Abstract
Remanufacturing, a process returning used products to at least as good as new condition, is increasingly recognized as an important part of the circular economy. Since returned used components for remanufacturing have varying conditions and different defects, remanufacturing is very time-consuming and labor-intensive. There is an urgent need to reuse knowledge generated from existing parts remanufacturing to rapidly create sound process planning for the new arrival of used parts. A hybrid method combing rough set (RS) and cased-based reasoning (CBR) for remanufacturing process planning is presented in this paper. RS is employed for features reduction and rapid determination of features’ weights automatically, and CBR is utilized to calculate the similarity of process cases to identify the most suitable solution effectively from case database. The application of the methodology is demonstrated in an example of remanufacturing process for a saddle guide. The results indicated that the quality of remanufactured products has been improved significantly. The method has been implemented in a prototype system using Visual Studio 2010 and Microsoft SQL Server2008. The results suggested that the hybrid RS–CBR system is feasible and effective for the rapid generation of sound process planning for remanufacturing.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- B :
-
An equivalence relation on \(\Omega \)
- C :
-
A set of condition features
- \(C_{k}\) :
-
The \(k{\mathrm{th}}\) condition feature
- \(C_i^X \) :
-
The \(i{\mathrm{th}}\) features of case X
- \(C_i^Y \) :
-
The \(i{\mathrm{th}}\) features of case Y
- D :
-
A decision features set
- f :
-
Information function
- H :
-
Case number
- \(L_{j}\) :
-
Value of \(j{\mathrm{th}}\) feature of reconditioning process
- m :
-
The number of features
- M:
-
Maximum assignment value of the feature
- \(M_{j}\) :
-
Name of \(j{\mathrm{th}}\) feature of reconditioning process
- \(N_{i}\) :
-
Name of \(i{\mathrm{th}}\) essential feature
- \(P_{j}\) :
-
The\( j{\mathrm{th}}\) process case
- q :
-
Each feature
- Q :
-
Vector set of features of reconditioning process
- \(Q_{j}\) :
-
The \(j{\mathrm{th}}\) feature of reconditioning process
- r :
-
An arbitrary feature
- R :
-
Vector set of essential features of used cores
- \(R_{i}\) :
-
The \(i{\mathrm{th}}\) essential feature
- S :
-
Corresponding solution
- U :
-
A nonempty and finite set of objects
- \(V_{i}\) :
-
Value of \(i{\mathrm{th}}\) essential feature
- \(V_{q}\) :
-
Value set of q
- \(w(C_k )\) :
-
The feature weights of condition feature \(C_k \)
- \(w_{R_i}\) :
-
Weight of \(i{\mathrm{th}}\) essential feature
- \(w_{Q_j}\) :
-
Weight of \(j{\mathrm{th}}\) feature of reconditioning process
- \(W_D (C_k)\) :
-
The significance of condition feature \(C_k \)
- X :
-
New case
- Y :
-
Source case
- \(\psi \) :
-
Proportional factor
- \(\Omega \) :
-
A finite set of features
- \(\varepsilon \left( {P_j } \right) \) :
-
The confidence of the \(j{\mathrm{th}}\) process case
References
Aamodt, A., & Plaza, E. (1994). Case-based reasoning: Foundational issues, methodological variations, and system approaches. AI Communications, 7(1), 39–59.
Aksoy, H. K., & Gupta, S. M. (2011). Optimal management of remanufacturing systems with server vacations. The International Journal of Advanced Manufacturing Technology, 54(9–12), 1199–1218.
Beaubouef, T., Ladner, R., & Petry, F. (2004). Rough set spatial data modeling for data mining. International Journal of Intelligent Systems, 19(7), 567–584.
Chang, C. G. (2014). The research of urban disaster emergency scheduling mechanism and method based on case-based reasoning. Shenyang: Northeastern University Press.
Chen, Z. F., Zhang, F., Jiang, D. Z., Ni, L. L., & Wang, H. Y. (2004). The filtering method for X-ray digital image of chest based on multi-resolution and rough set. Chinese Journal of Biomedical Engineering, 23(6), 486–489.
