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【目的】为实现长江疏浚砂就近用于入海口水工构筑物建设,【方法】定义疏浚砂占细骨料质量之比为掺量,设计5种掺量不同的混凝土小梁试件,将试件置于4种不同的盐环境(NaCl和Na_2SO4溶液组成)中进行全浸泡侵蚀,对侵蚀时间为30 d、60 d、90 d及未侵蚀的试件开展非标准三点弯试验,研究其力学性能并结合声发射技术监测裂缝开展情况。【结果】结果显示:(1)随着掺量升高,混凝土抗裂性能逐渐降低,掺量每升高12.5%,断裂峰值荷载相应下降5%左右,当掺量大于或等于37.5%,断裂峰值荷载骤降30%以上;(2)离子浓度越高,侵蚀效果越明显,而加入Cl-可缓解SO■对混凝土的侵蚀进程;(3)分析AF-RA值可知前期开裂以拉伸裂缝为主,剪切裂缝占比随裂缝扩展过程逐渐增大,掺量12.5%时剪切裂缝占比最小,此时裂缝发育最好;离子浓度越高剪切裂缝占比越大,裂缝发育越不完全。【结论】疏浚砂的掺入以及盐环境的侵蚀对混凝土的力学性能有明显的劣化作用,声发射累计振铃计数呈三阶段性,反映断裂破坏特性,验证了边界效应。研究成果为疏浚砂混凝土在盐环境下的水利水运工程应用提供了试验依据。
Abstract:[Objective]In order to realize that dredged sand from the Yangtze River can be used in construction of hydraulic structures near estuary, [Methods]proportion of dredged sand to the mass of fine aggregate was defined as the Content. 5 kinds of concrete trabecular specimens with different Content were designed, and the specimens were placed in 4 different salt environments(composed of NaCl and Na_2SO4 solution) for full immersion erosion. Non-standard three-point bending tests were carried out on the specimens with erosion time of 30 d, 60 d and 90 d and those without erosion. The mechanical properties were studied and the crack development was monitored by acoustic emission(AE) technology.[Results]The results show:(1) Crack resistance of concrete gradually decreases with increase of the dosage. For every 12.5% increase, the peak breaking load decreases by about 5%. When the dosage is greater than or equal to 37.5%, the peak breaking load drops by more than 30%.(2) The higher ion concentration is, the more obvious erosion effect is, and addition of Cl- can alleviate the erosion process of SO■.(3) The analysis of AF-RA values shows that tensile cracks are the main cracks in early stage, and the proportion of shear cracks increases gradually with the process of crack expansion. The proportion of shear cracks is the smallest when the content is 12.5%, and the fracture development is the best. The higher the ion concentration, the larger the proportion of shear fractures, the more incomplete the fracture development. The research result provide experimental basis for the application of dredged sand concrete in water conservancy and water transportation engineering under salt environment.[Conclusion]The addition of dredged sand and the erosion of salt environment have obvious deterioration effect on the mechanical properties of concrete. The accumulate counts of AE showed three stages, reflecting fracture characteristics and verifying boundary effect.
[1] 李青云.推进长江航道疏浚砂综合利用[N].中国水运报,2020-04-01(001).LI Qingyun.Promoting comprehensive utilization of dredged sand in Yangtze River[N].China Water Transport News,2020-04-01(001).
[2] 陈徐东,吴朝国,陈璋,等.养护温度对长江下游疏浚超细砂浆特性影响机制[J].复合材料学报,2023,40(4):2308-2320.CHEN Xudong,WU Chaoguo,CHEN Zhang,et al.Influence mechanism of curing temperature on the characteristics ofdredged ultrafine mortar from Yangtze River[J].Acta Materiae Compositae Sinica,2023,40(4):2308-2320.
[3] 李升涛,陈徐东,张伟,等.基于长江下游超细疏浚砂的碱激发矿渣混凝土力学性能[J].复合材料学报,2022,39(1):335-343.LI Shengtao,CHEN Xudong,ZHANG Wei,et al.Mechanical properties of alkali activated slag concrete with ultra fine dredged sand from Yangtze River[J].Acta Materiae Compositae Sinica,2022,39(1):335-343.
[4] 吴鲸,封学军,陈徐东,等.长江下游疏浚特细砂碱矿渣混凝土动态力学特性试验研究[J].混凝土,2022(1):116-121.WU Jing,FENG Xuejun,CHEN Xudong,et al.Experimental study on dynamic mechanical properties of dredged super fine sand and alkali slag concrete in the lower reaches of the Yangtze River[J].Concrete,2022(1):116-121.
