跳到主要內容

臺灣博碩士論文加值系統

(35.172.136.29) 您好!臺灣時間:2021/07/26 22:10
字體大小: 字級放大   字級縮小   預設字形  
回查詢結果 :::

詳目顯示

我願授權國圖
: 
twitterline
研究生:詩格拉
研究生(外文):Sugarla Edwin Nagaraj
論文名稱:製造商與清運商廢棄物清運模式建構
論文名稱(外文):Waste disposal models for manufacturing firm and disposal firm
指導教授:蔡啟揚
學位類別:碩士
校院名稱:元智大學
系所名稱:工業工程與管理學系
學門:工程學門
學類:工業工程學類
論文種類:學術論文
論文出版年:2009
畢業學年度:97
語文別:英文
論文頁數:79
中文關鍵詞:廢棄物清運模式存貨管制協同模式
外文關鍵詞:waste disposal modelinventoryintegrated model
相關次數:
  • 被引用被引用:0
  • 點閱點閱:320
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:0
This research identifies analyze and propose solutions for waste-related problems in industries. In this research an inventory control of the waste products that are generated during the manufacturing process is concerned. Two types of waste accumulation rates are discussed. One is the constant waste accumulation rate and the other is the linearly increasing waste accumulation rate. Also, waste disposal is examined from two different perspectives, from the point of view of the waste ‘producing’ company on the one hand, and from the point of view of the waste disposing company on the other hand. The idea of the basic model lies in the ‘turning upside down’ of the lot-sizing approach to inventory control theory. A corresponding formula for disposal is derived to calculate the optimal number of pick-ups and the amount of waste to be disposed at certain period of time. This shows that the results for these two different types of waste accumulation differ in a wide range because of the difference in the waste accumulated way which disturbs the storage cost. Finally, both the models are verified by a numerical example and both the results are compared.

An integrated model is developed and discussed in which both the manufacturing firm and the disposal firm are benefited by the integrated model. This research also explains the necessity of integration between the manufacturing and the disposal firm for effective implementation of the integrated model. An integrated lot-splitting model of facilitating multiple shipments in small lots is developed and compared with the existing approach in a simple waste disposal model, under deterministic conditions for waste products. It is shown that the optimal policy adopted by the integrated approach can provide a strong and consistent cost-minimizing effect for both the manufacturing firm and the disposal firm over the existing approach.
This research identifies analyze and propose solutions for waste-related problems in industries. In this research an inventory control of the waste products that are generated during the manufacturing process is concerned. Two types of waste accumulation rates are discussed. One is the constant waste accumulation rate and the other is the linearly increasing waste accumulation rate. Also, waste disposal is examined from two different perspectives, from the point of view of the waste ‘producing’ company on the one hand, and from the point of view of the waste disposing company on the other hand. The idea of the basic model lies in the ‘turning upside down’ of the lot-sizing approach to inventory control theory. A corresponding formula for disposal is derived to calculate the optimal number of pick-ups and the amount of waste to be disposed at certain period of time. This shows that the results for these two different types of waste accumulation differ in a wide range because of the difference in the waste accumulated way which disturbs the storage cost. Finally, both the models are verified by a numerical example and both the results are compared.