Finnie, G., & Sun, Z. (2003). R5 model for case-based reasoning. Knowledge-Based Systems, 16(1), 59–65.
Gao, J., Chen, X., & Zheng, D., (2010). Remanufacturing oriented adaptive repair system for worn components. In 5th international conference on responsive manufacturing: Green manufacturing (ICRM 2010) (pp. 13–18). IET.
Ghazalli, Z., & Murata, A. (2011). Development of an AHP–CBR evaluation system for remanufacturing: End-of-life selection strategy. International Journal of Sustainable Engineering, 4, 2–15.
Gómez-Vallejo, H. J., Uriel-Latorre, B., Sande-Meijide, M., Villamarín-Bello, B., Pavóna, R., Fdez-Riverola, F., et al. (2016). A case-based reasoning system for aiding detection and classification of nosocomial infections. Decision Support Systems, 84, 104–116.
Guide, J., D. R, V., Souza, G. C., Van Wassenhove, L. N., & Blackburn, J. D. (2006). Time value of commercial product returns. Management Science, 52(8), 1200–1214.
Jensen, R., & Shen, Q. (2004). Fuzzy rough attribute reduction with application to web categorization. Fuzzy Sets Systems, 141(3), 469–485.
Ji, S., Shen, X., & Shen, C. (2005). Application of CBR retrieval method to weather forecast based on rough set. Computer Engineering and Design, 26(11), 2898–2901.
Jia, X. Y., Shang, L., Zhou, B., & Yao, Y. Y. (2015). Generalized attribute reduct in rough set theory. Knowledge-Based Systems, 91, 204–218.
Jiang, Y. J., Chen, J., & Ruan, X. Y. (2006). Fuzzy similarity-based rough set method for case-based reasoning and its application in tool selection. International Journal of Machine Tools and Manufacture, 46, 107–113.
Jiang, X. L., Jiang, Z. G., Zhang, H., Zhang, X. G., & Zhu, S. (2013). A case-based reasoning model for evaluating remanufacturability of used parts and its application. Modern Manufacturing Engineering, 12, 6–9.
Jiang, Z. G., Zhou, F., Sutherland, J. W., Zhang, H., & Zhang, X. G. (2014). Development of an optimal method for remanufacturing process plan selection. The International Journal of Advanced Manufacturing Technology, 72(9–12), 1551–1558.
Kernabaum, S., Heyer, S., Chiotellis, S., & Seliger, G. (2009). Process planning for IT-equipment remanufacturing. CIRP Journal of Manufacturing Science and Technology, 2, 13–20.
Kin, S. M., Ong, S. K., & Nee, A., (2014). Remanufacturing process planning. International scientific committee of the 21st CIRP conference on life cycle engineering (Vol. 15, pp. 189–194). CIRP.
Li, Q., Liu, X. H., & Liu, Y. H. (2012). Rapid design system for the column of hydraulic support based on CBR. Modular Machine Tool and Automatic Manufacturing Technique, 7, 39–45.
Li, C., Tang, Y., Li, C., & Li, L. (2013). A modeling approach to analyze variability of remanufacturing process routing. IEEE Transactions on Automation Science and Engineering, 10(1), 86–98.
Li, Z., Zhou, X. H., Liu, W., & Kong, C. P. (2015). A geometry search approach in case-based tool reuse for mould manufacturing. The International Journal of Advanced Manufacturing Technology, 79(5–8), 757–768.
Lv, W. X., & Yang, Q. L. (2013). Predicting outcome of construction disputes litigation based on CBR-RBR model. Computer Engineering and Applications, 23, 1–9.
Maciá-Pérez, F., Berna-Martinez, J. V., Oliva, A. F., & Ortega, M. A. A. (2015). Algorithm for the detection of outliers based on the theory of rough sets. Decision Support Systems, 75, 63–75.
Muhammad, S. R., & Usman, q. (2016). An incremental dependency calculation technique for feature selection using rough sets. Information Sciences, 343–344, 41–65.
