工业废渣改良泥水盾构渣土的路用性能试验研究

工业废渣改良泥水盾构渣土的路用性能试验研究
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作者:
                        郭沁颖1郭沁颖
1. 东南大学 交通学院
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李白云2李白云
2. 佛山市交通科技有限公司
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丁建文1丁建文
1. 东南大学 交通学院
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陈剑刚2陈剑刚
2. 佛山市交通科技有限公司
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孙帅1孙帅
1. 东南大学 交通学院
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马云龙2马云龙
2. 佛山市交通科技有限公司
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作者单位:1. 东南大学 交通学院;2. 佛山市交通科技有限公司
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基金项目:国家自然科学基金(51978159)；“十二五”国家科技支撑计划(2015BAB07B06)

Experimental study on the road performance of slurry shield tunnel residue improved by industrial waste residues

Author:

GUO Qin-ying ^¹
GUO Qin-ying
1. School of Transportation, Southeast University
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LI Bai-yun ^²
LI Bai-yun
2. Foshan Communications Technology Co., LTD
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DING Jian-wen ^¹
DING Jian-wen
1. School of Transportation, Southeast University
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CHEN Jian-gang ^²
CHEN Jian-gang
2. Foshan Communications Technology Co., LTD
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SUN Shuai ^¹
SUN Shuai
1. School of Transportation, Southeast University
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MA Yun-long ^²
MA Yun-long
2. Foshan Communications Technology Co., LTD
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Affiliation:

1. School of Transportation, Southeast University;2. Foshan Communications Technology Co., LTD

Fund Project:

National Natural Science Foundation of China (No. 51978159); National Science and Technology Support Project in "Twelfth Five-Year" (No. 2015BAB07B06)

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参考文献 [27]

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摘要:

为实现泥水盾构废弃渣土的资源化利用，在石灰这一传统改良材料的基础上，通过掺入碱渣、脱硫石膏等工业废渣，以期将盾构渣土改良为路基填料。通过室内击实试验、CBR试验、无侧限抗压强度试验、干湿循环试验以及微观试验，研究了石灰-碱渣、石灰-脱硫石膏改良盾构渣土的力学性能及其浸水稳定性与耐久性，并分析了其改良机理。结果表明：掺入改良材料后，渣土的力学性能得到了很大改善，水稳性与耐久性也大幅提高，具有较好的路用力学性能，其中石灰-脱硫石膏组的整体水稳性与耐久性优于石灰-碱渣组，干湿循环的过程中，掺3%脱硫石膏的试样耐久性相对较好，在循环期间仅出现细小裂缝并未贯穿试样。研究表明，盾构渣土经过石灰与脱硫石膏等复合改良后具有良好的路用力学性能，可以作为路基填筑材料使用。

关键词:盾构渣土;工业废渣; 力学性能;干湿循环;微观机理

Abstract:

This study is carried out to realize the resource utilization of mud water shield residue. Industrial waste residues such as alkali slag and desulfurization gypsum are reasonably used to be combined with the traditional lime, in order to convert waste mud into qualified roadbed filling materials. Through the laboratory compaction tests, CBR tests, unconfined compressive strength tests, wetting-drying cycle tests and microscopic tests, the mechanical properties, immersion stability and durability of shield tunnel residue improved by lime-alkali slag and lime-desulfurization gypsum were studied, and the improvement mechanism was analyzed. The test results show that the mechanical properties of the soil were improved significantly after compound improvement. The water stability and durability were also greatly improved, with better mechanical properties for road use. Among them, the overall water stability performance and durability of the lime - desulfurization gypsum groups were better than the lime - alkali slag groups. During the wetting-drying cycles, the durability of the specimens mixed with 3% desulfurization gypsum was relatively good, with only small cracks not penetrating the specimens during the cycles. The study shows that the shield tunnel residue has good mechanical properties for road use after compound improvement of lime and desulfurization gypsum, and can be used as roadbed filling materials.

Key words:shield tunnel residue; industrial waste residues; mechanical properties; wetting-drying cycle; microscopic mechanism

参考文献

[1] Koyama Y. Present status and technology of shield tunneling method in Japan[J]. Tunnelling and Underground Space Technology, 2003, 18(2): 145-159.