An integrated model is developed and discussed in which both the manufacturing firm and the disposal firm are benefited by the integrated model. This research also explains the necessity of integration between the manufacturing and the disposal firm for effective implementation of the integrated model. An integrated lot-splitting model of facilitating multiple shipments in small lots is developed and compared with the existing approach in a simple waste disposal model, under deterministic conditions for waste products. It is shown that the optimal policy adopted by the integrated approach can provide a strong and consistent cost-minimizing effect for both the manufacturing firm and the disposal firm over the existing approach.
ABSRTACT i
ACKNOWLEDGMENT iii
TABLE OF CONTENT iv
LIST OF FIGURES vi
LIST OF TABLES vii
Chapter 1 Introduction 1
1.1 Overview 1
1.2 Waste Disposal 3
1.3 Purpose 5
1.4 Research Objective 6
1.5 Thesis Organization 6
Chapter 2 Literature Review 8
2.1 Inventory control 8
2.2 Waste Disposal Issue 12
2.3 Integrated Models 14
2.4 Summary 16
Chapter 3 Basic Model 18
3.1 Introduction to the systems 18
3.1.1 System Structure 18
3.1.2 Manufacturing firm 18
3.1.3 Disposal firm 19
3.1.4 Relationship between the two firms 19
3.1.5 Problem statement 20
3.2 Notations and Assumptions 21
3.2.1 Notations 21
3.2.2 Assumptions 22
3.3 Case: 1 (Constant waste accumulation rate) 23
3.4 Case: 2 (Linearly increasing waste accumulation rate) 28
3.4.1 Waste accumulation rate 29
3.4.2 Waste accumulation rate 36
3.5 Comparison between the two waste accumulation rates 43
Chapter 4 Integrated Model 49
4.1 Introduction 49
4.2 Notations and Assumptions 50
4.2.1 Notations 50
4.2.2 Assumptions 51
4.3 Integration of costs under constant waste accumulation rate 51
4.3.1 Numerical Example 4.1 53
4.4 Integration of costs under linearly increasing waste accumulation rate 57
4.4.1 Numerical Example 4.2 59
4.4.2 Numerical Example 4.3 62
4.5 Comparison between the integrated models 65
Chapter 5 Conclusion and Future Research 68
5.1 Conclusion 68
5.2 Future Research 71
References 72
Anis, C. and Daoud, A. K., 2004, Analysis of a production/inventory system with randomly failing production unit submitted to regular preventive maintenance. European Journal of Operational Research, 156: 712-718.

Anwar, M. F. and Nagi, R., 1997, Integrated lot-sizing and scheduling for just-in-time production of complex assemblies with finite set-ups. International Journal of Production Research, 35: 1447-1470.

Axsater, S., 2001, A framework for decentralized multi-echelon inventorv control. IIE Transactions, 33: 91-98.

Banerjee, A., 1985, A joint economic-lot-size model for purchaser and vendor. Decision Sciences, 17: 292-311.

Ben-Daya, M., 2002, The economic production lot-sizing problem with imperfect production processes and imperfect maintenance. International Journal of Production Economics, 76: 257-264.

Biswas, A., Sarkar, J. and Sarkar, S., 2004, Availability of a periodically inspected system, maintained under an imperfect-repair policy. IEEE Transactions on Reliability, 52 (3): 318-331.

Boehle, S., Dobbs, K. and Stamps, D., 2000, Two views of distance learning, Training, 37 (6): 34.

Cheng, T. C. E., 1991, An economic order quantity model with demand-dependent unit production cost and imperfect production processes. IIE Transactions, 23: 23-28.

Chiu, S. W., Gong, D. C. and Wee, H. M., 2004, The effects of the random defective rate and the imperfect rework process on the economic production quantity model, Japan. Journal of Industrial and Applied Mathematics, 21(3): 375-389.

Chiu, Y. S. P., Chiu, S. W. and Chao, H. C., 2006, Numerical method for determination of reworking or scraping the defective items in a finite production rate model. Communications in Numerical Methods in Engineering, 22(5): 377-386.

Chiu, Y. P., 2003, Determining the optimal lot size for the finite production model with random defective rate, the rework process and backlogging. Engineering Optimization, 35(4): 427-437.

Chung, K. J. and Hou, K. L., 2003, An optimal production run time with imperfect production processes and allowable shortages. Computers and Operations Research, 30: 483-490.

Collier, G. and Johnson, D. F., 1998, Patch choice as a function of procurement cost and encounter rate. Journal of the Experimental Analysis of Behavior, 69: 5-17.

Das, T. K. and Sarkar, S., 1999, Optimal preventive maintenance in a production inventory system. IIE Transactions, 31: 537-551.

Davey, K. R., 1999, Field optimization using calculus of stationary points. IEE Transactions on Magnetics, 35: 1718-1722.

Dekker, R. and Frenk, J. B. G., 2000, On the newboy model with a cutoff transaction size. IIE Transactions, 32: 461-470.

Erlonkotter, D., 1978, A dual based procedure for uncapacitated facility location. Operations Research, 26: 992-1009.

