共查询到20条相似文献,搜索用时 31 毫秒
1.
Cui Ming-Juan Zheng Jun-Jie Chu Jian Wu Chao-Chuan Lai Han-Jiang 《Acta Geotechnica》2021,16(5):1377-1389
Calcareous sands have abundant intraparticle pores and are prone to particle breakage. This often leads to poor engineering properties, which poses a challenge to coastal infrastructure construction. A study using bio-cementation to improve the engineering properties of calcareous sand is presented in this paper. The macro- and microscopic properties of bio-cemented calcareous sand were characterized by drained triaxial tests and scanning electron microscopy observations. Experimental results show that the precipitated calcium carbonate can effectively fill the intra- and interparticle pores and bond adjacent particles, thus enhancing the shear strength of calcareous sand. The special structures (e.g. abundant intraparticle pores and rough surface) and mineral components (i.e. calcium carbonate) of calcareous sand are beneficial for improving bacterial retention in soil, which leads to a relatively uniform and dense calcium carbonate distribution on the sand particle surface, exhibiting a layer-by-layer growth pattern. This growth pattern and the abundant interparticle pores would result in less effective calcium carbonate. The strength enhancement of bio-cemented calcareous sand is significantly lower than that of bio-cemented silica sand at the same calcium carbonate content, which may be caused by the differences in the following: (a) soil skeleton strength; (b) the amount of effective calcium carbonate; and (c) interparticle pore-filling of calcium carbonate.
相似文献2.
钙质砂广泛分布于热带海岸地区,其抗剪强度较低,在较高应力条件下极易破碎。因此,对以钙质砂为主要原料的地基材料进行加固,是海洋岩土工程领域的研究热点。基于尿素水解过程的碳酸钙成矿技术(MICP)是近年来地基材料加固领域的一项新技术。目前广泛使用的生物强化法实现MICP存在成本昂贵及环境适应性差等问题,制约了其大规模工程应用。研究采用原位生物激发MICP法对钙质砂进行加固,并对加固后试样开展直剪和一维压缩试验。结果表明:原位生物激发MICP方法可以在钙质砂中形成有效胶结,胶结水平最大可达6.26%。采用高浓度胶结溶液或增加注射次数可提高胶结水平。同时,加固后钙质砂的最大应力比、最大剪胀角以及残余内摩擦角均随胶结水平增加而显著增大,但竖向应力水平增大会抑制这些力学指标的增大。随胶结水平升高,试样压缩性显著减小;压缩后的原位激发MICP加固钙质砂中,细颗粒与粗颗粒的比例均随胶结水平的增加而增大。 相似文献
3.
Ming-Juan Cui Jun-Jie Zheng Rong-Jun Zhang Han-Jiang Lai Jun Zhang 《Acta Geotechnica》2017,12(5):971-986
Microbially induced calcite precipitation (MICP) is used increasingly to improve the engineering properties of granular soils that are unsuitable for construction. This shows MICP technique significant advantages such as low energy consumption and environmentally friendly feature. The objective of the present study is to assess the strength behaviour of bio-cemented sand with varying cementation levels, and to provide an insight into the mechanism of MICP treatment. A series of isotropic consolidated undrained compression tests, calcite mass measurement and scanning electron microscopy tests were conducted. The experimental results show that the strength of bio-cemented sand depends heavily on the cementation level (or calcite content). The variations of strength parameters, i.e. effective friction angle φ′ and effective cohesion c′, with the increase in calcite content can be well evaluated by a linear function and an exponential function, respectively. Based on the precipitation mechanism of calcite crystals, bio-clogging and bio-cementation of calcite crystals are correlated to the amount of total calcite crystals and effective calcite crystals, respectively, and contributed to the improvement in the effective friction angle and effective cohesion of bio-cemented sand, separately. 相似文献
4.
