ESTIMATION OF POTENTIAL MINERAL RESOURCE DEPOSITS IN RESIDENCE BUILDINGS OF HUILONGGUAN COMMUNITY IN BEIJING

LI Haiping; REN Shuai; JIN Min

doi:10.13205/j.hjgc.202210025

Volume 40 Issue 10

Oct. 2022

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LI Haiping, REN Shuai, JIN Min. ESTIMATION OF POTENTIAL MINERAL RESOURCE DEPOSITS IN RESIDENCE BUILDINGS OF HUILONGGUAN COMMUNITY IN BEIJING[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(10): 183-191. doi: 10.13205/j.hjgc.202210025

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LI Haiping, REN Shuai, JIN Min. ESTIMATION OF POTENTIAL MINERAL RESOURCE DEPOSITS IN RESIDENCE BUILDINGS OF HUILONGGUAN COMMUNITY IN BEIJING[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(10): 183-191. doi: 10.13205/j.hjgc.202210025

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ESTIMATION OF POTENTIAL MINERAL RESOURCE DEPOSITS IN RESIDENCE BUILDINGS OF HUILONGGUAN COMMUNITY IN BEIJING

doi: 10.13205/j.hjgc.202210025

School of Environment and Natural Resources, Renmin University of China, Beijing 100872, China

Received Date: 2021-12-03

Abstract

Abstract

Mining urban mineral resource deposits to compensate for the shortage of primary mineral resources is of great significance. The key to this problem is to estimate urban mineral deposits accurately. This research focused on the residence buildings and estimated the potential mineral deposits on a community scale. In this paper, Huilongguan community in Beijing was chosen as an example, and the in-use stock of 662 residence buildings in 21 communities was estimated quantitatively. Mineral deposits were estimated according to the life cycle of China's residence building, and the number of recoverable resources was calculated furthermore. Annual greenhouse gas emissions of current buildings were also estimated. The results showed that:1) potential deposits of mineral resources were large and the total amount in 21 communities reached 7.293 million tons; 2) buildings of 562 frame and 70 shear wall structures took 95.48% of the whole, and their greenhouse gas emissions were much higher than brick-concrete structure buildings. Environmental pressure would be greater as frame and shear wall structure buildings become dominant in the future; 3) the estimated recyclable materials deposit were 3.658 million tons and might have beneficial resource, and environmental effects through classified treatment and recycling.
- urban mineral resources,
- deposits of residence building,
- resources development and utilization,
- environmental impacts

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References(27)

References

[1]	刘航.中国城市矿产资源开发利用现状、问题及对策[J].中国矿业,2018,27(9):1-6 ,15.
[2]	国家统计局固定资产投资统计司. 中国建筑业统计年鉴[M].北京:中国统计出版社,2018.
[3]	常纪文,杜根杰,李红科,等.建筑垃圾绿色低碳资源化利用市场空间广阔[J].环境经济,2021(7):38-41.
[4]	杨东,刘晶茹,李玉,等.面向城市管理的城市建筑存量研究综述[J].中国环境管理,2019,11(5):88-93.
[5]	ROW A T, JACOBS J. The Death and Life of Great American City[J]. Yale Law Journal, 1962, 6(8):94-109.
[6]	孙笑非,钱易,温宗国,等.我国"城市矿山"开发利用战略研究[J]. 中国工程科学,2017,19(4):97-102.
[7]	董磊.基于资源节约的城市住宅建筑存量更新策略[D].天津:天津大学,2014.
[8]	郭振,张炫钊.海岛基础设施物质存量构成及动态变化研究:以山东庙岛为例[J].青岛科技大学学报(社会科学版),2017,33(4):40-46,117.
[9]	BOGOVIKU L L, WALDMANN D. Modelling of mineral construction and demolition waste dynamics through a combination of geospatial and image analysis[J]. Journal of Environmental Management, 2021,282:11879.
[10]	北京市统计局. 北京统计年鉴[M]. 北京:中国统计出版社,1980-2020.
[11]	BARLES S. Urban metabolism of paris and its region[J]. Journal of Industrial Ecology, 2009, 13(6):898-913.
[12]	VINCENT A, SABINE B. Studying construction materials flows and stock:a review[J]. Resources, Conservation & Recycling, 2017,123:153-164.
[13]	WEI Q C, GRAEDEL T E. In-use product stocks link manufactured capital to natural capital[J]. Proceedings of the National Academy of Sciences, 2015, 112(20):6265-6270.
[14]	DAIGO I, HASHIMOTO S, MATSUNDY. Material stocks and flows accounting for copper and copper-based alloys in Japan[J]. Resources, Conservation & Recycling, 2008, 53(4):208-217.
[15]	GERST M D, GRAEDEL T E. In-use stocks of metals:status and implications[J]. Environmental Science & Technology, 2008, 42(19):7038-7045.
[16]	刘天星,胡聃.北京住宅建设的环境影响:1949-2003年——从生命周期角度评价建筑材料的环境影响[J].中国科学院研究生院学报,2006,23(2):231-241.
[17]	王小兵,邓南圣,孙旭军.建筑物生命周期评价初步[J].环境科学与技术,2002,25(4):18-20 ,49.
[18]	吕文倩.城市住宅建筑物质代谢研究[D].南京:南京农业大学,2014.
[19]	王寿兵. 生命周期评价[J].上海管理科学,1998(4):45.
[20]	王汉东,黄瓅瑶,朱思蓉,等.三峡区间面雨量空间插值方法对比分析[J].水利信息化,2021(1):26-29.
[21]	周永生,易和鸣,肖遗规.浅议中国"城市矿产"的发展[J].生态经济,2012(8):123-126.
[22]	杨静,刘燕丽.我国城市建筑垃圾资源化现状及对策研究[J].中小企业管理与科技(中旬刊),2021(2):95-97.
[23]	杜婷,李惠强,郭太平,等.废弃混凝土再生骨料应用的经济性分析[J].新型建筑材料,2006(6):30-33.
[24]	李浩,翟宝辉.中国建筑垃圾资源化产业发展研究[J].城市发展研究,2015,22(3):119-124.
[25]	邓攀.建筑垃圾资源化方法和利用价值[J].中国资源综合利用,2019,37(11):63-65.
[26]	张佳,李赓,王琛.城市建筑寿命的空间规律及其影响因素:以兰州市城关区为例[J].城市问题,2018(11):21-27.
[27]	GB/T 50378-2006, 绿色建筑评价标准[S].中国建筑工业出版社,2006.