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Frontiers of Engineering Management

ISSN 2095-7513

ISSN 2096-0255(Online)

CN 10-1205/N

Postal Subscription Code 80-905

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Front. Eng    2016, Vol. 3 Issue (2) : 132-135    https://doi.org/10.15302/J-FEM-2016026
ENGINEERING MANAGEMENT THEORIES and METHODOLOGIES
The Integration Model of Closed-Loop Supply Chain Resource Allocation Considering Remanufacturing
Xiao-qiu Shi(),Yan-yan Li,Wei Long
School of Manufacturing Science and Engineering, Sichuan University, Chengdu 610065, China.
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Abstract

Logistics resource planning is an integration model of materials requirement planning and distribution resource planning which is a resource allocation technology. It is a technology of satisfying both production material supply and resource allocation optimization which is based on inventory management. For the remanufacturing supply chain, recycling and rebuilding of products form a reverse materials movement loop which challenges the traditional logistics resource planning system. For the characteristics of reverse logistics of remanufacturing supply chain, we propose a closed-loop supply chain resource allocation model based on autonomous multi-entity. We focus on integration resource allocation model of materials requirement planning and distribution resource planning considering remanufacturing.
Keywords remanufacturing      supply chain      reverse logistics      resource allocation      integration model     
Corresponding Author(s): Xiao-qiu Shi   
Online First Date: 13 September 2016    Issue Date: 22 September 2016
 Cite this article:   
Xiao-qiu Shi,Yan-yan Li,Wei Long. The Integration Model of Closed-Loop Supply Chain Resource Allocation Considering Remanufacturing[J]. Front. Eng, 2016, 3(2): 132-135.
 URL:  
https://academic.hep.com.cn/fem/EN/10.15302/J-FEM-2016026
https://academic.hep.com.cn/fem/EN/Y2016/V3/I2/132
Fig.1  LRP architecture.
Fig.2  LRP II architecture.
Notations Explanation
D(t) Master demand schedule
D1(t) A part of the main requirements document D(t), which companies can produce by themselves
D2(t) Products are not produced by enterprise
D3(t) Outsourcing plan
D4(t) Products form recycling system which can be used by remanufacturing
P(t) Market order plan
S(t) Delivery scheme
Os(t) Product delivery on the way
OP(t) Product arrival or in-transit
T1(t) Product plan whose materials are raw materials
T2(t) Product plan whose materials are from recycling products
Tab.1  Notations and its Explanation
1 Atasu, A., Van Wassenhove, L.N., & Sarvary, M. (2009). Efficient take-back legislation. Production and Operations Management, 18, 243–258.
https://doi.org/10.1111/j.1937-5956.2009.01004.x
2 Bras, B., & Mcintosh, M. W. (1999). Product, process and organization design for remanufacture—an overview research. Robots and Computer Integrated Manufacturing, 167–178.
3 Chen, Q. (1997). MRP II Manufacturing Resource Planning Basis. Beijing: Enterprise Management Publishing Group.
4 Gao, H. (2009). Workshop logistics intelligent control and warehouse management system research. Hubei: Huazhong University of Science and Technology.
5 Guo, J. (2011). Warehouse and MRP-II management Q & A. Guangzhou: Guangdong Provincial Publishing Group.
6 Han, J., Wu, C., & Fan, Y. (1998). Status and developing trends of supply chain modeling and management technology. CIMS, 4, 8–13.
7 Li, Y., & Long, W. (2012). The integration model of supply chain resource allocation—LRP. International Asia Conference on Industrial Engineering and Management Innovation (IEMI2012) Proceedings, 1279–1285.
8 Wang, Q., Liu, F., & Huang, H. (2008). Service oriented discrete workshop reconfigurable manufacturing execution system research. Computer Integrated Manufacturing, 4, 737–743.
9 Yuan, C., & Liu, H. (2007). Logistics, Warehousing and Distribution Management. Beijing: Peking University Press.
10 Zhang, Y. (1997). MRP-II and its Application. Beijing: Tsinghua University Press.
11 Zhu, X., & Pan, . (2000). Mix the multi-objective optimization design variables of Pareto genetic algorithm to realize. Journal of Shanghai Jiao Tong University, 411–414.
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