應用數學規劃法設計冰水網路及冰水主機操作策略

Meng-Da Lee; 李孟達

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/10035

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳誠亮
dc.contributor.author	Meng-Da Lee	en
dc.contributor.author	李孟達	zh_TW
dc.date.accessioned	2021-05-20T20:57:15Z	-
dc.date.available	2011-08-03
dc.date.available	2021-05-20T20:57:15Z	-
dc.date.copyright	2011-08-03
dc.date.issued	2011
dc.date.submitted	2011-07-28
dc.identifier.citation	[1] Brooke, A., Kendrick. D., Meeraus, A., Raman, R., and Rosenthal, R. E. GAMS: A User’s Guide. GAMS Development Corporation, 1988. [2] Chaplin Tyler, S.M. Chemical Engineering Economics. Mcgraw-Hill Book Company, 1984. [3] C.L.Chen, L.F. Lin, Y.J. Ciou andW.C. Chen. Superstructure-based MINLP formulation for systhesis of re-circulating cooling-water network with intermediate mains. Journal of Chemical Engineering of Japan, 40:235, 2007. [4] Feng, X. and Seider, W.D. New structure and design methodology for water networks. Ind. Eng. Chem. Res., 40:6140, 2001. [5] Feng, X. and Shen B. Wang. Recirculating Cooling-water Network with an intermediate Cooling-Water Main. Energy and Fuels, 19:1723, 2005. [6] FENG Xiao, LI Yucai and YU Xinjiang . Improving Energy Performance of Water Allocation Networks. Chinese Journal of Chemical Engineering, 16(3):480, 2008. [7] Gunarantam, M., A.-A. K. A. J.-K. and Smith, R. Automated design of total water systems. Ind. Eng. Chem. Res., 44(2005):588. [8] H. Rodera and M.J. Bagajewicz. Targeting procedures for energy saving by heat integration across plants. AIChE, 45(8):1721, 1999. [9] Irene Mei Leng Chew, Raymond Tan, Denny Kok Sum Ng, Dominic Chwan Yee Foo. Synthesis of Direct and Indirect Interplant Water Network. Ind. Eng. Chem. Res., 47:9485, 2008. [10] Jin-Kuk Kim and R. Smith. Cooling system design for water and wastewater minimization. Ind. Eng. Chem. Res., 43:608, 2004. [11] Kim, J., R. Smith. Cooling water system design. Chem. Eng. Sci., 56:3641, 2001. [12] Kim, J., R. Smith. Automated retrofit design of cooling-water systems. AICHE J., 49:1712, 2003. [13] Kim, J., Savulescu. L., R. Smith. Design of cooling system for effluent temperature reduction. Chem. Eng. Sci., 56:1811, 2001. [14] Kuo,W., and Smith, R. Effluent treatment system design. Chem. Eng. Sci., 52:4273, 1997. [15] Kuo, W., and Smith, R. Design of water-using systems involving regeneration,. 76:94, 1998. [16] L.E. Savulescu, M. Sorin and R.Smith. Direct and indirect heat transfer in water network systems. Applied Thermal Engineering, 22:981, 2002. [17] Liu,Y., Duan, H. and Feng, X. The design of water-reusing network with a hybrid structure through mathematical programming. Chinese Journal of Chemical Engineering, 16:1, 2008. [18] M. AMIDPOUR and G. T. POLLEY. APPLICATION OF PROBLEMDECOMPOSITION IN PROCESS INTEGRATION. Institution of Chemical Engineers, 15(12):809, 1991. [19] M.H. Panjeshahi, A. Ataei, M. Gharaie, R. Parand. Optimum design of cooling water system for energy and water conservation. Chemical Engineering Research and Design, 87:200, 2009. [20] Miguel Bagajewicz and H.Rodera . Energy savings in total site heat integration across many plants. Computers and Chemical Engineering, 24:1237, 2000. [21] M.M. Castro, T.W. Song and J.M. Pinto. Minimization of operational costs. Trans IchemE, 78(part A):part A, 2000. [22] Robin Smith. Chemical Process Design and Integration. Wiley, 2005. [23] Rosain RM. Reusing water in CPI plants. Chemical engineering progress, 89(4):28. [24] S. AHMAD and D. C.W. Htn. Heat recovery between areas of integrity. Computers chem. Engng., 15(12):809, 1991. [25] S.V. Bedekar, P. Nithiarasu and K.N. Seetharamu. Experimental investigation of the performance of a counter-flow, packed-bed mechanical cooling tower. Energy, 23(11):943, 1998. [26] T. Majozi and A. Moodley. Simultaneous targeting and design for cooling water systemwith multiple cooling water supplies. Computers and Chemical Engineering, 32:540, 2008. [27] Wang, Y. and Smith, R. Design of distributed effluent treatment system. Chem. Eng. Sci., 49:3127, 1994. [28] Wang, Y. and Smith R. Wastewater minimization. Chem. Eng. Sci., 49:981, 1994. [29] Xiao Feng ., Jie Bai, Huimin Wang, Xuesong Zheng. Grass-roots design of regeneration recycling water networks. Computers and Chemical Engineering, 32:1892, 2008.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/10035	-
