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Increasing the Capacity of Plant Bottlenecks by Using of Improving the Ratio of Mean Time between Failures to Mean Time to Repair

Authors: Jalal Soleimannejad, Mohammad Asadizeidabadi, Mahmoud Koorki, Mojtaba Azarpira


A significant percentage of production costs is the maintenance costs, and analysis of maintenance costs could to achieve greater productivity and competitiveness. With this is mind, the maintenance of machines and installations is considered as an essential part of organizational functions and applying effective strategies causes significant added value in manufacturing activities. Organizations are trying to achieve performance levels on a global scale with emphasis on creating competitive advantage by different methods consist of RCM (Reliability-Center-Maintenance), TPM (Total Productivity Maintenance) etc. In this study, increasing the capacity of Concentration Plant of Golgohar Iron Ore Mining & Industrial Company (GEG) was examined by using of reliability and maintainability analyses. The results of this research showed that instead of increasing the number of machines (in order to solve the bottleneck problems), the improving of reliability and maintainability would solve bottleneck problems in the best way. It should be mention that in the abovementioned study, the data set of Concentration Plant of GEG as a case study, was applied and analyzed.

Keywords: Bottleneck, Golgohar Iron Ore Mining and Industrial Company, maintainability, maintenance costs, reliability.

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[1] A. Azadeha, S.M. Asadzadehd, N. Salehib, M. Firoozic, "Condition-based maintenance effectiveness for series–parallel power generation system—A combined Markovian simulation model", Reliability Engineering & System Safety,2014, Volume 142, Pages 357–368.
[2] Ben-Daya, M., Duffuaa, S.O., Maintenance and quality: the missing link. Journal of Quality in Maintenance Engineering 1 (1), 1995, 20–26.
[3] Blischke, W.R., Murthy, D.N.P., Reliability: Modelling, Prediction and Optimization. Wiley, New York, 2000.
[4] Blischke, W.R., Murthy, D.N.P., Case Studies in Reliability and Maintenance. John Wiley and Sons Inc., Hoboken, New Jersey. 2003, pp. 351–445.
[5] raglia, M; Frosolini, M; Zammori, " Overall equipment effectiveness of a manufacturing line (OEEML)", Journal of Manufacturing Technology Management Vol.20 No.1, 2009, pp.29-8
[6] Da Silva Manuel Inacio, C; Manuel Pereira Cabrita, C; de Oliveira Matias Joao Carlos. P, "reliability maintenance: a case study concerning maintenance service costs"., Journal of Quality in Maintenance Engineering Vol.14 No.4,2008, pp.343-355.
[7] Eliashberg, J., Singpurwalla, N.D., Wilson, S.P., Calculating the reserve for a time and usage indexed warranty. Management Science 43 (7), 1997, 966–975.
[8] Gia-Shie Liu, Three m-failure group maintenance models for M/M/N unreliable queuing service systems, Computers & Industrial Engineering., Volume 62, Issue 4, 2012, Pages 1011–1024.
[9] Giorgio Baronea, , Dan M. Frangopolb , Life-cycle maintenance of deteriorating structures by multi-objective optimization involving reliability, risk, availability, hazard and cost., Structural Safety, Volume 48, May 2014, Pages 40–50,2014.
[10] Inman, R.R., Empirical evaluation of exponential and independence assumptions in queuing models of manufacturing systems. Production and Operations Management 8 (4), 409–432, 1999.
[11] Ireson, W. G., Coombs, C. F., Moss, R.Y., Handbook of Reliability Engineering and Management. McGraw-Hill, New York, 1996.
[12] Karin S. de Smidt-Destombesa, Matthieu C. van der Heijdenb, Aart van Hartenb., On the availability of a k-out-of-N system given limited spares and repair capacity under a condition based maintenance strategy., Reliability Engineering & System Safety., Volume 83, Issue 3, Pages 287–300,2004.
[13] Katila, P, "TPM principles in the flexible manufacturing systems"., Journal of Technical Report,2000.
[14] K. Das, A comparative study of exponential distribution vs Weibull distribution in machine reliability analysis in a CMS design. Computers & Industrial Engineering 54, 12–33, 2008.
[15] Koren, Y., Hu, S.J., Weber, T., Impact of manufacturing system configuration on performance. Annals of the CIRP 47, 369–372, 1998.
[16] Liberopoulos, G., Tsarouhas, P., Reliability analysis of an automated pizza processing line. Journal of Food Engineering 69 (1), 79–96, 2005.
[17] Montgomery, D.C., Introduction to Statistical Control. John Wiley and Sons Inc., New York, NY. pp. 69–85, 1985.
[18] Morse, P.M, " Queues, inventories and maintenance: the analysis of operational systems with variable demand and supply", John Wiley, 1958.
[19] Nachiappan R. M; Anantharaman N., "Evaluation of overall line effectiveness (OLE) in a continuous product line manufacturing system", Journal of Manufacturing Technology Management Vol. 17 No. 7, pp. 987-1008, 2005.
[20] Panagiotis H. Tsarouhas, Ioannis S. Arvanitoyannis, Zafiris D. Ampatzis., A case study of investigating reliability and maintainability in a Greek juice bottling medium size enterprise (MSE). Journal of Food Engineering 95, 479–488, 2009.
[21] Seifoddini, S., Djassemi, M., The effect of reliability consideration on the application of quality index. Computers and Industrial Engineering 40 (1–2), 65–77, 2001.
[22] Tsarouhas, P., Varzakas, T., Arvanitoyannis, I., Reliability and maintainability analysis of strudel production line with experimental data; a case study. Journal of Food Engineering 91, 250–259, 2009a.
[23] Tsarouhas, P., Arvanitoyannis, I., Varzakas, T., Reliability and maintainability analysis of cheese (feta) production line in a Greek medium-size company: a case study. Journal of Food Engineering 94, 233–240, 2009b.
[24] Usher, J.M., Roy, U., Parsaei, H.R., Integrated Product and Process Development. Wiley, Hoboken, NJ, 1998.
[25] Wang, Y., Jia, Y., Yu, J., Yi, S., Failure probabilistic model of CNC lathes. Reliability Engineering and System Safety 65 (1), 307–314, 1999.