湖底淤泥固化土的环境耐久性研究
摘要:为了评价淤泥固化土的环境耐久性,采用矿渣体系的碱激发胶凝材料(矿渣粉、偏高岭土、石灰和水玻璃)和普通硅酸盐水泥为固化剂,通过开展无侧限抗压、冻融循环、Na2SO4及NaCl浸泡侵蚀、扫描电镜和EDS-Mapping试验,分析了侵蚀环境下固化淤泥土的典型水化产物、强度演变规律、质量损失率和微观结构特征,结果表明,碱激发固化淤泥内部生成的水化硅铝酸钠凝胶(N-A-S-H)能有效提高强度,但是冻融循环和浸泡侵蚀均会导致固化土强度劣化;水泥固化淤泥受硫酸盐侵蚀后,钙矾石会呈现簇状发展而产生膨胀开裂,导致强度下降;碱激发固化剂的抗氯离子能力优于硫酸根离子,综合环境耐久性优于普通硅酸盐水泥。
Abstract:In order to evaluate the environmental durability of solidified lake-bottom sediment, alkali activated cementing material of slag system (slag powder, metakaolin, lime and sodium silicate) and traditional cement were used as curing agent. Through unconfined compression, freezing-thawing cycle, Na2SO4 and NaCl erosion leaching, scanning electron microscopy and EDS-Mappingtests, the typical hydrates, strength evolution, mass loss rate and microstructure characteristics of solidified sediment in erosion environment were analyzed. The results show that a large amount of hydrated sodium silicate aluminate gel(N-A-S-H)was formed in the alkali-excited solidified sediment. The freezing-thawing cycle and erosion leaching can lead to the deterioration of the strength of solidified sediment. The development of ettringite led to expansion and cracking when the cement-solidified sediment was eroded by sulfate, which resulted in the decrease of strength. The alkali-activated curing agent has better chloride ion resistance than sulfate ion and better comprehensive environmental durability than conventional Portland cement.
中文标题:
湖底淤泥固化土的环境耐久性研究
Study on Environmental Durability of Solidified Lake-bottom Sediment
作者:
王矿山1,,庞龙1,戴振鑫1,章晖1,张新军2
Wang Kuangshan1,,Pang Long1,Dai Zhenxin1,Zhang Hui1,Zhang Xinjun2
作者简介:王矿山,男,1981年生,汉族,安徽宿州人,大学本科,高级工程师,主要从事工程技术、投资、咨询方面的研究。E-mail:wsq@ahszu.edu.cn
通讯地址:
1.中国电建集团华东勘测设计研究院有限公司,浙江杭州 310000 2.中铁一局集团有限公司,陕西西安 710000
1.PowerChinaHuadongSurvey,DesignandResearchInstituteCo.,Ltd.,Hangzhou310000,Zhejiang,China 2.ChinaRailwayFirstBureauGroupCo.,Ltd.,Xi’an710000,Shaanxi,China
中图分类号:TU 411
doi:10.3969/j.issn.1007-2993.2023.04.014
出版物:岩土工程技术
收稿日期:2022-05-23
修回日期:2022-08-14
录用日期:2022-12-09
刊出日期:2023-08-08
关键词:固化淤泥,强度,冻融循环,侵蚀,耐久性
Key words:solidified sediment,strength,freezing-thawing cycle,erosion,durability
文档包含图片数量:图片(8)张
文档包含表格数量:表格(2)个
参考文献:
[1]王文军,袁飞飞,蒋建良,等. 高含水率吹填淤泥固化土强度特性及预测模型[J]. 地下空间与工程学报,2021,17(2):461-467.
[2]张志勇,严 娟. 城市河道淤泥固化技术试验研究[J]. 人民长江,2021,52(12):210-213.
[3]周瑞荣,刘 磊,刘 辉,等. 厂拌淤泥固化土的研究及工程应用[J]. 中国港湾建设,2021,41(12):50-54.
[4]黄英豪,戴济群,徐 锴. 新拌固化淤泥的流动性和黏滞性试验研究[J]. 岩土工程学报,2022,44(2):235-244.
[5]易耀林,李 晨,孙 川,等. 碱激发矿粉固化连云港软土试验研究[J]. 岩石力学与工程学报,2013,32(9):1820-1826. doi: 10.3969/j.issn.1000-6915.2013.09.013
[6]孙秀丽,童 琦,刘文化,等. 碱激发粉煤灰和矿粉改性疏浚淤泥力学特性及显微结构研究[J]. 大连理工大学学报,2017,57(6):622-628.
[7]周恒宇,王修山,胡星星,等. 地聚合物固化淤泥强度增长影响因素及机制分析[J]. 岩土力学,2021,42(8):2089-2098.
[8]吴 俊,征西遥,杨爱武,等. 矿渣–粉煤灰基地质聚合物固化淤泥质黏土的抗压强度试验研究[J]. 岩土力学,2021,42(3):647-655.
[9]陈 锐,郝若愚,李 笛,等. 碱激发材料固化低液限粉黏土路用性能及抗冻融特性研究[J]. 工程地质学报,2022,30(2):327-337.
[10]王东星,肖 杰,李丽华,等. 基于碳化–固化技术的武汉东湖淤泥耐久性演变微观机制[J]. 岩土力学,2019,40(8):3045-3053.
[11]谈云志,柯 睿,陈君廉,等. 偏高岭土–石灰增强水泥固化淤泥的耐久性研究[J]. 岩土力学,2020,41(4):1-8.
[12]王臻华,项 伟,吴雪婷,等. 复合固化剂固化淤泥的耐久性和稳定性研究[J]. 安全与环境工程,2019,26(4):74-86. doi: 10.13578/j.cnki.issn.1671-1556.2019.04.012
[13]WANG S,LANG L,WEI M L,et al. Strength and microstructural characteristics of cement-solidified salt-rich dredged silt modified by nanoparticles[J]. Marine Georesources & Geotechnology,2021,40(8):1-12.
[14]周建伟,余保英,孔亚宁,等. 氧化镁质和硫铝酸钙膨胀剂对工程水泥基复合材料性能的影响[J]. 硅酸盐通报,2022,41(1):33-40. doi: 10.3969/j.issn.1001-1625.2022.1.gsytb202201006
基金项目:
基金项目:安徽省高校自然科学研究重点项目(2022AH051388;KY2020-ZX-24)
- 文件大小:
- 3.32 MB
- 下载次数:
- 60
-
高速下载
|
|
