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EML 4550: Engineering Design Methods . Probability and Statistics in Engineering Design: Reliability, FMEA, FEMCA. Class Notes Hyman: Chapter 5. System reliability. Reliability of Series Systems. 0.99. 0.85. 0.98. For constant per-unit failure rates.
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EML 4550: Engineering Design Methods Probability and Statistics in Engineering Design: Reliability, FMEA, FEMCA Class Notes Hyman: Chapter 5
Reliability of Series Systems 0.99 0.85 0.98
For constant per-unit failure rates • Per-unit failure rate of series system is constant and equal to the sum of the component failure rates
Reliability of Parallel Systems 0.99 0.85 0.98
4 6 5 Example • Find the system reliability of the following combinational system with both serial and parallel arrangements. Assume all sub-systems have a reliability of 0.9 1 2 3
For constant per-unit failure rates(example: two systems in parallel) • System does not have constant per-unit failure rate even if components do • System reliability for parallel systems is always greater than the most reliable component • Most systems are not designed in parallel (redundancy) due to cost considerations (unless needed due to safety and life-protection considerations) • Series • Transmission line, Power train • Parallel • Multiple airplane engines, Two headlights
Reliability of Large Systems • Most systems are neither parallel nor series, but a hybrid combination • Calculation of overall system reliability, however, is done following the simple principle shown before • Parallel systems are used when extremely high reliability is needed (by use of redundancy)
Cost of Reliability Total cost Minimized cost Cost due to design and manufacture Cost Cost to customer: failed products, reputation, etc.. Reliability
FTA • Fault Tree Analysis • Work from the overall system backwards towards the component level (top down approach) • Identify system fault modes and possible causes • Assign probabilities to each fault mode • Build a ‘tree’ and use it to evaluate overall reliability, availability, etc. • A Fault Tree Analysis Handbook (from US Nuclear Regulatory Commission) • The basic elements of a fault tree in pp. 34-44
FMEA and FMECA • Failure Modes and Effects Criticality Analysis • Work from the component level and identify all possible fault modes at the component level (a team effort and bottom-up approach) • Assess criticality of each component fault and its effects on overall system performance • Build a ‘table’ with all fault modes, assign probabilities, severity, determine interactions, possible actions, etc. • Three factors for failure analysis: The severity of a failure (Sev), The probability of occurrence of the failure (Occ), The likelihood of detecting the failure (Det) • RPN (risk priority number)=(Sev)(Occ)(Det): quantify overall risk for a specific failure • Use the table to asses overall reliability (see an example)
Step-by-step Procedures • The design is broken down into components with a block diagram showing their interrelations. • Identify functions for each individual components (1st column) • List the potential failure modes (2nd column) • Describe the consequences/effects due to the failure (3rd column); frequently coming from customers, regulation, and/or experienced designers Use the severity table to determine the numerical value (Sev). • Identify potential causes (root cause analysis, column 6) Find Occurrence value (Occ) • Determine how one can detect the potential failure (colume 8) Find detectability (Det) • Calculate the risk priority number (RPN) • Determine the corrective actions to remove potential failures. Assign responsibility to appropriate person(s) for the removal of each failure. • Estimate the RPN after the corrective actions.
Implications • Incorporate availability, reliability, and maintainability on the product specification • Prepare a mathematical model to assess system reliability (e.g., FMECA) • Design with reliability and maintainability in mind • Exercise FMECA each time a design change is needed, or to explore incremental improvements to the design that may improve reliability without critically affecting functionality and cost