DYNAMIC OPTIMIZATION OF LAYOUT OF CONSTRUCTION WASTE RECYCLING FACILITIES: A CASE STUDY OF XINING, CHINA

WU Kunlun; GONG Zhiqi; WU Jia

doi:10.13205/j.hjgc.202306026

Volume 41 Issue 6

Jun. 2023

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2023 > 41(6): 194-201,258

HUANG Yajie, CUI Yanzhi, LIU Haidong, BIAN Huafeng, LI Junchao, ZHOU Yan. ANALYSIS OF SPATIAL DIFFERENCES AND COUNTERMEASURES OF PRECISION OF THE RURAL DOMESTIC SEWAGE TREATMENT IN THE YELLOW RIVER BASIN[J]. ENVIRONMENTAL ENGINEERING , 2023, 41(6): 47-53,156. doi: 10.13205/j.hjgc.202306007

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WU Kunlun, GONG Zhiqi, WU Jia. DYNAMIC OPTIMIZATION OF LAYOUT OF CONSTRUCTION WASTE RECYCLING FACILITIES: A CASE STUDY OF XINING, CHINA[J]. ENVIRONMENTAL ENGINEERING , 2023, 41(6): 194-201,258. doi: 10.13205/j.hjgc.202306026

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DYNAMIC OPTIMIZATION OF LAYOUT OF CONSTRUCTION WASTE RECYCLING FACILITIES: A CASE STUDY OF XINING, CHINA

doi: 10.13205/j.hjgc.202306026

WU Kunlun¹,
GONG Zhiqi^{1,2
,
,},
WU Jia¹

1. School of Civil Engineering, Qinghai University, Xining 810016, China;
2. Key Laboratory of Energy-saving Building Materials and Engineering Safety of Qinghai, Xining 810016, China

Received Date: 2022-09-13
Available Online: 2023-09-02

Abstract

Abstract

The layout of construction waste recycling facilities is the key to the construction of waste recycling network. In order to realize the multi-cycle consideration of facility location layout, a time-sharing evolution planning method was proposed, which integrated the facility processing capacity, social negative effect and construction waste production characteristics in different periods, and established a multi-objective programming model to minimize the regional economic cost and environmental negative impact. The genetic algorithm was used to solve the problem intelligently, and the dynamic optimization scheme of the facility location layout was obtained. Taking the main urban area of Xining as an example, a three-period construction waste recycling facility network was established to verify the effectiveness of the model. The results showed that the candidate points at B2 and B3 in stage t₁ (2020), and B2, B3 and B5 in stage t₂ (2025) and t₃ (2030) were the optimal location, and the fitness values converged to 3.7925×10⁸, 4.392×10⁸ and 5.0205×10⁸, respectively. This model can effectively balance the contradiction between economy and environment in facility location layout, and realize the dynamic optimization of facility location. The research provides certain reference for government and other relevant decision-makers to construct regional construction waste recycling facility networks.
- construction waste,
- facility layout,
- dynamic optimization,
- genetic algorithm

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References(25)