为了提升微生物固化砂土的效果,考虑火山灰的多孔结构及活性特征,设计进行了火山灰增强微生物诱导碳酸钙沉淀(MICP)固化砂土试验,综合宏观物理力学试验和微细观检测,系统分析了火山灰对微生物固化砂土的增强效果及增强机制。结果表明:(1)火山灰能够显著提高砂土微生物加固过程中的固菌率和胶结物产量,火山灰掺量在10%左右达到最佳,与常规MICP相比,固菌率提高了118.28%,胶结物生成量提高了29.55%。(2)火山灰的掺入提高了固化体的抗压强度和抵抗变形的能力,不同围压下固化体的抗压强度提升了52.26%~62.96%,破坏时的应变增加了100.00%~112.58%。(3)火山灰掺入后,固化体的孔隙大小及孔隙率明显减小,整体的密实性及抗渗性能进一步提升,孔隙率从20.12%减小为14.17%,渗透系数降低了一个数量级。(4)火山灰对微生物固化砂土的增强机制主要包括3个方面,一方面,火山灰在砂颗粒间起到了良好的充填作用,大幅减少了颗粒间的大孔隙,使得固化体的密实性增强;另一方面,火山灰良好的吸附作用有效提高了试样内细菌的含量,使固化体碳酸钙的产量及分布的均匀性均增加;第3方面,火山灰中的活性物质参与反应生成的胶凝物质与碳酸钙晶体形成复合凝胶体,使得固化体的胶结性能和密实程度进一步增强。 相似文献
5.
Ali Firat Cabalar 《Geotechnical and Geological Engineering》2011,29(4):411-418
Waste tires are used in some engineering applications and thereby reduce the potential impact on the environment, for example,
as lightweight materials in geotechnical engineering projects. This paper presents a brief literature review on geotechnical
applications of processed waste tires, and a laboratory study on the effect of tire shreds on the physical properties of two
different sands (fine angular sand and coarse rotund sand). Each type of sand was mixed four different percentages of rubber
particles; 5, 10, 20 and 50% by dry weight. Direct shear tests were employed to investigate the effect of rubber particles
on the shear strength of sands and internal friction angle. The addition of shredded waste rubber particles slightly decreased
both the internal angle of friction and the shear strengths of the sands within the tested stress and strain levels. Additionally,
a prediction model using stepwise regression (SR) method is proposed to calculate the shear strength of sands with the increasing
rubber content. The performance of accuracies of proposed SR models are quite satisfactory. The proposed SR models are presented
as relatively simple explicit mathematical functions for further use by researchers. 相似文献
6.
Mahmoud Ghazavi 《Geotechnical and Geological Engineering》2004,22(3):401-416
Waste materials such as waste tires, rubbers, and plastic materials are normally produced in every society, entering the environment
and causing serious problems. These problems may be somehow reduced by finding applications for them in engineering, for example,
as lightweight materials for backfill in geotechnical projects. To this aim, this paper demonstrates how shear strength characteristics
of sand mixed with various percentages of waste garden hose grains are altered. A relatively, uniform sand has been mixed
with waste hose grains in loose and slightly compacted states. Waste hose grains were prepared with special popular machinery
in a local area. Various sand-rubber mixtures having 0%, 10%, 15%, 20%, 50%, 70%, and 100% waste hose particles by weight
were chosen. The rubber grains were distributed in the sand such that uniform mixtures are obtained. In order to compare the
shear strength of different sand-rubber samples, two compaction states were considered. The results show that the influencing
parameters on shear strength characteristics of sand-rubber mixtures are normal stress, mixture unit weight, and rubber content.
With the selected waste hose particles, compaction states, and rubber contents, the initial friction angle φ1 does not change significantly. However, an apparent cohesion appears in the mixtures. From environmental point of view and
due to lightweight material for the sand-waste hose particles, it may be useful to use such materials in corresponding geotechnical
projects.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
7.
微生物固化技术(MICP)是岩土工程领域新兴起的一种不良地基处理技术,不同地基土体之间的颗粒粒径并不相同,其固化效果也可能存在一定差别。选用3种不同颗粒粒径范围的砂土进行微生物固化处理,并基于无侧限抗压强度试验、孔隙体积测量和洗酸处理,从宏观角度分析颗粒粒径对微生物固化效果的影响。结合扫描电镜测试,从细观角度对微生物固化机制进行了初探。研究结果表明,微生物固化砂土中碳酸钙晶体以颗粒簇形式堆积在砂土颗粒表面及颗粒间接触处,其尺寸随碳酸钙晶体堆叠程度的增加而增大;对于颗粒粒径较小的砂土,颗粒间孔隙较易被碳酸钙晶体填充密实,固化试样内有效碳酸钙晶体比例较大,“结构性”较强,无侧限抗压强度较高。 相似文献
8.
