Assessing Product Reliability_6

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8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? Several simple models can be used to calculate system failure rates, starting with failure rates for failure modes within individual system components This section deals with models and methods that apply to non-repairable components and systems. Models for failure rates (and not repair rates) are described. The next section covers models for (repairable) system reliability growth. We use the Competing Risk Model to go from component failure modes to component failure rates. Next we use the Series Model to go from components to assemblies and systems. These models assume independence and "first failure mode to reach failure causes both the component and the system to fail". If some components are "in parallel", so that the system can survive one (or possibly more) component failures, we have the parallel or redundant model. If an assembly has n identical components, at least r of which must be working for the system to work, we have what is known as the r out of n model. The standby model uses redundancy like the parallel model, except that the redundant unit is in an off-state (not exercised) until called upon to replace a failed unit. This section describes these various models. The last subsection shows how complex systems can be evaluated using the various models as building blocks. http://www.itl.nist.gov/div898/handbook/apr/section1/apr18.htm [5/1/2006 10:41:49 AM] 8.1.8.1. Competing risk model 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8.1.8.1. Competing risk model Use the competing risk model when the failure mechanisms are independent and the first mechanism failure causes the component to fail Assume a (replaceable) component or unit has k different ways it can fail. These are called failure modes and underlying each failure mode is a failure mechanism. The Competing Risk Model evaluates component reliability by "building up" from the reliability models for each failure mode. The following 3 assumptions are needed: 1. Each failure mechanism leading to a particular type of failure (i.e., failure mode) proceeds independently of every other one, at least until a failure occurs. 2. The component fails when the first of all the competing failure mechanisms reaches a failure state. 3. Each of the k failure modes has a known life distribution model Fi(t). The competing risk model can be used when all three assumptions hold. If Rc(t), Fc(t), and hc(t) denote the reliability, CDF and failure rate for the component, respectively, and Ri(t), Fi(t) and hi(t) are the reliability, CDF and failure rate for the i-th failure mode, respectively, then the competing risk model formulas are: http://www.itl.nist.gov/div898/handbook/apr/section1/apr181.htm (1 of 2) [5/1/2006 10:41:50 AM] 8.1.8.1. Competing risk model Multiply reliabilities and add failure rates Think of the competing risk model in the following way: All the failure mechanisms are having a race to see which can reach failure first. They are not allowed to "look over their shoulder or sideways" at the progress the other ones are making. They just go their own way as fast as they can and the first to reach "failure" causes the component to fail. Under these conditions the component reliability is the product of the failure mode reliabilities and the component failure rate is just the sum of the failure mode failure rates. Note that the above holds for any arbitrary life distribution model, as long as "independence" and "first mechanism failure causes the component to fail" holds. When we learn how to plot and analyze reliability data in later sections, the methods will be applied separately to each failure mode within the data set (considering failures due to all other modes as "censored run times"). With this approach, the competing risk model provides the glue to put the pieces back together again. http://www.itl.nist.gov/div898/handbook/apr/section1/apr181.htm (2 of 2) [5/1/2006 10:41:50 AM] 8.1.8.2. Series model 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8.1.8.2. Series model The series model is used to go from individual components to the entire system, assuming the system fails when the first component fails and all components fail or survive independently of one another The Series Model is used to build up from components to sub-assemblies and systems. It only applies to non replaceable populations (or first failures of populations of systems). The assumptions and formulas for the Series Model are identical to those for the Competing Risk Model, with the k failure modes within a component replaced by the n components within a system. Add failure rates and multiply reliabilities in the Series Model When the Series Model assumptions hold we have: The following 3 assumptions are needed: 1. Each component operates or fails independently of every other one, at least until the first component failure occurs. 2. The system fails when the first component failure occurs. 