement study on FMEA in the process of military equipment maintenance. In The Proceedings of 2011 9th International Conference on Reliability, Maintainability and Safety, pp. 803-810, IEEE, 2011.

Bluvband, Z., Grabov, P. Failure analysis of FMEA. In 2009 Annual Reliability and Maintainability Symposium, pp. 344-7, IEEE, 2009.

Van Leeuwen, J.F., Nauta, M.J., De Kaste, D., Odekerken-Rombouts, Y.M.C.F., Oldenhof, M.T., Vredenbregt, M.J., Barends, D.M. Risk analysis by FMEA as an element of analytical validation. J Pharm Biomed Anal, 50(5), 1085-7, 2009, https://doi.org/10.1016/j.jpba.2009.06.049