基于公理设计的产品可靠性要求实现方法

杨德真; 任羿; 王自力; 肖静

基于公理设计的产品可靠性要求实现方法

北京航空航天大学可靠性与系统工程学院, 北京 100191

详细信息

中图分类号: N945.17
计量
- 文章访问数: 1113
- HTML全文浏览量: 140
- PDF下载量: 482
- 被引次数: 0
出版历程
- 收稿日期: 2013-03-15
- 网络出版日期: 2014-01-20

Design-in of reliability through axiomatic design

School of Reliability and Systems Engineering, Beijing University of Aeronautics and Astronautics, Beijing 100191, China

摘要

摘要: 针对可靠性设计要求难以系统、全面落实到产品设计方案的问题，提出了一种基于公理设计的产品可靠性要求实现方法.首先，应用公理设计原理进行产品初步设计，从而确定其功能需求，并针对各项功能的保持要求进一步扩展功能保持需求（扩展的功能保持需求构成功能保持域，该域包含于功能域），进而系统导出参数化的可靠性设计方案；其次，根据功能保持需求扩展或优化设计参数，构建考虑可靠性设计要求的域映射模型，并给出应用独立公理进行方案评价的方法.同时，以温度传感器设计为例贯穿全文，验证了所提出方法的可行性和有效性.
- 可靠性 /
- 独立公理 /
- 公理设计 /
- 功能保持域 /
- 温度传感器
Abstract: To completely meet the requirements of reliability design in the product designing, an axiom-based designing-in reliability approach was proposed. In light of the axiomatic design principles, products were designed preliminarily to establish their functional requirements, so that according to these the preservation requirements were augmented (the functions preserving requirements constitute a functional requirement preserving domain that is included in functional domain), which derived the parameterized solution for reliability design systematically. Subsequently, the design parameters were augmented and optimized to achieve the functions preserving requirements. Mapping model of the augmented functional domain, the physical domain was established. And a solutions evaluation approach based on independence axiom was proposed. Being exemplified by the design of a temperature sensor, the present study demonstrates that all approaches are feasible, efficient, and could be applied in real engineering scenarios.
- reliability /
- independence axiom /
- axiomatic design /
- functional requirement preserving domain(FRPD) /
- temperature sensor

HTML全文

参考文献(21)

[1]	GEIA-STD-0009 Reliability program standard for systems design, development, and manufacturing[S]
[2]	Pecht M.Product reliability, maintainability, and supportability handbook[M].2nd ed.New York:Taylor & Francis Group, LLC, 2009
[3]	Yan Chuliang, Liu Kege.Theory of economic life prediction and reliability assessment of aircraft structure[J].Chinese Journal of Aeronautics, 2011, 24(2):164-170
[4]	Zhao Changxiao, Chen Yao, Wang Hailiang, et al.Reliability analysis of aircraft condition monitoring network using an enhanced BDD algorithm[J].Chinese Journal of Aeronautics, 2012, 25(6):925-930
[5]	Akay D, Kulak O, Henson B.Conceptual design evaluation using interval type-2 fuzzy information axiom[J].Computers in Industry, 2011, 62:138-146
[6]	Yao Jun, Xu Mingge, Zhong Weiqiang.Research of step-down accelerated degradation data assessment method of a certain type of missile tank[J].Chinese Journal of Aeronautics, 2012, 25(6): 917-924
[7]	Gong Qi, Zhang Jianguo, Tan Chunlin, et al.Neural networks combined with importance sampling techniques for reliability evaluation of explosive initiating device[J].Chinese Journal of Aeronautics, 2012, 25(2):208-215
[8]	Li Jinghui, Mosleh Ali, Kang Rui.Likelihood ratio gradient estimation for dynamic reliability application[J].Reliability Engineering and System Safety, 2011, 96(12):1667-1679
[9]	Suh N P.The principles of design[M].NY:Oxford University Press, 1990
[10]	Suh N P.Design and operation of large systems[J].Journal of Manufacturing Systems, 1995, 14(3):203-213
[11]	Suh N P.Axiomatic design:advances and applications[M].NY:Oxford University Press, 2001
[12]	Suh N P, Do S H.Axiomatic design of software systems[J].CIPR Annuals-Manufacturing Technology, 2000, 49(1): 95-100
[13]	Kulak O, Kahraman C.Multi-attribute comparison of advanced manufacturing systems using fuzzy vs crisp axiomatic design approach[J].International Journal of Production Economics, 2005, 95:415-424
[14]	Helander M G.Using design equations to identify sources of complexity in human-machine interaction[J].Theoretical Issues in Ergonomics Science, 2007, 8(2):123-146
[15]	Nakao1 M, Kobayashi N, Hamada K, et al.Decoupling executions in navigating manufacturing processes for shortening lead time and its implementation to an unmanned machine shop[J].IRP Annals-Manufacturing Technology, 2007, 56(1):171-174
[16]	Kulak O, Cebi S, Kahraman C.Applications of axiomatic design principles:a literature review[J].Expert Systems with Applications, 2010, 37:6705-6717
[17]	Tang Dunbing, Zhang Guangjun, Dai Sheng.Design as integration of axiomatic design and design structure matrix[J].Robotics and Computer-Integrated Manufacturing, 2009, 25(3): 610-619
[18]	Celika M, Cebib S, Kahramanb C, et al.Application of axiomatic design and TOPSIS methodologies under fuzzy environment for proposing competitive strategies on Turkish container ports in maritime transportation network[J].Expert Systems with Applications, 2009, 36(3):4541-4557
[19]	Ahmed R, Koo J M, Jeong Y H.Design of safety-critical systems using the complementarities of success and failure domains with a case study[J].Reliability Engineering and System Safety, 2011, 96:201-209
[20]	Schnetzler M J, Sennheiser A, Schonsleben P.A decomposition-based approach for the development of a supply chain strategy[J].International Journal of Production Economics, 2007, 105:21-42
[21]	Field M O, Anderson G W.Development and testing of a multiplexed temperature sensor[M].New Jersey:Proquest, Umi Dissertation Publishing, 2012