References

[1]	DUAN H B, MILLER T R, LIU G, et al. Construction debris becomes growing concern of growing cities[J]. Waste Management,2019, 83(1):1-5.
[2]	国家发展和改革委员会.中国资源综合利用年度报告(2014)[J].再生资源与循环经济,2014,7(10):3-8.
[3]	OMER M M, RAHMAN R A, ALMUTAIRI S. Construction waste recycling:enhancement strategies and organization size[J]. Physics & Chemistry of The Earth,2022, 126(6):103114.
[4]	LI G, LIU J K, GIORDANO A. Robust optimization of construction waste disposal facility location considering uncertain factors[J]. Journal of Cleaner Production,2022, 353(6):131455.
[5]	CHANG N B, CHEN Y L, WANG S F. A fuzzy interval multiobjective mixed integer programming approach for the optimal planning of solid waste management systems[J]. Fuzzy Sets & Systems,1997, 89(1):35-60.
[6]	ARAGONES-BELTRAN P, PASTOR-FERRANDO J P, GARCIA-GARCIA F, et al. An Analytic Network Process approach for siting a municipal solid waste plant in the metropolitan area of Valencia (Spain)[J]. Journal of Environmental Management,2010,91(5):1071-1086.
[7]	BANIAS G, ACHILLAS C, VLACHOKOSTAS C, et al. Assessing multiple criteria for the optimal location of a construction and demolition waste management facility[J]. Building & Environment,2010,45(10):2317-2326.
[8]	李强,刘洋,申玲.基于复杂网络的动态建筑垃圾处置设施网络布局[J].环境工程,2020,38(12):130-137.
[9]	GAO S Y, LIU Y, ZHOU Y Y, et al. Spatial distribution of construction waste recycling facilities[J]. Sensors & Materials,2021,32(11):3975-3990.
[10]	侯金亮.基于遗传算法的多目标空间优化选址[D].青岛:中国石油大学(华东),2011.
[11]	马小姝,李宇龙,严浪.传统多目标优化方法和多目标遗传算法的比较综述[J].电气传动自动化,2010,32(3):48-50 ,53.
[12]	LIU J K, XIAO Y Q, WANG D, et al. Optimization of site selection for construction and demolition waste recycling plant using genetic algorithm[J]. Neural Computing & Applications,2019,31(9):233-245.
[13]	SHI Q W, REN H, MA X R, et al. Site selection of construction waste recycling plant[J]. Journal of Cleaner Production,2019,227(8):532-542.
[14]	TONG B, WANG J W, WANG X, et al. Optimal route planning for truck-drone delivery using variable neighborhood tabu search algorithm[J]. Applied Sciences-Basel,2022,12(1):529.
[15]	TANG H T, REN S L, JIANG W G, et al. Optimization of multi-objective unequal area facility layout[J]. Ieee Access,2022,10:2169-3536.
[16]	GONG M G, JIAO L C, YANG D D, et al. Research on evolutionary multi-objective optimization algorithms[J]. Journal of Software,2009,20(2):271-289.
[17]	BARBOSA-POVOA A P, CARVALHO A, et al. Opportunities and challenges in sustainable supply chain:an operations research perspective[J]. European Journal of Operational Research,2018,268(2):399-431.
[18]	RAHIMI M, GHEZAVATI V. Sustainable multi-period reverse logistics network design and planning under uncertainty utilizing conditional value at risk (CVaR) for recycling construction and demolition waste[J]. Journal of Cleaner Production,2018,172:1567-1581.
[19]	住房和城乡建设部.建筑垃圾处理标准:CJJ/T 134-2019[S].北京:中国建筑工业出版社,2019:5.
[20]	ZHENG L N, WU H Y, ZHANG H, et al. Characterizing the generation and flows of construction and demolition waste in China[J]. Construction & Building Materials,2017, 136(4):405-413.
[21]	WU H Y, WANG J Y, DUAN H B, et al. An innovative approach to managing demolition waste via GIS (geographic information system):a case study in Shenzhen city, China[J]. Journal of Cleaner Production,2016,112(1):494-503.
[22]	SONG Y L, WANG Y, LIU F, et al. Development of a hybrid model to predict construction and demolition waste:China as a case study[J]. Waste Management,2018,59(1):350-361.
[23]	DING T, XIAO J Z. Estimation of building-related construction and demolition waste in Shanghai[J]. Waste Management,2014,34(11):2327-2334.
[24]	DING Z K, GONG W Y, VIVIAN W T TAM,et al. Conceptual framework for renovation waste management based on renovation waste generation rates in residential buildings:an empirical study in China[J]. Journal of Cleaner Production,2019, 228(8):284-293.
[25]	SOLEIMANI H, GOVINDAN K, SAGHAFI H, et al. Fuzzy multi-objective sustainable and green closed-loop supply chain network design[J]. Computers & Industrial Engineering,2017, 109(7):191-203.

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