钙质砂是中国南海岛礁工程建设的主要建筑材料和地基土成份,其具有高孔隙、易破碎和强度低等不良工程地质特性。为改善钙质砂力学性能,提高其工程可靠性,提出利用微生物诱导碳酸钙沉积(MICP)协同纤维加筋改性钙质砂。文章通过开展无侧限抗压试验以及扫描电镜测试,对比分析不同纤维掺量下MICP固化钙质砂的力学响应特性及微观破坏机理。结果表明:(1)MICP技术能够有效固化钙质砂,并提升其力学强度;(2)纤维能够增加细菌定殖面积,提升碳酸钙沉积量,并由此提升试样延性和韧性,降低刚度;(3)应力应变曲线呈阶梯状多峰特征。在应力上升阶段,砂颗粒和碳酸钙会发生局部破碎;在峰后应力下降阶段,碳酸钙、砂颗粒、纤维的胶结作用增强了纤维的抗拔性能,限制了破坏面的发展;(4)碳酸钙、砂颗粒、纤维的耦合胶结作用是纤维加筋改善试样韧性、延性的根本原因。 相似文献
9.
微生物固化(microbial-induced calcite precipitation, 简称为MICP)技术是岩土工程领域新兴起的一种地基处理技术,利用微生物诱导产生的碳酸钙晶体胶结松散土颗粒,改善土体的力学特性。选用巴氏芽孢杆菌作为固化细菌,采用单一浓度(0.5、1.0 mol)和多浓度相结合(前期采用0.5 mol,后期采用1.0 mol)的化学处理方式注射胶结液(尿素/氯化钙混合液),研究化学处理方式对微生物固化砂土强度的影响。基于试验测试分析了固化砂土试样的强度、破坏模式以及碳酸钙含量。试验结果表明,化学处理方式对固化砂土试样的强度有显著影响,对破坏模式和碳酸钙含量无明显影响;多浓度相结合的化学处理方式能够以较少的灌浆次数获取较高强度的试样。最后,对化学处理方式对强度影响的机制进行深入分析。 相似文献
10.
Use of scrap tyres in isolation systems for seismic damping, requires a knowledge of the engineering properties of sand–rubber mixtures (SRM). The primary objective of this study is to assess the influence of granulated rubber and tyre chips size and the gradation of sand on the strength behaviour of SRM by carrying out large-scale direct shear tests. A large direct shear test has been carried out on SRM considering different granulated rubber and tyre chip sizes and compositions. The following properties were investigated to know the effect of granulated rubber on dry sand; peak shear stress, cohesion, friction angle, secant modulus and volumetric strain. From the experiments, it was determined that the major factors influencing the above-mentioned properties were granulated rubber and tyre chip sizes, percentage of rubber in SRM and the normal stress applied. It was observed that the peak strength was significantly increased with increasing granulated rubber size up to rubber size VI (passing 12.5 mm and retained on 9.5 mm), and by adding granulated rubber up to 30%. This study shows that granulated rubber size VI gives maximum shear strength values at 30% rubber content. It was also found that more uniformly graded sand gives an improved value of shear strength with the inclusion of granulated rubber when compared to poorly graded sand. 相似文献
11.
压力作用下颗粒发生破碎是引起砂土力学特性变化的重要因素之一, 对于钙质砂这种易破碎的材料更是如此。为进一步弄清颗粒破碎对钙质砂的应力-应变强度影响, 本文对钙质砂进行三轴固结排水剪切试验得到应力-应变曲线, 并筛分得到三轴试验前后钙质砂颗分曲线。通过引入Hardin定义的颗粒相对破碎率Br, 分析了相对密度、围压与颗粒破碎的关系及颗粒破碎对钙质砂应力-应变和抗剪强度的影响。结果表明:随围压的增大颗粒破碎增量逐渐减小, 直到破碎达到一个上限值, 此时围压和相对密度对颗粒破碎影响很小; 颗粒间的滑动标志着应力达到极限状态, 而颗粒破碎会阻碍应力达到极限状态, 在本实验中, 低围压时颗粒破碎少, 颗粒相对运动形式为滑移, 使应力-应变曲线为软化型, 高围压下颗粒破碎严重, 颗粒破碎在剪切过程中始终发生, 使应力-应变曲线呈应变硬化型; 颗粒破碎使体变从剪胀逐渐发展到剪缩, 且破碎越严重剪缩越严重; 在低围压下钙质砂强度主要由剪胀和咬合提供, 高围压下颗粒破碎严重, 剪胀消失, 咬合减小, 使峰值摩擦角减小, 抗剪强度降低。 相似文献
12.
