题名

Lot Sizing for Recoverable Remanufacturing Decisions with Cost, Lead Time and Carbon Dioxide Emissions

并列篇名

考量碳排放量、成本與前置時間於再製造系統之批量決策

DOI

10.29416/JMS.201810_25(4).0001

作者

蘇泰盛(Tai-Sheng Su);吳靖純(Chin-Chun Wu);黃立雯(Li-Wen Huang)

关键词

Remanufacturing Systems ; Fuzzy Theory ; Possibilistic Linear Programming ; Lead-Time ; CO_2 Emissions ; 再製造系統 ; 模糊理論 ; 可能性規劃法 ; 前置時間 ; 二氧化碳排放量

期刊名称

管理與系統

卷期/出版年月

25卷4期(2018 / 10 / 01)

页次

457 - 491

内容语文

英文
中文摘要

This work uses new and recoverable materials to mix into the remanufacturing systems. It implements a possibilistic linear programming model to provide aid in making production decisions in recyclable remanufacturing systems subject to a fuzzy environment which includes multi-component, multi-vendor, multi-source and multi-machine factors. When the related parameters are imprecise in the systems, both the trapezoidal and triangular possibility distributions are used. This work applies fuzzy theory and possibility linear programming to set the objective function, demand and CO_2 emission uncertainty. We propose a decision making model to consider the procurement of raw materials, new materials and recycled materials mixed into the remanufacturing systems with reference to the restrictions of supplier/vendor capacity, CO_2 emissions and machine yield in order to minimize total cost, lead-time and CO_2 emissions. In addition, we propose a procedure for solving the fuzzy objective functions and fuzzy constraints. To test the adequacy of model, we use a numerical example from a real case study. The results and suggestions can provide a feasible situation for production planning.
英文摘要