[5] 李光伟.水工特细砂混凝土性能试验[J].水利水电科技进展,2006(4):18-20.LI Guangwei.Experimental study on characteristics of hydraulic super-fine sand concrete[J].Advances in Science and Technology of Water Resources,2006(4):18-20.
[6] ZHAO M,DAI M,LI J,et al.Case study on performance of pumping concrete with super-fine river-sand and manufactured-sand[J].Case Studies in Construction Materials,2023,18:e01850.
[7] DANG J,ZHAO J.Influence of waste clay bricks as fine aggregate on the mechanical and microstructural properties of concrete[J].Construction and Building Materials,2019,228:116757.
[8] KUMAR K,BOKKA D,MANNE M,et al.Towards greener construction:Assessing the mechanical properties of concrete with demolition waste and quarry dust blends[J].Journal of Physics:Conference Series,2024,2779:012045.
[9] LIU H,ZHANG Q,LI V,et al.Durability study on engineered cementitious composites (ECC) under sulfate and chloride environment[J].Construction & Building Materials,2017,133:171-181.
[10] CARé S,HERVé E.Application of a n-phase model to the diffusion coefficient of chloride in mortar[J].Transport in Porous Media,2004,56(2):119-135.
[11] 张全红,王涛,穆松,等.不同侵蚀环境下喷射混凝土耐久性提升技术及作用机理[J].硅酸盐通报,2024,43(4):1410-1419.ZHANG Quanhong,WANG Tao,MU Song,et al.Durability improvement and mechanism of shotcrete under different corrosion environments[J].Bulletin of the Chinese Ceramic Society,2024,43(4):1410-1419.
[12] QIAO H,HAKUZWEYEZU T,YANG B.Experimental study on sulfate erosion resistance of nano-CaCO3 modified concrete[J].Canadian Journal of Civil Engineering,2022,49(4):590-596.
[13] 张宇,张志伟,徐强,等.盐浸-干湿-冻融耦合作用下混凝土坝强震开裂机理[J].南水北调与水利科技(中英文),2024,22(1):158-165.ZHANG Y,ZHANG Z W,XU Q,et al.The mechanism of strong seismic cracking of concrete dams under the coupled action of salt immersion,dry-wet cycle,and freeze-thaw cycle[J].South-to-North Water Transfers and Water Science & Technology,2024,22(1):158-165.
[14] 杨军兆,张戎令,薛彦瑾,等.基于分形维数的硫酸盐环境下混凝土抗蚀系数及微观机理研究[J].材料导报,2025,39(7):93-99.YANG Junzhao,ZHANG Rongling,XUE Yanjin,et al.Study on corrosion resistance coefficient and micro-mechanism of concrete in sulphate environment based on fractal dimension[J].Materials Reports,2025,39(7):93-99.
[15] RAGOUG R,METALSSI,OTHMAN O,et al.Durability of cement pastes exposed to external sulfate attack and leaching:Physical and chemical aspects[J].Cement and Concrete Research,2019,116:134-145.
[16] 张佳豪,王海龙,刘思盟,等.干湿循环作用下硅粉轻骨料混凝土抗硫酸盐性能分析[J].排灌机械工程学报,2023,41(1):32-37.ZHANG Jiahao,WANG Hailong,LIU Simeng,et al.Analysis of sulfate resistance of silica fume lightweight aggregate concrete under dry-wet cycle[J].Journal of Drainage and Irrigation Machinery Engineering,2023,41(1):32-37.
[17] 罗滔,黄陈霖,张天祺,等.堆石混凝土劈裂抗拉破坏过程中声发射特征分析[J].水利水电技术(中英文),2024,55(1):40-50.LUO Tao,HUANG Chenlin,ZHANG Tianqi,et al.Analysis of acoustic emission characteristics during the splitting tensile failure process of rock filled concrete[J].Water Resources and Hydropower Engineering,2024,55(1):40-50.
[18] LI S,FAN X,CHEN X,et al.Development of fracture process zone in full-graded dam concrete under three-point bending by DIC and acoustic emission[J].Engineering Fracture Mechanics,2020,230(3):106972.
