Browse > Article
http://dx.doi.org/10.1016/j.ijnaoe.2017.11.004

Design of reliability critical system using axiomatic design with FMECA  

Goo, Bongeun (Dept. of Mechanical Engineering, KAIST)
Lee, Joohee (Dept. of Mechanical Engineering, KAIST)
Seo, Suwon (Dept. of Mechanical Engineering, KAIST)
Chang, Daejun (Dept. of Mechanical Engineering, KAIST)
Chung, Hyun (Department of Naval Architecture & Ocean Engineering, Chungnam National University)
Publication Information
International Journal of Naval Architecture and Ocean Engineering / v.11, no.1, 2019 , pp. 11-21 More about this Journal
Abstract
In product design, the initial design stage is being increasingly emphasized because it significantly influences the successive product development and production stages. However, for larger and more complex products, it is very difficult to accurately predict product reliability in the initial design stage. Various design methodologies have been proposed to resolve this issue, but maintaining reliability while exploring design alternatives is yet to be achieved. Therefore, this paper proposes a methodology for conceptual design considering reliability issues that may arise in the successive detailed design stages. The methodology integrates the independency of axiomatic design and the hierarchical structure of failure mode, effects, and criticality analysis (FMECA), which is a technique widely used to analyze product reliability. We applied the proposed methodology to a liquefied natural gas fuel gas supply system to verify its effectiveness in the reliability improvement of the design process.
Keywords
Axiomatic design; Failure mode, effects, and criticality analysis (FMECA); Reliability; LNG fuel gas supply system;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Abdelkader, B., Daoud, A.K., 1994. A state of the art review of FMEA/FMECA. Int. J. Reliab. Qual. Saf. Eng. 1 (4), 515-543.   DOI
2 Arcidiacono, G., 1997. FMECA application to a continuous rolling machine for sole leather. In: International Conference on Engineering Design, vol. 25, pp. 647-650.
3 Arcidiacono, G., 2000. Axiomatic design for reliability. ATA Mot. Car Eng. J. 53, 309-315.
4 Suh, N.P., 1998. Axiomatic design theory for systems. Res. Eng. Des. 10, 189-209.   DOI
5 Suh, N.P., 1990. Principles of Design. Oxford University Press, New York.
6 Seung, J.R., Kosuke, I., 2003. Using cost based FMEA to enhance reliability and serviceability. Intell. Maint. Syst. 17, 179-188.
7 Arcidiacono, G., Delogu, M., 2001. The integration of reliability techniques as an aid to the design optimization of an earth moving machine. In: ASME International, Proceedings of International ME 2001 Congress and Exposition, New York (USA).
8 Arcidiacono, G., Campatelli, G., 2004. Reliability improvement of a diesel engine using the FMETA approach. Qual. Reliab. Eng. Int. 20, 143-154.   DOI
9 Shin, G.S., Kim, Y.I., Park, G.J., 2007. Decoupling process of a coupled design in axiomatic design using the Triz. Proc. Korean Soc. Mech. Eng. 31, 77-88.   DOI
10 Shin, G.S., Park, G.J., 2004. Conceptual design of a beam splitter for the laser marker using axiomatic design and TRIZ. J. Korean Soc. Precis. Eng. 21, 166-173.
11 Shirwaiker, R., Okudan, G., 2008. Triz and axiomatic design: a review of case-studies and a proposed synergistic use. J. Intell. Manuf. 19, 33-47.   DOI
12 Seo, S.W., 2012. A Pump-free Pressure Boosting System for LNG Fuel Gas Supply System. MS Thesis. Dept. of Mechanical Engineering, KAIST. http://library.kaist.ac.kr/thesis02/2012/2012M020104341_S1Ver2.pdf.
13 Seo, S.W., Chu, B.S., Noh, Y.Y., Jang, W.H., Lee, S.I., Seo, Y.T., Chang, D.J., 2014. An economic evaluation of operating expenditures for LNG fuel gas supply systems onboard. Ships Offshore Struct. 11 (2), 213-223.
14 Telsang, M., 2006. Industrial Engineering and Production Management. S Chand & Co Ltd, New Delhi.
15 Wuersig, G.M., 2014. LNG as Ship Fuel. DNV GL, Hamburg.
16 Rausand, M., Hoyland, A., 2004. System Reliability Theory Models, Statistical Methods, and Applications, second ed. John Wiley & Sons, Inc., Hoboken, New Jersey.
17 Yang, K., Zhang, H., 2000. A comparison of TRIZ and axiomatic design. In: First International Conference on Axiomatic Design, vol. 1, pp. 235-242.
18 An, C., Lee, D., Son, Y., Lee, H.,S., 2010. A study for reliability improvement of belt type door system using FMECA. Korean Soc. Railw. 13, 58-64.
19 Chen, Z., Tan, R., 2006. Study on integrating application method for AD and TRIZ. IFIP Int. Fed. Inf. Process. 207, 421-432.
20 Goo, B.G., Ahn, J.G., Kwak, J.M., Chang, D.J., Chung, H., 2011. A methodology to improve the reliability of the design: axiomatic design with FMECA. In: Proceedings of the Society of CAD/CAM Engineers Conference, vol. 1, pp. 717-731.
21 Heo, G.Y., Lee, T.S., Do, S.H., 2010. Interactive system design using the complementarity of axiomatic design and fault tree analysis. Nucl. Eng. Technol. 39, 51-62.   DOI
22 Lee, K.S., Choi, J.H., 2009. A conceptual design of new automatic bicycle transmission by TRIZ and design axiom. J. Korean Soc. Mech. Eng. 33, 269-275.   DOI
23 IEEE Std 352, 1987. IEEE Guide for General Principles of Reliability Analysis of Nuclear Power Generating Station Safety Systems. The Institute of Electrical and Electronics.
24 Joseph, A., Childs, A.M., 1999. A modified FMEA tool for use in identifying and addressing common cause failure risks in industry. Annu. Rel. Maint. Sym 1, 19-24.
25 Kulak, O., Kahraman, C., Oztaysi, B., Tanyas, M., 2005. Multi-attribute information technology project selection using fuzzy axiomatic design. J. Enterp. Inf. Manag. 18, 275-288.   DOI
26 Park, G.J., 2007. Introduction to Mechanical Design. Dong-Myeong Press, Paju, Republic of Korea.
27 Pickard, K., Muller, P., Bertsche, B., 2005. Multiple failure mode and effects analysis - an approach to risk assessment of multiple failures with FMEA. Rel. Maint. Sym 1, 457-462.
28 Zigmund, B., Rafi, P., Pavel, G., 2005. Bouncing failure analysis (BFA): the unified FTA-FMEA methodology. Annu. Rel. Maint. Sym 1, 463-467.