本研究考量新料與回收料混合之再製造系統,並建構一個可能性線性規劃模式,提供於可回收再製造系統之模糊環境進行生產決策。模式中考量多零組件、多供應商、多回收商、多料源及多機台等因素。系統中的相關參數是具模糊性,模糊參數可用梯形與三角形可能性分配來表示。本研究應用模糊理論與可能性線性規劃來表示目標函數、需求量及二氧化碳排放量的不確定性。我們也提出一個決策模式於可回收再製造系統,模式中考量新料與回收料的混合、物料供應商的採購、二氧化碳的排放量及機台良率等限制,達到最小總成本、前置時間及二氧化碳排放量的目標。此外,我們提出一個模糊目標函數和目標限制式的求解程序,為驗證模式的正確性,我們以一個實務案例之數值進行測試,研究結果和建議是適合於生產計畫使用。
主题分类 基礎與應用科學 > 統計
社會科學 > 財金及會計學
社會科學 > 管理學
参考文献
  1. Bao, X.,Tang, O.,Ji, J.(2008).Applying the Minimum Relative Entropy Method for Bimodal Distribution in a Remanufacturing System.International Journal of Production Economics,113(2),969-979.
  2. Cholette, S.,Venkat, K.(2009).The Energy and Carbon Intensity of Wine Distribution: a Study of Logistical Options for Delivering Wine to Consumers.Journal of Cleaner Production,17(16),1401-1413.
  3. Elhedhli, S.,Merrick, R.(2012).Green Supply Chain Network Design to Reduce Carbon Emissions.Transportation Research Part D,17(5),370-379.
  4. Guide, V.D.R., Jr,Jayaraman, V.,Srivastava, R.(1999).The Effect of Lead Time Variation on the Performance of Disassembly Release Mechanisms.Computers & Industrial Engineering,36(4),759-779.
  5. Hua, G.,Cheng, T. C. E.,Wang, S.(2011).Managing Carbon Footprints in Inventory Management.International Journal Production Economics,132(2),178-185.
  6. Kannan, G.,Sasikumar, P.,Devika, K.(2010).A Genetic Algorithm Approach for Solving a Closed Loop Supply Chain Model: A Case of Battery Recycling.Applied Mathematical Modelling,34(3),655-670.
  7. Kilic, H. S.,Cebeci, U.,Ayhan, M.B.(2015).Reverse Logistics System Design for the Waste of Electrical and Electronic Equipment (WEEE) in Turkey.Resources, Conservation and Recycling,95,120-132.
  8. Konstantaras, I.,Skouri, K.(2010).Lot Sizing for a Single Product Recovery System with Variable Setup Numbers.European Journal of Operational Research,203(2),326-335.
  9. Laan, E.,Salomon, M.,Dekker, R.(1999).An Investigation of Lead-Time Effects in Manufacturing/Remanufacturing Systems under Simple PUSH and PULL Control Strategies.European Journal of Operational Research,115(1),195-214.
  10. Lai, Y. J.,Hwang, C. L.(1992).A New Approach to Some Possibilistic Linear Programming Problems.Fuzzy Sets and Systems,49(2),121-133.
  11. Li, X.,Baki, F.,Tian, P.,Chaouch, B. A.(2014).A Robust Block-Chain Based Tabu Search Algorithm for the Dynamic Lot Sizing Problem with Product Returns and Remanufacturing.Omega,42(1),75-87.
  12. Li, X.,Wang, D.,Li, K.,Gao, Z.(2013).A Green Train Scheduling Model and Fuzzy Multi-Objective Optimization Algorithm.Applied Mathematical Modelling,37(4),2063-2073.
  13. Liang, T. F.(2009).Fuzzy Multi-Objective Project Management Decisions Using Two-Phase Fuzzy Goal Programming Approach.Computers & Industrial Engineering,57(4),1407-1416.
  14. Liu, Z. Y.,Sealy, M. P.,Guo, Y. B.,Liu, Z. Q.(2015).Energy Consumption Characteristics in Finish Hard Milling of Tool Steels.Procedia Manufacturing,1,477-486.
  15. Mahadevan, B.,David, F.P.,Fleischmann, M.(2003).Periodic Review, Push Inventory Policies for Remanufacturing.European Journal of Operational Research,151(3),536-551.
  16. Nenes, G.,Panagiotidou, S.,Dekker, R.(2010).Inventory Control Policies for Inspection and Remanufacturing of Returns: A Case Study.International Journal of Production Economics,125(2),300-312.
  17. Ozgen, D.,Gulsun, B.(2014).Combining Possibilistic Linear Programming and Fuzzy AHP for Solving the Multi-Objective Capacitated Multi-Facility Location Problem.Information Sciences,268,185-201.
  18. Paksoy, T.,Pehlivan, N. Y.,Ozceylan, E.(2012).Application of Fuzzy Optimization to a Supply Chain Network Design: A case study of an Edible Vegetable Oils Manufacturer.Applied Mathematical Modelling,36(6),2762-2776.
  19. Paksoy, T.,Pehlivan, N.Y.(2012).A Fuzzy Linear Programming Model for the Optimization of Multi-Stage Supply Chain Networks with Triangular and Trapezoidal Membership Functions.Journal of the Franklin Institute,349(1),93-109.