[2] 陈蕊,杨凯,肖为,等. 工程渣土的资源化处理处置分析[J]. 环境工程, 2020, 38(03): 22-26.CHEN R, YANG K, XIAO W, et al. Analysis on recycling treatment and disposal of engineering slag [J]. Environmental Engineering, 2020, 38(3): 22-26. (in Chinese)

[3] 李泽闯,程培峰,胡志文,等. 土石路堤压实质量控制与碾压动力响应模拟分析[J]. 土木与环境工程学报(中英文), 2021, 43(04): 33-41.LI Z C, CHENG P F, HU Z W, et al. Compaction quality control and rolling dynamic response simulation analysis of earth-rock embankment [J]. Journal of Civil and Environmental Engineering, 2021, 43(04): 33-41. (in Chinese)

[4] 中国公路学报编辑部. 中国路基工程学术研究综述·2021[J]. 中国公路学报, 2021, 34(03): 1-49.Editorial Department of China Journal of Highway and Transport. Review on China’s subgrade engineering research·2021 [J]. China Journal of Highway and Transport, 2021, 34(03): 1-49. (in Chinese)

[5] 朱敏. 改良黄土物理力学性质及路用性研究[D].陕西:长安大学, 2021.ZHU M. Research on physical mechanics properties and road usage of improved loess [D]. Shangxi: Chang’an University, 2021. (in Chinese)

[6] 张涛,刘松玉,蔡国军,等. 木质素改良粉土热学与力学特性相关性试验研究[J]. 岩土工程学报, 2015, 37(10): 1876-1885.ZHANG T, LIU S Y, CAI G J, et al. Experimental study on relationship between thermal and mechanical properties of treated silt by lignin [J]. Chinese Journal of Geotechnical Engineering, 2015, 37(10): 1876-1885. (in Chinese)

[7] 牛雷,徐丽娜,郑俊杰. 纤维对水泥土加固效果影响的试验研究[J]. 土木与环境工程学报(中英文), 2021, 43(02): 35-40.LIU L, XU L N, ZHENG J J. Experimental study on the reinforcement effect of fiber on cemented soil [J]. Journal of Civil and Environmental Engineering, 2021, 43(02): 35-40. (in Chinese)

[8] 赵天宇,曹志伟,张宗伟,等. 石灰与水泥对甘肃省黄土路基填料改良效果研究[J]. 公路, 2021, 66(10): 51-57.ZHAO T Y, CAO Z W, ZHANG Z W, et al. Research on improvement effect of lime and cement on loess subgrade filler in Gansu Province [J]. Highway, 2021, 66(10): 51-57. (in Chinese)

[9] El Shinawi A. Instability improvement of the subgrade soils by lime addition at Borg El-Arab, Alexandria, Egypt [J]. Journal of African Earth Sciences, 2017, 130: 195-201.

[10] Susan D R, George M F, Thomas L B, et al. Rapid chemical stabilization of soft clay soils [J]. Transportation Research Record, 2007, 2026(1): 39-46.

[11] 张赛,章剑青,尚石磊,等. 南京长江漫滩废弃粉土改良用作路基填料的室内试验研究[J/OL]. 土木与环境工程学报(中英文).https://kns.cnki.net/kcms/detail/50.1218.tu.20211004.1842.004.html.HANG S, ZHANG J Q, SHANG S L, et al. Laboratory investigation on the solidified waste silt from Nanjing Yangtze river floodplain as subgrade filling [J/OL]. Journal of Civil and Environmental Engineering. https://kns.cnki.net/kcms/detail/50.1218.tu.20211004.1842.004.html.

[12] 杜延军,刘松玉,覃小纲,等. 电石渣稳定过湿黏土路基填料路用性能现场试验研究[J]. 东南大学学报(自然科学版), 2014, 44(02): 375-380.DU Y J, LIU S Y, QIN X G, et al. Field investigations on performance of calcium carbide residues stabilized over-wet clayey soils used as highway subgrade materials [J]. Journal of Southeast University (Natural Science Edition), 2014, 44(02): 375-380. (in Chinese)

[13] 何俊,石小康,栗志翔. 水玻璃-碱渣-矿渣固化高含水率淤泥的强度性质[J]. 工程地质学报, 2019, 27(04): 729-736.HE J, SHI X K, LI Z X. Strength properties of dredged silt at high water con-tent treated with sodium silicate, soda residue and ground granulated blastfurnace slag [J]. Journal of Engineering Geology, 2019, 27(04): 729-736. (in Chinese)

