Product Maintainability Design Method and Support Tool Based on Feature Model
Author(s)
Yufeng DING
ABSTRACT
Maintainability is an important character which is given by product design process. The maintainability design criteria and measure index used in product maintainability analysis are summarized and discussed in this paper. A product maintainability design method is studied by integrating the product feature model, maintainability design criteria with measure index. Product feature model can be built on the basis of the product feature library quickly. Product feature library for steam turbine design is created by using SolidWorks design library origination structure. A methodology which supports the design and development of product maintainability design support tool (PMDSTs) is put forward. The function of PMDSTs is designed by using UML (Unified Modeling Language) use case diagram, it is developed by using VC++ 6.0. The maintainability analysis application case of steam turbine-generator system is given at last.
Maintainability is an important character which is given by product design process. The maintainability design criteria and measure index used in product maintainability analysis are summarized and discussed in this paper. A product maintainability design method is studied by integrating the product feature model, maintainability design criteria with measure index. Product feature model can be built on the basis of the product feature library quickly. Product feature library for steam turbine design is created by using SolidWorks design library origination structure. A methodology which supports the design and development of product maintainability design support tool (PMDSTs) is put forward. The function of PMDSTs is designed by using UML (Unified Modeling Language) use case diagram, it is developed by using VC++ 6.0. The maintainability analysis application case of steam turbine-generator system is given at last.
Cite this paper
nullY. DING, "Product Maintainability Design Method and Support Tool Based on Feature Model," Journal of Software Engineering and Applications, Vol. 2 No. 3, 2009, pp. 165-172. doi: 10.4236/jsea.2009.23024.
nullY. DING, "Product Maintainability Design Method and Support Tool Based on Feature Model," Journal of Software Engineering and Applications, Vol. 2 No. 3, 2009, pp. 165-172. doi: 10.4236/jsea.2009.23024.
References
[1] http://www.barringer1.com/jul01prb.htm. [2] B. Abdullah, M. S. Yusoff, and Z. M. Ripin, “Integration of design for modularity and design for assembly to enhance product maintainability,” Proceddings of 1st International Con-ference 7th AUN/SEED-Net Fieldwise seminar on Manufac-turing and Material processing, pp. 263–269, University Ma-laya, 2006. [3] C. A. Slavila, C. Decreuse, and M. Ferney, “Fuzzy approach for maintainability evaluation in the design process,” Concurrent Engineering, Vol. 13, No. 4, pp. 291–300, 2005. [4] A. Coulibaly, R. Houssin and B. Mutel, “Maintainability and safety indicators at design stage for mechanical products,” Computers in Industry, Vol. 59, No. 5, pp 438–449, 2008. [5] Y. F. Ding and B.Y. Sheng, “Study on product maintenance integration model,” Submit to The IEEE International Confer-ence on Industrial Engineering and Engineering Management (IEEM) 2009. [6] M. Pecht, “Product reliability, maintainability, supportability handbook,” CRC Press, Boca Raton, Florida, pp. 191–192, 1995. [7] B. S. Dhillon, “Engineering maintainability,” Eelservier, 2008. [8] H. Reiche, “Life cycle cost in reliability and maintainability of electronic systems,” Computer Science Press, Potomac, Mary-land, pp. 3–23.1980. [9] W. Kue, V. R. Parsad, F. A. Tillman and C. Hwang, “Optimal reliability design: Fundamentals and applications,” Cambridge University Press, 2001. [10] A. M. Sarhan, “Reliability equivalence factors of a general series–parallel system,” Reliability Engineering and System Safety, Vol. 94, No. 2, pp.229–236, 2009. [11] SolidWorks Corporation. “Solidworks 2000 API help,” 2006. [12] Stapelberg and R. Frederick, “Handbook of reliability, avail-ability, maintainability and safety in engineering design,” Springer, 2009.
[1] http://www.barringer1.com/jul01prb.htm. [2] B. Abdullah, M. S. Yusoff, and Z. M. Ripin, “Integration of design for modularity and design for assembly to enhance product maintainability,” Proceddings of 1st International Con-ference 7th AUN/SEED-Net Fieldwise seminar on Manufac-turing and Material processing, pp. 263–269, University Ma-laya, 2006. [3] C. A. Slavila, C. Decreuse, and M. Ferney, “Fuzzy approach for maintainability evaluation in the design process,” Concurrent Engineering, Vol. 13, No. 4, pp. 291–300, 2005. [4] A. Coulibaly, R. Houssin and B. Mutel, “Maintainability and safety indicators at design stage for mechanical products,” Computers in Industry, Vol. 59, No. 5, pp 438–449, 2008. [5] Y. F. Ding and B.Y. Sheng, “Study on product maintenance integration model,” Submit to The IEEE International Confer-ence on Industrial Engineering and Engineering Management (IEEM) 2009. [6] M. Pecht, “Product reliability, maintainability, supportability handbook,” CRC Press, Boca Raton, Florida, pp. 191–192, 1995. [7] B. S. Dhillon, “Engineering maintainability,” Eelservier, 2008. [8] H. Reiche, “Life cycle cost in reliability and maintainability of electronic systems,” Computer Science Press, Potomac, Mary-land, pp. 3–23.1980. [9] W. Kue, V. R. Parsad, F. A. Tillman and C. Hwang, “Optimal reliability design: Fundamentals and applications,” Cambridge University Press, 2001. [10] A. M. Sarhan, “Reliability equivalence factors of a general series–parallel system,” Reliability Engineering and System Safety, Vol. 94, No. 2, pp.229–236, 2009. [11] SolidWorks Corporation. “Solidworks 2000 API help,” 2006. [12] Stapelberg and R. Frederick, “Handbook of reliability, avail-ability, maintainability and safety in engineering design,” Springer, 2009.