多孔质混凝土植被恢复组合结构与材料性能研究

材料导报

2020, Vol. 34

Issue (Z1): 199-202

无机非金属及其复合材料

多孔质混凝土植被恢复组合结构与材料性能研究

李义强¹, 李智², 赵斌¹, 刘磊², 蓝群力³, 张新天³, 卞立波³

1 北京市首发天人生态景观有限公司,北京 100083;
2 北京市首都公路发展集团有限公司,北京 100161;
3 北京建筑大学土木与交通工程学院,北京 100044

Study on Composite Structure and Material Properties of Porous ConcreteVegetation Restoration

LI Yiqiang¹, LI Zhi², ZHAO Bin¹, LIU Lei², LAN Qunli³, ZHANG Xintian³, BIAN Libo³

1 Beijing Shoufa Tianren Ecological Landscape Co.,Ltd., Beijing 100083, China;
2 Beijing Capital Highway Development Group Co., Ltd., Beijing 100161, China;
3 School of Civil and Transportation Engineering, Beijing University of Civil Engineering and Architecture, Beijing 100044, China

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摘要针对利用框格梁结构进行加固的高陡边坡,提出了一种新型组合结构与材料对其进行植被恢复,可以满足结构稳定性和植物生长性能的要求。此结构将多孔质混凝土基础层、客土层与植生层组合为一体,研究内容包括现场调研、室内试验、小样本生长试验等,确定利用工程废渣的多孔质混凝土材料组成,并进行了各结构层的性能分析。

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关键词: 多孔质混凝土高陡边坡植被恢复组合结构工程废渣

Abstract: Aiming at the high-steep slopes which are strengthened by the anchor frame structure, this paper proposes a new combined structure and material for vegetation restoration. Through field investigation, indoor performance test, small sample growth test, etc., the performance analysis of raw materials and structural layers was carried out on the porous concrete composite structure using engineering waste. The combined structure combines the porous concrete foundation layer, the soil layer and the plant layer, and satisfies the requirements of structural stability and plant growth performance.

Key words: porous concrete high and steep rock slope vegetation restoration combined structure engineering waste

发布日期: 2020-07-01

ZTFLH:

U414

作者简介: 李义强,首发生态公司党总支书记、董事长,园林绿化高级工程师,北京林业大学研究生校外导师。在生态文明建设战略背景下,引领高速公路绿化企业转型升级成为“交通领域生态环保专家”和“山水林田湖草一体化修复治理专家”。立足“绿色公路”,创新近自然修复技术、践行海绵城市建设、营建湿地景观,取得一系列核心理念和技术,主持编制国家标准《裸露坡面植被恢复技术标准》,发表核心期刊论文十余篇,拥有多项国家专利。

引用本文:

李义强, 李智, 赵斌, 刘磊, 蓝群力, 张新天, 卞立波. 多孔质混凝土植被恢复组合结构与材料性能研究[J]. 材料导报, 2020, 34(Z1): 199-202.
LI Yiqiang, LI Zhi, ZHAO Bin, LIU Lei, LAN Qunli, ZHANG Xintian, BIAN Libo. Study on Composite Structure and Material Properties of Porous ConcreteVegetation Restoration. Materials Reports, 2020, 34(Z1): 199-202.

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http://www.mater-rep.com/CN/ 或 http://www.mater-rep.com/CN/Y2020/V34/IZ1/199

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