Taylor, F. W., 1911, Shop Management, Harper and Brothers Publishers, New York and London.

Gavirneni, S. and Tayur, S., 2001, An efficient procedure for non-stationary inventory control. IIE Transactions, 33: 83-89.

Glassey, C. R. and Gupta, V. K., 1974, A linear programming analysis of paper recycling. Management Science, 21: 392-408.

Goyal, S. K., 1976, An integrated inventory model for a single supplier - single customer problem. International Journal of Production Research, 15: 107-111.

Goyal, S. K., 1988, A joint economic lot-size model for purchaser and vendor: A comment. Decision Sciences, 19: 236-241.

Greenberg, H. J., 1995, Mathematical programming models for environmental quality control. Operations Research, 43(4): 578-622.

Gupta, M. C., 1995, Environmental management and its impact on the operations function. International Journal of Operations and Production Management, 15: 34-51.

Ha, D. and Kim, S. L., 1997, Implementation of JIT purchasing: an integrated approach. Production Planning and Control, 8(2): 152-157.

Haase, K., 1994, Lotsizing and Scheduling for Production Planning, Lecture Notes. Economics and Mathematical Systems, (Berlin: Springer), 408.

Harris, F. W., 1913, How many parts to make at once, Factory. The Magazine of Management, 10: 135-136.

Hayek, P. A. and Salameh, M. K., 2001, Production lot sizing with the reworking of imperfect quality items produced. Production Planning and Control, 12: 584-590.

Hill, R. M., 1999, The optimal production and shipment policy for the single-vendor single-buyer integrated production inventory problem. International Journal of Production Research, 37: 2463-2475.

Hillier, F. S. and Lieberman, G. J., 2001, Introduction to Operations Research. McGraw-Hill Co. Inc., New York, 941-958.

Hillier, F. S. and Lieberman, G. J., 2002, Introduction to Operations Research, Seventh Edition, McGraw-Hill Co. Inc., New York.

Hofmann, C., 1998, Investments in modern production technology and the flow-oriented EPQ-model. International Journal of Production Research, 54: 193-206.

Hopp, W. and Spearman, M., 1996, Factory Physics: Foundations of Factory Management, Irwin/McGraw Hill, Chicago, IL.

Hoque, M. A. and Goyal, S. K., 2000, An optimal policy for a single-vendor single-buyer integrated production-inventory system with capacity constraint of transport equipment. International Journal of Production Economics, 65: 305-315.

Inderfurth, K., 1997, Simple optimal replenishment and disposal strategies for a product recovery system with leadtimes. OR Spectrum, 19: 111-122.

Islam, M. N., 2004, A methodology for extracting dimensional requirements for a product from customer needs. International Journal of Advanced Manufacturing Technology, 23: 489–494.

Krikke, H. R., Van Harten, A. and Schuur, P., 1999, Business case: reverse logistic network re-design for copiers. OR Spectrum, 31: 381-409.

Kroll, E., Beardsey, B. and Parulian, A., 1996, A methodology to evaluate ease of disassembly for product recycling. IIE Transactions, 28(10): 837-849.

Lapin, L. L., 1994, Quantitative methods for business decisions: with cases, 6th edition. Fort Worth: Dryden Press.

Lee, H. L. and Rosenblatt, M. J., 1987, Simultaneous determination of production cycle and inspection schedules in a production system. Management Sciences, 33: 1125-1136.

Liang, X. B. and Wang, J., 2000, A recurrent neural network for nonlinear optimization with a continuously different objective function and bound constraints. IEEE on Neural Networks, 11: 1251-1263

Lin, C. S., Chen, C. H. and Kroll, D. E., 2003, Integrated production-inventory models for imperfect production processes under inspection schedules. Computers and Industrial Engineering, 44: 633-650.

Liu, X. P., Wang, S. W. and Liu, G. F., 2002, Recycling strategy and a recyclability assessment model based on an artificial neural network. Journal of Materials Processing Technology, 129: 500-506.

Ljunggren, M., 2000, Modelling national solid waste management. Waste Management, 18: 525–537.