[19] 范向前,刘决丁,胡少伟,等.中央带裂缝混凝土循环拉伸断裂试验Felicity效应[J].复合材料学报,2019,36(12):2968-2974.FAN Xiangqian,LIU Jueding,HU Shaowei,et al.Cyclic tensile fracture test of concrete with central crack and felicity effect[J].Acta Materiae Compositae Sinica,2019,36(12):2968-2974.
[20] DU F,LI D,LI Y.Fracture mechanism and damage evaluation of FRP/steel-concrete hybrid girder using acoustic emission technique[J].Journal of Materials in Civil Engineering,2019,31(7).DOI:10.1061/(ASCE)MT.1943-5533.0002758.
[21] XIE F,LI J,ZHAO G,et al.Experimental study on performance of cast-in-situ recycled aggregate concrete under different sulfate attack exposures[J].Construction and Building Materials,2020,253:119144.
[22] XU S,REINHARDT H W,WU Z,et al.Comparison between the double-K fracture model[J].Otto Graf Journal,2003,24:131-157.
[23] ALYAMI M H,ALRASHIDI R S,MOSAVI H,et al.Potential accelerated test methods for physical sulfate attack on concrete[J].Construction and Building Materials,2019,229:116920.
[24] 梁咏宁,黄君一,林旭健,等.氯盐对受硫酸盐腐蚀混凝土性能的影响[J].福州大学学报(自然科学版),2011,39(6):947-951.LIANG Yongning,HUANG Junyi,LIN Xujian,et al.The effect of chloride on concrete under sulfate attack[J].Journal of Fuzhou University(Natural Science Edition),2011,39(6):947-951.
[25] 耿欧,孙倩,李大贺.氯盐对再生混凝土硫酸盐侵蚀的抑制作用研究[J].建筑科学与工程学报,2020,37(6):108-116.GENG Ou,SUN Jing,LI Dahe.Study on inhibitory effect of chlorine salton sulfate corrosion of recycled concrete[J].Journal of Architecture and Civil Engineering,2020,37(6):108-116.
[26] 李玉根,张慧梅,刘光秀,等.风积砂混凝土基本力学性能及影响机理[J].建筑材料学报,2020,23(5):1212-1221.LI Yugen,ZHANG Huimei,LIU Guangxiu,et al.Mechanical properties and influence mechanism of aeolian sand concrete[J].Journal of Building Materials,2020,23(5):1212-1221.
[27] 吴朝国,陈徐东,宁英杰,等.静停时间对长江下游蒸养疏浚砂浆特性的影响[J].土木与环境工程学报(中英文),2024,46(4):193-201.WU Chaoguo,CHEN Xudong,NING Yingjie,et al.The influence of static stop time on the characteristics of steam dredged mortar in the Yangtze River[J].Journal of Civil and Environmental Engineering,2024,46(4):193-201.
[28] 冯璐,陈徐东,张锦华,等.基于声发射技术的非标准自密实混凝土三点弯曲梁动态断裂特性[J].复合材料学报,2021,38(2):630-640.FENG Lu,CHEN Xudong,ZHANG Jinhua,et al.Dynamic fracture characteristics of non-standard three-point bendingself-compacting concrete beams based on acoustic emission[J].Acta Materiae Compositae Sinica,2021,38(2):630-640.
[29] 谢秋桐,陈徐东,白银,等.循环损伤后全级配混凝土断裂过程声发射特征[J].南水北调与水利科技(中英文),2024,22(2):359-367.XIE Qiutong,CHEN Xudong,BAI Yin,et al.Acoustic emission characteristics of full-graded concrete fracture process after cyclic damage[J].South-to-North Water Transfers and Water Science & Technology,2024,22(2):359-367.
[30] CHEN C,FAN X,CHEN X.Experimental investigation of concrete fracture behavior with different loading rates based on acoustic emission[J].Construction and Building Materials,2020,237:117472.
[31] HAN Q H,YANG G,XU J,et al.Acoustic emission data analyses based on crumb rubber concrete beam bending tests[J].Engineering Fracture Mechanics,2019,210:189-202.
基本信息:
DOI:10.13928/j.cnki.wrahe.2025.11.018
中图分类号:U654
引用信息:
[1]陈璋,石丹丹,陈徐东.复合盐环境下疏浚砂混凝土梁断裂性能[J].水利水电技术(中英文),2025,56(11):230-242.DOI:10.13928/j.cnki.wrahe.2025.11.018.
基金信息:
国家自然科学基金项目(52379124); 中央高校基本科研业务费(B230204021)