• Rail Vehicles, Semester 2, position 4
• Industry Engineering, Semester 2, position 4
• Mašinstvo i informacione tehnologije, Semester 2, position 4

The aim of this course is to acquire the necessary knowledge and practical skills that will enable students to apply production and maintenance systems based on risk management, due to knowledge in the identification, analysis, risk assessment and decision-making on the basis of those facts.

Student after completing the course is able to: a) recognize /describe core systems, methods and strategies of terotechnology procedures b) applies terotechnology method based on risk, c) applies models RIMAP (Risk Inspection Maintenance Procedures) d) applies RCM models (Models for reliability based maintenance) in practice, and e) elect / propose appropriate solutions for the mitigation of risk. Upon successful completion of this course, students are able to choose the appropriate method, collect the data source required for the implementation of certain methods of risk management, conduct methodological procedure, conduct specific methods of processing results, critically consider and make decisions on the mitigation of risk depending on the results.

Introduction to terotechnology. Terotechnological procedures, operations and technologies. Aims and objectives of terotechnological activities. The principles of maintenance. Maintenance policy. Maintenance systems. The organizational structure of maintenance function. Maintenance methods and strategies. Maintenance methods based on risk. Maintaining the reliability - Reliability Centered Maintenance - RCM. Qualitative risk assessment. Risk-based Inspection - RBI. The concept of risk-based maintenance - RBIM. Risk Based Life Cycle Management of technical resources - RBLM. Risk Based Management - RBM. Maintenance procedures based on risk - RIMAP. Risk management tools - Pareto, Ishikawa, FMEA, FTA. Risk assessment at workplaces and in environment. Role of anthropometry in OSHA. Application of risk management in national industrial practice.

Collection and systematization of data collected in companies. Еvaluation of data on individual risks. Preliminary risk matrix. Calculation of individual riskс. Risk matrix. Preliminary evaluation of the possible scenarios of origin effects. Risk tools application - Pareto, Ishikawa, FMEA, FTA. Detailed analysis of one or more of the selected scenarios, including probability analysis to achieve them. Detailed technical analysis of possible consequences of different scenarios. The overall analysis of possible consequences and analysis in terms of insurance and reinsurance.

Enrolled semester.

Handouts from lectures and instructions for exercises. It is recommended to use other literature, especially during the exercises.

Total assigned hours: 75

New material: 20
Elaboration and examples (recapitulation): 10

Auditory exercises: 0
Laboratory exercises: 0
Calculation tasks: 15
Seminar paper: 0
Project: 15
Consultations: 0
Discussion/workshop: 0
Research study work: 0

Review and grading of calculation tasks: 2
Review and grading of lab reports: 0
Review and grading of seminar papers: 0
Review and grading of the project: 3
Test: 5
Test: 0
Final exam: 5

Activity during lectures: 0
Test/test: 25
Laboratory practice: 0
Calculation tasks: 20
Seminar paper: 0
Project: 25
Final exam: 30
Requirement for taking the exam (required number of points): 30

1. Klarin M., Ivanovic G., Stanojevic P., Raicevic R. , Principles of Terotechnological Procedures, Faculty of Mechanical Engineering, Belgrade, 1994.; 2. Smith D., Reliability, Maintainability and Risk - Practical methods for engineers, Elsevier Butterworth-Heinemann, Oxford, 2005.; 3. Zio E., AN INTRODUCTION TO THE BASICS OF RELIABlTY and RISK ANALYSIS, World Scientific Publishing Co., 2007.; Panchal, D., Chatterjee, P., Pamucar, D., & Tyagi, M. (Eds.). Reliability and Risk Modeling of Engineering Systems. Springer, 2021.; Handouts - theory and practice, 2023.