AHP‐IFM Target: An Innovative Method to Define Reliability Target in an Aerospace Prototype Based on Analytic Hierarchy Process

It is generally believed that the reliability of a mechanical system is determined by its composition. The system operates properly when all of its components do not fail. Based on this assumption, the reliability of the system can be represented by the reliability of its components. A problem arises when applying this hypothesis to a system containing motion mechanisms. There is a phenomenon in motion mechanism that the components do not happen structural failure (we call it “Type I failure”) and joint failure (we call it “Type II failure”), but the function of the mechanism cannot meet the requirements (we call it “Type III failure”). A reliability allocation method, which synthetically considers the composition and Type III failure modes of the motion mechanism, is proposed to solve this problem. A relative dispersion factor is introduced to describe the failure dependence of components and is proposed to calculate the complexity and criticality. A series system reliability allocation model considering three types of failure modes is established. Finally, using an airplane gear door lock mechanism as an example, a comparative analysis of the system reliability allocation results with and without considering Type III failure modes is made. The allocation results show the component reliability value without considering Type III failure modes is less than that when considering them, which will increase the system hazards. The result considering Type III failure modes is more reasonable than that from the traditional method.

Section: Figurementioning

confidence: 59%

A reliability allocation method of mechanism considering system performance reliability

Zhang

Song

2019

“…However, if such a relationship is not available especially in the early design stage, the system reliability requirement can be proportionally assigned to the corresponding subsystems or components according to their weights. Typical reliability allocation methods using the allocation weights include Bracha method, Aeronautical Radio Inc. (ARINC) method, Advisory Group on Reliability of Electronic Equipment (AGREE) method, the feasibility of objectives method, Karmiol method, the maximal entropy ordered weighted averaging method and the integrated factors method . Commonly used factors consist of complexity, failure frequency, state‐of‐the‐art technology, criticality, environmental conditions.…”

Section: Introductionmentioning

confidence: 99%

“…Typical reliability allocation methods using the allocation weights include Bracha method, 3 Aeronautical Radio Inc. (ARINC) method, 4 Advisory Group on Reliability of Electronic Equipment (AGREE) method, 5 the feasibility of objectives method, 6 Karmiol method, 7 the maximal entropy ordered weighted averaging method 8 and the integrated factors method. 9 Commonly used factors consist of complexity, failure frequency, state-of-the-art technology, criticality, environmental conditions. They are usually considered in different combinations to calculate the reliability allocation weight.…”

Section: Introductionmentioning

confidence: 99%

Reliability Allocation for Series‐Parallel Systems subject to Potential Propagated Failures

Cao

Liu

Fang

2020

To analyze the dependent failures in the early stage of system development, this paper considers the potential propagated failures in the reliability allocation process. Factors which can be used to not only measure the component importance but also to reflect the influence brought by propagated failures are proposed. Specifically, cooperative game theory is introduced to explore how the propagated failures affect the failure severity level. Failure rates are obtained by using the Alpha Factor Model with the consideration of dependence among components. Reliability improvement rate is also developed to proportionally assign the target improvement of system reliability to the corresponding components. Furthermore, reliability allocation frameworks for series, parallel and series‐parallel systems are designed respectively to make the proposed model meet a wide range of applications. An illustrative example of a hydraulic cooling system is presented to show how the proposed approach is applied. The allocation results demonstrate that the proposed method can achieve a valid reliability improvement with the minimum error.

“…Furthermore, the parameters in conventional fuzzy FTA models cannot exactly signify the increasingly complex knowledge‐based systems. Secondly, due to the expert knowledge acquisition process, the domain expert board usually establishes diverse experience and knowledge from one another and produces various types of knowledge information including complete/incomplete, precise/imprecise, and known/unknown because of its cross functional and multidisciplinary nature . The latter shortages can be handled by the interval 2‐tuple linguistic terms method.…”

Section: Introductionmentioning

confidence: 99%

“…Secondly, due to the expert knowledge acquisition process, the domain expert board usually establishes diverse experience and knowledge from one another and produces various types of knowledge information including complete/incomplete, precise/imprecise, and known/unknown because of its cross functional and multidisciplinary nature. 27 The latter shortages can be handled by the interval 2-tuple linguistic terms method. The 2-tuple intuitionistic fuzzy numbers (IFNs) and many of its considerable extension can overcome the aforementioned limitation.…”

mentioning

confidence: 99%

Footprint of knowledge acquisition improvement in failure diagnosis analysis

Yazdi

2018

Fault tree analysis (FTA) as an effective and efficient risk assessment tool are widely used to analyze the reliability of a complex system. In this context, FTA can properly improve the safety performance of the system by preventing an event which may lead to occurrence of a catastrophic accident. However, traditional FTA is still suffering from dynamic structure demonstration and importantly epistemic uncertainty processing. In this study, a novel methodology is introduced using Bayesian updating mechanism to deal with dynamic structure and 2‐tuple fuzzy set named as intuitionistic fuzzy numbers are employed to cope with subjectivity of uncertainty processing. Accordingly, the most critical system components which affect the system reliability are recognized by using an appropriate sensitivity analysis method. The proposed methodology is then applied on a real case study application (a brake fluid filling system) in order to examine the effectiveness and feasibility of the approach. The results illustrated that the new methodology can have enough benefits for diagnosing the systems' faults compared with listing approaches of safety and reliability analysis. In terms of empirical case study, “electromotor failure” was evaluated as the second most critical basic event in conventional‐based approaches, whereas in the novel methodology “high pressure liquefied material” was recognized as the second one.