3. Each of the n (possibly different) components in the system has a known life distribution model Fi(t). with the subscript S referring to the entire system and the subscript i referring to the i-th component. Note that the above holds for any arbitrary component life distribution models, as long as "independence" and "first component failure causes the system to fail" both hold. The analogy to a series circuit is useful. The entire system has n components in series. http://www.itl.nist.gov/div898/handbook/apr/section1/apr182.htm (1 of 2) [5/1/2006 10:41:50 AM] 8.1.8.2. Series model The system fails when current no longer flows and each component operates or fails independently of all the others. The schematic below shows a system with 5 components in series "replaced" by an "equivalent" (as far as reliability is concerned) system with only one component. http://www.itl.nist.gov/div898/handbook/apr/section1/apr182.htm (2 of 2) [5/1/2006 10:41:50 AM] 8.1.8.3. Parallel or redundant model 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8.1.8.3. Parallel or redundant model The parallel model assumes all n components that make up a system operate independently and the system works as long as at least one component still works Multiply component CDF's to get the system CDF for a parallel model The opposite of a series model, for which the first component failure causes the system to fail, is a parallel model for which all the components have to fail before the system fails. If there are n components, any (n-1) of them may be considered redundant to the remaining one (even if the components are all different). When the system is turned on, all the components operate until they fail. The system reaches failure at the time of the last component failure. The assumptions for a parallel model are: 1. All components operate independently of one another, as far as reliability is concerned. 2. The system operates as long as at least one component is still operating. System failure occurs at the time of the last component failure. 3. The CDF for each component is known. For a parallel model, the CDF Fs(t) for the system is just the product of the CDF's Fi(t) for the components or Rs(t) and hs(t) can be evaluated using basic definitions, once we have Fs(t). The schematic below represents a parallel system with 5 components and the (reliability) equivalent 1 component system with a CDF Fs equal to the product of the 5 component CDF's. http://www.itl.nist.gov/div898/handbook/apr/section1/apr183.htm (1 of 2) [5/1/2006 10:41:50 AM] 8.1.8.3. Parallel or redundant model http://www.itl.nist.gov/div898/handbook/apr/section1/apr183.htm (2 of 2) [5/1/2006 10:41:50 AM] 8.1.8.4. R out of N model 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8.1.8.4. R out of N model An r out of n model is a system that survives when at least r of its components are working (any r) An "r out of n" system contains both the series system model and the parallel system model as special cases. The system has n components that operate or fail independently of one another and as long as at least r of these components (any r) survive, the system survives. System failure occurs when the (n-r+1)th component failure occurs. When r = n, the r out of n model reduces to the series model. When r = 1, the r out of n model becomes the parallel model. We treat here the simple case where all the components are identical. Formulas and assumptions for r out of n model (identical components): 1. All components have the identical reliability function R(t). 2. All components operate independently of one another (as far as failure is concerned). 3. The system can survive any (n-r) of the components failing. The system fails at the instant of the (n-r+1)th component failure. Formula for an r out of n system where the components are identical System reliability is given by adding the probability of exactly r components surviving to time t to the probability of exactly (r+1) components surviving, and so on up to the probability of all components surviving to time t. These are binomial probabilities (with p = R(t)), so the system reliability is given by: Note: If we relax the assumption that all the components are identical, then Rs(t) would be the sum of probabilities evaluated for all possible terms that could be formed by picking at least r survivors and the corresponding failures. The probability for each term is evaluated as a product of R(t)'s and F(t)'s. For example, for n = 4 and r = 2, the system http://www.itl.nist.gov/div898/handbook/apr/section1/apr184.htm (1 of 2) [5/1/2006 10:41:51 AM] 8.1.8.4. R out of N model reliability would be (abbreviating the notation for R(t) and F(t) by using only R and F) Rs = R1R2F3F4 + R1R3F2F4 + R1R4F2F3 + R2R3F1F4 + R2R4F1F3 + R3R4F1F2 + R1R2R3F4 + R1R3R4F2 + R1R2R4F3 + R2R3R4F1 + R1R2R3R4 http://www.itl.nist.gov/div898/handbook/apr/section1/apr184.htm (2 of 2) [5/1/2006 10:41:51 AM] 8.1.8.5. Standby model 8. Assessing Product Reliability 8.1. Introduction 8.1.8. How can you evaluate reliability from the "bottom-up" (component failure mode to system failure rate)? 8.1.8.5. Standby model The Standby Model evaluates improved reliability when backup replacements are switched on when failures occur. A Standby Model refers to the case in which a key component (or assembly) has an identical backup component in an "off" state until needed. When the original component fails, a switch turns on the "standby" backup component and the system continues to operate. Identical backup Standby model leads to convolution formulas In other words, Tn = t1 + t2+ ... + tn, where each ti has CDF F(t) and Tn has a CDF we denote by Fn(t). This can be evaluated using convolution formulas: In the simple case, assume the non-standby part of the system has CDF F(t) and there are (n-1) identical backup units that will operate in sequence until the last one fails. At that point, the system finally fails. The total system lifetime is the sum of n identically distributed random lifetimes, each having CDF F(t). In general, convolutions are solved numerically. However, for the special case when F(t) is the exponential model, the above integrations can be solved in closed form. http://www.itl.nist.gov/div898/handbook/apr/section1/apr185.htm (1 of 2) [5/1/2006 10:41:52 AM]
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