[14] 姜起斌. 深茂铁路阳西至马踏段高液限土改良研究[D]. 四川: 西南交通大学, 2019.JIAN Q B. Study on improvement of high liquid limit soil in Yangxi-Mata Section of Shenzhen-Maoming Railway [D]. Sichuan: Southwest Jiaotong University, 2019. (in Chinese)

[15] 章为民,戴济群,王芳. 高液限路基土改良设计方法研究[J]. 路基工程, 2006(5): 76-77.ZHANG W M, DAI J Q, WANG F. Research for design method of the HLL clay subgrade soil stabilization [J]. Subgrade Engineering, 2006(5): 76-77. (in Chinese)

[16] 公路土工试验规程:JTG 3430—2020 [S]. 北京 : 人民交通出版社, 2020.Test methods of soils for highway engineering:JTG 3430—2020 [S]. Beijing: China Communications Press, 2020. (in Chinese)

[17] Masashi K, Supakij N, Takeshi K. Utilization of Stainless-Steel Slag by Cement Hardening[J]. Soils Foundations, 1993, 33(3): 118-129.

[18] 潘浩. 赤泥磷石膏固化重金属污染土的特性和机理研究[D]. 江苏: 东南大学, 2020.PAN H. Study on characteristic and mechanism of red mud and phosphogysum solidifying heavy metal contaminated soil [D]. Jiangsu: Southeast University, 2020. (in Chinese)

[19] 孙树林,郑青海,唐俊,等. 碱渣改良膨胀土室内试验研究[J]. 岩土力学, 2012, 33(06): 1608-1612.SUN S L, ZHENG Q H, TANG J, et al. Experimental research on expansive soil improved by soda residue [J]. Rock and Soil Mechanics, 2012, 33(06): 1608-1612. (in Chinese)

[20] Celestine O. Okagbue. Stabilization of Clay Using Woodash [J]. Journal of Materials in Civil Engineering, 2007, 19(1): 14-18.

[21] Akcanca F, Aytekin M. Effect of wetting–drying cycles on swelling behavior of lime stabilized sand–bentonite mixtures [J]. Environmental Earth Sciences, 2012, 66(1): 67-74.

[22] 谈云志,孔令伟,郭爱国,等. 红黏土路基填筑压实度控制指标探讨[J]. 岩土力学, 2010, 31(03): 851-855.TAN Y Z, KONG L W, GUO A G, et al. Discussion on the compaction degree index of subgrade filled with laterite [J]. Rock and Soil Mechanics, 2010, 31(03): 851-855. (in Chinese)

[23] 李芳菲,华渊,刘文化,等. 干湿循环条件下水泥固化疏浚淤泥的物理力学特性[J]. 硅酸盐通报, 2019, 38(02): 344-350.LI F F, HUA Y, LIU W H, et al. Physico-mechanical characteristics of cement-solidified dredged sludge under drying and wetting cycle [J]. Bulletin of the Chinese Ceramic Society, 2019, 38(02): 344-350. (in Chinese)

[24] 袁润章. 胶凝材料学[M]. 武汉:武汉工业大学出版社, 1996.YUAN R Z. Cementitious Material Science [M]. Wuhan:Wuhan Industrial University Press, 1996. (in Chinese)

[25] 李广信, 张丙印, 于玉贞,等. 土力学[M]. 北京: 清华大学出版社, 2013.LI G X, ZHANG B Y, YU Y Z, et al. Soil mechanics [M]. Beijing: Tsinghua University Press, 2013. (in Chinese)

[26] 查甫生,刘松玉,杜延军. 石灰-粉煤灰改良膨胀土试验[J]. 东南大学学报(自然科学版), 2007(02): 339-344.ZHA F S, LIU S Y, DU Y J. Experiment on improvement of expansive clays with lime-fly ash [J]. Journal of Southeast University (Natural Science Edition), 2007(02): 339-344. (in Chinese)

[27] 惠会清,胡同康,王新东. 石灰、粉煤灰改良膨胀土性质机理[J]. 长安大学学报(自然科学版), 2006(02): 34-37.UI H Q, HU T K, WANG X D. Improved mechanism of expansive soils by lime and fly-ash [J]. Journal Of Chang''an University (Natural Science Edition), 2006(02): 34-37.

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收稿日期:2022-09-16
最后修改日期:2022-11-26
录用日期:2022-11-27
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