  20. Pishvaee, M. S.,Razmi, J.,Torabi, S. A.(2012).Robust Possibilistic Programming for Socially Responsible Supply Chain Network Design: A New Approach.Fuzzy Sets and Systems,206,1-20.
  21. Pishvaee, M. S.,Torabi, S. A.(2010).A Possibilistic Programming Approach for Closed-Loop Supply Chain Network Design under Uncertainty.Fuzzy Sets and Systems,161(20),2668-2683.
  22. Pishvaee, M. S.,Torabi, S. A.,Razmi, J.(2012).Credibility-Based Fuzzy Mathematical Programming Model for Green Logistics Design under Uncertainty.Computers & Industrial Engineering,62(2),624-632.
  23. Richter, K.,Weber, J.(2001).The Reverse Wagner/Whitin Model with Variable Manufacturing and Remanufacturing Cost.International Journal of Production Economics,71(1-3),447-456.
  24. Sadghiani, N. S.,Torabi, S.A.,Sahebjamnia, N.(2015).Retail Supply Chain Network Design under Operational and Disruption Risks.Transportation Research,75,95-114.
  25. Schweiger, K.,Sahamie, R.(2013).A Hybrid Tabu Search Approach for the Design of a Paper Recycling Network.Transportation Research Part E,50,98-119.
  26. Shaw, K.,Shankar, R.,Yadav, S.S.,Thakur, L.S.(2012).Supplier Selection Using Fuzzy AHP and Fuzzy Multi-Objective Linear Programming for Developing Low Carbon Supply Chain.Expert Systems with Applications,39(9),8182-8192.
  27. Shih, L. H.(2001).Reverse Logistics System Planning for Recycling Electrical Appliances and Computers in Taiwan.Resources, Conservation and Recycling,32(1),55-72.
  28. Skerlos, S. J.,Morrow, W. R.,Chan, K.,Zhao, F.,Hula, A.,Seliger, G.,Basdere, B.(2003).Economic and Environmental Characteristics of Global Cellular Telephone Remanufacturing.IEEE International Symposium on electronics and the environment
  29. Sundarakani, B.,Souza, R.D.,Goh, M.,Wagner, S.M.,Manikandan, S.(2010).Modeling Carbon Footprints across the Supply Chain.International Journal of Production Economics,128(1),43-50.
  30. Tang, O.,Grubbström, R. W.,Zanoni, S.(2007).Planned Lead Time Determination in a Make-to-Order Remanufacturing System.International Journal of Production Economics,108(1-2),426-35.
  31. Teunter, R.(2004).Lot-Sizing for Inventory Systems with Product Recovery.Computers & Industrial Engineering,46(3),431-441.
  32. Torabi, S.A.,Hassini, E.(2008).An Interactive Possibilistic Programming Approach for Multiple Objective Supply Chain Master Planning.Fuzzy Sets and Systems,159(2),193-214.
  33. Tseng, S. C.,Hung, S. W.(2014).A Strategic Decision-Making Model Considering the Social Costs of Carbon Dioxide Emissions for Sustainable Supply Chain Management.Journal of Environmental Management,133,315-322.
  34. Vahdani, B.,Tavakkoli-Moghaddam, R.,Jolai, F.(2013).Reliable Design of a Logistics Network under Uncertainty: A Fuzzy Possibilistic-Queuing Model.Applied Mathematical Modelling,37(5),3254-3268.
  35. Van der Laan, E. A.,Teunter, R. H.(2006).Simple Heuristics for Push and Pull Remanufacturing Policies.European Journal of Operational Research,175(2),1084-1102.
  36. Van der Laan, E.,Dekker, R.,Salomon, M.(1996).Product Remanufacturing and Disposal: A Numerical Comparison of Alternative Control Strategies.International Journal of Production Economics,45(1-3),489-498.
  37. Van der Laan, E.,Salomon, M.(1997).Production Planning and Inventory Control with Remanufacturing and Disposal.European Journal of Operation Research,102(2),264-278.
  38. Yang, M.F.,Lin, Y.(2013).Applying Fuzzy Multi-Objective Linear Programming to Project Management Decisions with the Interactive Two-Phase Method.Computers & Industrial Engineering,66(4),1061-1069.
  39. Zadeh, L. A.(1978).Fuzzy Sets as a Basis for a Theory of Possibility.Fuzzy Sets and Systems,1(1),3-28.
  40. Zahiri, B.,Tavakkoli-Moghaddam, R.,Pishvaee, M.S.(2014).A Robust Possibilistic Programming Approach to Multi-Period Location-Allocation of Organ Transplant Centers under Uncertainty.Computers & Industrial Engineering,74,139-148.
  41. Zimmermann, H. J.(1978).Fuzzy Programming and Linear Programming with Several Objective Functions.Fuzzy Sets and Systems,1(1),45-55.
print cancel