dc.description.abstract	本文同時針對冰水網路系統及冰水主機操作策略，提出以數學規劃法的方式進行整體最適化的設計。首先我們提出一個可以描述所有可能的冰水網路超結構，針對超結構中的每一個單元逐步建立規範方程式，即可將冰水網路系統的最適化問題變成一個典型的混合整數非線性規劃(MINLP)數學問題，再經求解可以獲得冰水網路系統的最適化設計。目標函數(1)為最小總冰水消耗量，對一個虛擬的例子作不同情境的最適化並比較其結果；接著，基於目標函數(1)的結果，我們為了得到唯一解，所以提出目標函數(2) 為每一冰水使用單元最小通過量。再者，我們也提出冰水主機之超結構，考慮不同的冰水主機操作上下限，利用目標函數(3)為最少固定及變動操作成本去探討不同網路結構對其操作策略之影響。接著透過目標函數(4)使得冰水操作方式可以獲得一個唯一解。最後我們利用一個簡單的冰水網路合成例子，驗證本研究所提出之數學模型及超結構上可設計出適當的冰水網路設計與冰水主機操作策略織架構與操作條件。	zh_TW
dc.description.abstract	This work aims to develop a mathematical model for the synthesis of refrigerated water network systems and chiller operating strategy simultaneously. First of all, we proposed one model which includes all possible configurations of refrigerated water network system under all conditions. By setting relevant constraints up for each part of the superstructure, the design problem of refrigerated water network system is formulated as a mixed-integer nonlinear program that can be solved for optimal configuration of refrigerated water network. Objective functions 1 and 2 are considered which involving the mimnimization of refrigerated water supply and obtaining a unique network structure. Furthermore we also proposed a superstructure for chillers' operation, considering different operating upper and lower bounds. In this work, two objective functions are considered to minimize fixed and variable operating cost. Finally, numerical examples are used to show that the proposed approach can provide the optimal design of refrigerated water network system and chiller operating strategy.	en
dc.description.provenance	Made available in DSpace on 2021-05-20T20:57:15Z (GMT). No. of bitstreams: 1 ntu-100-R98524085-1.pdf: 10019866 bytes, checksum: f3b615fdff24ea2a01e7bd65e84d587b (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	目錄誌謝 i 摘要 iii Abstract v 附圖目錄 xi 附表目錄 xv 1 緒論 1 1.1 前言 1 1.2 整合性冰水網路與冰水主機操作策略之發展與說明 4 1.3 文獻回顧 6 1.4 研究動機與目的 8 1.5 組織章節 9 2 冰水網路最適化之模型建構 11 2.1 模型建立之背景說明與想法 11 2.2 模型建立之基本假設條件 17 2.3 模型建立之圖解說明 18 2.4 模型之符號、集合、系統參數與變數(Indices, Sets, Parameter, and Variable) 22 2.4.1 下標符號說明(Indices) 22 2.4.2 集合說明(Sets) 23 2.4.3 系統參數(Parameter) 24 2.4.4 系統變數(Variables) 24 2.5 冰水網路限制式 27 2.5.1 冰水使用單元流量平衡與能量平衡 27 2.5.2 供應儲存槽流量平衡與能量平衡 29 2.5.3 中間儲存槽流量平衡與能量平衡 30 2.5.4 回流儲存槽流量平衡與能量平衡 31 2.5.5 物流流量之上限與下限 32 2.6 各網路結構下的額外限制式 33 2.6.1 Re-use Separate Design 之額外限制式 34 2.6.2 Re-use Separate Design with Inner Mains 之額外限制式 35 2.6.3 Re-use with Inter-Plant Mains之額外限制式 36 2.6.4 Re-use with Inter/Inner-Plant 之額外限制式 37 2.7 目標函數(Objectives) 38 2.7.1 目標函數(1) 最少總冰水消耗量(To Minimize Total Refrigerated Water) 39 2.7.2 目標函數(2) 每一冰水使用單元最小通過量(To minimize Throughput of RW Units) 40 3 冰水主機之操作策略 41 3.1 模型建立之背景說明與想法 41 3.2 模型建立之基本假設條件 43 3.3 模型建立之圖解說明 44 3.4 模型之符號、集合、系統參數與變數(Indices, Sets, Parameter, and Variable) 46 3.5 冰水主機限制式 48 3.5.1 冰水主機流量平衡 48 3.5.2 冰水主機能量平衡 49 3.5.3 冰水主機邏輯限制 51 3.6 目標函數(Objectives) 52 3.6.1 目標函數(3) 最少固定/變動操作成本(To Minimize Fixed/variable Operating Cost) 53 3.6.2 目標函數(4) 每一冰水主機最小通過量(To Minimize Throughput of Chillers) 54 4 冰水網路及冰水主機操作策略之模擬與結果分析 57 4.1 最適化軟體 58 4.2 兩個工廠及十一個冰水使用單元之冰水網路模擬 58 4.3 冰水網路間之冰水不考慮熱整合之問題(without HI) 61 4.3.1 操作點下限為0.5，操作點上限為1.0 64 4.3.2 操作點下限為0.75，操作點上限為1.0 73 4.3.3 操作點下限為1.0，操作點上限為1.0 77 4.4 冰水主機間之冰水考慮熱整合之問題(with HI) 81 4.4.1 操作點下限為0.5，操作點上限為1.0 81 4.4.2 操作點下限為0.75，操作點上限為1.0 81 4.4.3 操作點下限為1.0，操作點上限為1.0 83 5 結論與未來展望 91 5.1 結論 91 5.2 未來展望 92 參考文獻 95
dc.language.iso	zh-TW
dc.title	應用數學規劃法設計冰水網路及冰水主機操作策略	zh_TW
dc.title	A Mathematical Approach for the Design of Refrigerated Water Network and Chiller Operating Strategy	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	錢義隆,王子奇,鄭智成
dc.subject.keyword	最適化,超結構,冰水網路系統,冰水主機,混合整數非線性規劃,	zh_TW
dc.subject.keyword	Optimization,Superstructure,Refrigerated Water Network Systems,Chiller,Mixed-integer nonlinear programming (MINLP),	en
dc.relation.page	97
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2011-07-28
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	化學工程學研究所	zh_TW
顯示於系所單位：	化學工程學系

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