Ni, Y. C., Yang, J. G., & Lv, Z. J. (2006). Raw cotton yarn Tenacity’s rule extraction based on rough set theory. Progress in Textile Science and Technology, 6, 65–70.
Ozturk, P., & Tidemann, A. (2014). A review of case-based reasoning in cognition-action continuum: A step toward bridging symbolic and non-symbolic artificial intelligence. Knowledge Engineering Review, 29, 51–57.
Parkinson, H. J., & Thompson, G. (2004). Systematic approach to the planning and execution of product remanufacture. Journal of Process Mechanical Engineering, 218, 1–13.
Pawlak, Z. (2002). Rough sets and intelligent data analysis. Information Sciences, 147(1–4), 1–12.
Qi, J., Hu, J., & Peng, Y. H. (2016). Hybrid weighted mean for CBR adaptation in mechanical design by exploring effective, correlative and adaptative values. Computers in Industry, 75, 58–66.
Renzis, A. D., Garriga, M., Flores, A., & Cechich, A. (2016). Case-based reasoning for web service discovery and selection. Electronic Notes in Theoretical Computer Science, 321, 89–112.
Shen, Q., & Chouchoulas, A. (2002). A rough-fuzzy approach for generating classification rules. Pattern Recognition, 35(11), 2425–2438.
Song, C., Guan, X., Zhao, Q., & Ho, Y. C. (2005). Machine learning approach for determining feasible plans of a remanufacturing system. IEEE Transactions on Automation Science and Engineering, 2(3), 262–275.
Teunter, R. H., & Flapper, S. D. P. (2011). Optimal core acquisition and remanufacturing policies under uncertain core quality fractions. European Journal of Operational Research, 210(2), 241–248.
Tian, G. D., Chu, J. W., Hu, H. S., & Li, H. L. (2014). Technology innovation system and its integrated structure for automotive components remanufacturing industry development in China. Journal of Cleaner Production, 85, 419–432.
Veerakamolmal, P., & Gupta, S. M. (2002). A case-based reasoning approach for automating disassembly process planning. Journal of Intelligent Manufacturing, 13(1), 47–60.
Wei, S., Cheng, D., Sundin, E., & Tang, O. (2015). Motives and barriers of the remanufacturing industry in China. Journal of Cleaner Production, 94, 340–351.
Wen, H., Liu, M., Liu, C., & Liu, C. (2015). Remanufacturing production planning with compensation function approximation method. Applied Mathematics and Computation, 256, 742–753.
Xiong, J. Q., Rao, Y. X., Liu, H. S., & Zhang, M. K. (2007). Remanufacturing intelligent CAPP system for repairing parts. Journal of Nanchang University (Engineering and Technology), 29(1), 29–31.
Zhang, T. Z., Chu, J. W., Wang, X. P., & Cui, P. F. (2011). Development pattern and enhancing system of automotive components remanufacturing industry in China. Resources Conservation and Recycling, 55, 613–622.
Zhang, X. H., Deng, Z. H., Liu, W., & Cao, H. (2013). Combining rough set and case based reasoning for process conditions selection in camshaft grinding. Journal of Intelligent Manufacturing, 24(2), 211–224.
Zhang, J. B., Li, T. R., & Chen, H. M. (2014). Composite rough sets for dynamic data mining. Information Science, 257, 81–100.
Zhou, F., Jiang, Z. G., Zhang, H., & Wang, Y. (2014). A case-based reasoning method for remanufacturing process planning. Discrete Dynamics in Nature and Society, 2014, 168631. doi:10.1155/2014/168631.
Acknowledgments
The work described in this paper was supported by the National Natural Science Foundation of China (51205295, 51405075), Wuhan Youth Chenguang Program of Science and Technology (2014070404010214). These financial contributions are gratefully acknowledged.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Jiang, Z., Jiang, Y., Wang, Y. et al. A hybrid approach of rough set and case-based reasoning to remanufacturing process planning. J Intell Manuf 30, 19–32 (2019). https://doi.org/10.1007/s10845-016-1231-0
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10845-016-1231-0