Nahmias, S., 2001, Production and Operations Analysis. McGraw-Hill Co. Inc., New York, 203-214.

Nie, X. H., Huang, G. H., Li, Y. P. and Liu, L., 2007, IFRP: A hybrid interval-parameter fuzzy robust programming approach for waste management planning under uncertainty. Journal of Environmental Management, 84: 1-11.

Nita, H. and Ajay, S., 2009, An integrated economic lot-size model for vendor–buyer inventory system when input is random. Mathematical and Computer Modelling, 49: 1326-1330.

Osteryoung, S., Nosari, E., McCarty, D. and Reinhart, W.J., 1986, Use of the EOQ model for inventory analysis. Production and Inventory Management, 27: 39-45.

Ouyang, L. Y., Chen, C. K. and Chang, H. C., 2002, Quality improvement, setup cost and lead-time reductions in lot size reorder point models with an imperfect production process. Computers and Operations Research, 29: 701-1717.

Pham, H. and Wang, H., 1996, Imperfect maintenance. European Journal of Operational Research, 94 (3): 425-438.

Pirkul, H. and Schilling, D. A., 1988, The siting of emergency service facilities with workload capacities and backup service. Management Science, 34: 896-908.

Plossl, G., 1994, Orlicky’s Material Requirements Planning, 2nd edition (New York: McGraw-Hill).

Porteus, E. L., 1986, Optimal lot sizing, process quality improvement and setup cost reduction. Operations Researches, 34: 37-44.

Ramasesh, R. V., 1990, Recasting the traditional inventory model to implement just-in-time purchasing. Production and Inventory Management Journal, 31: 71-75.

Revelle, C., Marks, D. and Liebman, L., 1970, Analysis of private and public sector location models. Management Science, 16: 692-707.

Richter, K., 1996, The EOQ repair and waste disposal model with variable setup numbers. European Journal of Operational Research, 96: 313-324.

Rosenblatt, M. J. and Lee, H. L., 1986, Economic production cycles with imperfect production processes. IIE Transactions, 18: 48-55.

Salameh, M. K. and Jaber, M. Y., 2000, Economic production quantity model for items with imperfect quality. International Journal of Production Economics, 64: 59-64.

Silver, E. A., Pyke, D. F. and Peterson, R., 1998, Inventory Management and Production Planning and Scheduling. John Wiley and Sons, Inc., New York, 151- 172.

Sipper, D. and Bulfin, R. L., 1997, Production Planning, Control and Integration, McGraw-Hill.

Stuart, J. A., Ammons, J. C. and Turbini, L. J., 1999, A product and process selection model with multidisciplinary environmental considerations. Operations Research, 47(2): 221-234.

Tseng, S. T., Yeh, R. H. and Ho, W. T., 1998, Imperfect maintenance policies for deteriorating production systems. International Journal of Production Economics, 55: 191-201.

Viswanathan, S., 1998, Optimal strategy for the integrated vendor-buyer inventory model. European Journal of Operational Research, 105: 38-42.

Vollmann, T. E., Berry, W. L. and Whybark, D. C., 1997, Manufacturing Planning and Control Systems, 4th edition (Boston: McGraw-Hill).

Wiese, H. and Zelewski, S., 2002, Waste disposal and waste avoidance. International Journal of Production Research, 40(14): 3391-3400.

Wu, J. W., Lin, C., Tan, B. and Lee, W. C., 2000, An EOQ inventory model with time varying demand and Weibull deterioration with shortages. International Journal of System Science, 31: 677-683.

Yang, P. C. and Wee, H. M., 2005, A win-win strategy for an integrated vendor–buyer deteriorating inventory system. Mathematical Modeling and Analysis, in Proceedings of the 10th International Conference MMA2005 and CMAM2, Trakai, 541-546.

Yee, M. J. and Veatch, M. H., 2000, Just-in-time policies for single-machine manufacturing flow controllers. IEEE Transactions on Automatic Control, 45: 336- 340.
QRCODE
 
 
 
 
 
                                                                                                                                                                                                                                                                                                                                                                                                               
第一頁 上一頁 下一頁 最後一頁 top