A Three-State Space Modeling Method for Aircraft System Reliability Design

IF 2.1 3区工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Machines Pub Date : 2023-12-25 DOI:10.3390/machines12010013

Yao Wang, Fengtao Wang, Yue Feng, S. Cao

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引用次数: 0

Abstract

Reliability is an inherent attribute of a system through optimal system design. However, during the aircraft system development process, the reliability evaluation and system function design efforts are often disconnected, leading to a divide between reliability experts and system designers in their work schedule. This disconnect results in an inefficient aircraft system reliability optimization process, known as the “two-skin” phenomenon. To address this issue, a three-state space model is proposed. Firstly, an analysis was conducted on the relationship between the system function architecture developed by the system designers and the reliability evaluation performed by the reliability experts. Secondly, based on the principle of function flow, the state of failure was categorized into “physical failure” and “non-physical failure”. Additionally, a new state of “function loss” was introduced as the third state for the system, in addition to the traditional states of “normal” and “faulty”. Thirdly, through the state of “Function loss”, an effective integration of system fault modes and function modes was achieved, leading to an optimized system reliability model. A three-state space modeling method was then developed by transforming the system function architecture into a system reliability model. Finally, this new model was applied to an aircraft’s rudder and fly-by-wire control system. The results demonstrate that the function architecture at the design stage of the system can be accurately transformed into the new three-state space model. The structure aligns closely with the function architecture and can be effectively utilized in quantitative system reliability calculations. In this way, the process of ensuring system reliability can be seamlessly integrated into the system optimization design process. This integration alleviates the issue of disjointed work between reliability experts and system designers, leading to a more streamlined and efficient aircraft system optimization process.

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飞机系统可靠性设计的三态空间建模方法

通过优化系统设计，可靠性是系统的固有属性。然而，在飞机系统研制过程中，可靠性评估和系统功能设计工作往往脱节，导致可靠性专家和系统设计人员在工作进度安排上出现分歧。这种脱节导致飞机系统可靠性优化过程效率低下，即所谓的 "两张皮 "现象。针对这一问题，提出了一种三态空间模型。首先，分析了系统设计人员制定的系统功能架构与可靠性专家进行的可靠性评估之间的关系。其次，根据功能流原理，将故障状态分为 "物理故障 "和 "非物理故障"。此外，除了传统的 "正常 "和 "故障 "状态外，还引入了新的 "功能丧失 "状态，作为系统的第三种状态。第三，通过 "功能损失 "状态，实现了系统故障模式和功能模式的有效整合，从而优化了系统可靠性模型。然后，通过将系统功能架构转化为系统可靠性模型，开发出一种三态空间建模方法。最后，将这一新模型应用于飞机的方向舵和电传操纵系统。结果表明，系统设计阶段的功能结构可以准确地转化为新的三态空间模型。该结构与功能架构紧密结合，可有效用于系统可靠性的定量计算。这样，确保系统可靠性的过程就可以无缝集成到系统优化设计过程中。这种整合缓解了可靠性专家和系统设计人员之间工作脱节的问题，从而使飞机系统优化过程更加精简高效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Machines Multiple-

CiteScore

3.00

自引率

26.90%

发文量

1012

审稿时长

11 weeks

期刊介绍： Machines (ISSN 2075-1702) is an international, peer-reviewed journal on machinery and engineering. It publishes research articles, reviews, short communications and letters. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. Full experimental and/or methodical details must be provided. There are, in addition, unique features of this journal: *manuscripts regarding research proposals and research ideas will be particularly welcomed *electronic files or software regarding the full details of the calculation and experimental procedure - if unable to be published in a normal way - can be deposited as supplementary material Subject Areas: applications of automation, systems and control engineering, electronic engineering, mechanical engineering, computer engineering, mechatronics, robotics, industrial design, human-machine-interfaces, mechanical systems, machines and related components, machine vision, history of technology and industrial revolution, turbo machinery, machine diagnostics and prognostics (condition monitoring), machine design.