为深入研究剪切速率对钙质砂强度和变形特征的影响,对钙质干砂进行不同剪切速率条件下的直剪试验。研究结果表明,随剪切速率从0.1 mm/min增至2.4 mm/min时钙质砂抗剪强度先减小后增大,其内摩擦角亦呈现出先减小后增大趋势,临界剪切速率为1.6 mm/min;低法向应力条件下钙质砂试样随剪切速率的增加更易于呈现剪胀现象,高法向应力条件下剪切速率从0.1 mm/min增长至1.6 mm/min时试样整体剪缩量逐渐减小;当剪切速率继续从1.6 mm/min增长至2.4 mm/min时试样最大剪缩量逐渐增加;不同法向应力水平条件下钙质砂加载速率效应的细观机制不同,较低应力水平条件下钙质砂加载速率效应主要由试样内部颗粒错动、换位、重新排列引起,在较高应力水平条件下钙质砂加载速率效应主要由颗粒破碎引起。 相似文献
13.
Ahmed AbdelRazek Rami M El-Sherbiny Hani A Lotfi 《Geomechanics and Geoengineering》2018,13(4):288-300
The use of granulated recycled rubber as a lightweight material in civil engineering applications has been widely growing over the past 20 years. Processed waste tires mixed with soils have been introduced as lightweight fills for slopes, retaining walls, and embankments. It has also been considered as a damping material under foundations in seismic zones. Understanding the properties of sand-rubber mixtures is essential to evaluate its performance in geotechnical applications. Isotopically consolidated drained (CD) triaxial tests were conducted to investigate the effect of rubber size, content and saturation condition on the mechanical properties of sand-rubber mixtures. Moreover, the compressibility of the sand-rubber mixtures under sustained loading was investigated through one dimensional consolidation tests. The unit weight, shear strength and stiffness of sand-rubber mixtures decreased whereas deformability increased at increased rubber content. A non-linear stress-strain response was observed, that changed from brittle to ductile behaviour at increased rubber content. Sand-rubber mixtures, under one dimensional loading, exhibited significant settlement that increased as rubber content increased. 相似文献
14.
The effect of grain size distribution on the unconfined compressive strength (UCS) of bio-cemented granular columns is examined. Fine and coarse aggregates were mixed in various percentages to obtain five different grain size distributions. A four-phase percolation strategy was adopted where a bacterial suspension and a cementation solution (urea and calcium chloride) were percolated sequentially. The results show that a gap-graded particle size distribution can improve the UCS of bio-cemented coarser granular materials. A maximum UCS of approximately 575 kPa was achieved with a particle size distribution containing 75% coarse aggregate and 25% fine aggregate. Furthermore, the minimum UCS obtained has applications where mitigation of excessive bulging of stone/sand columns, and possible slumping that might occur during their installation, is needed. The finding also implies that the amount of biochemical treatments can be reduced by adding fine aggregate to coarse aggregate resulting in effective bio-cementation within the pore matrix of the coarse aggregate column as it could substantially reduce the cost associated with bio-cementation process. Scanning electron microscopy results confirm that adding fine aggregate to coarse aggregate provides more bridging contacts (connected by calcium carbonate precipitation) between coarse aggregate particles, and hence, the maximum UCS achieved was not necessarily associated with the maximum calcium carbonate precipitation. 相似文献
15.
目前对钙质土压缩特性的研究主要集中在钙质细砂,而实际工程中广泛存在钙质粗粒料,因此对钙质粗粒料压缩特性开展研究具有重要意义。通过颗粒强度测定仪和全自动大型固结仪对钙质土进行了单颗粒破碎试验和一维压缩试验,研究了颗粒粒径和相对密度对钙质粗粒料的颗粒强度和压缩特性的影响。单颗粒试验结果表明,钙质砂单颗粒的特征应力随着颗粒相对密度的增大而增大;单颗粒的破碎强度具有明显的尺寸效应,可利用单颗粒的特征应力进行标准化,且服从Weibull分布。压缩试验结果表明,单一粒径试样破碎后的分形维数随颗粒粒径的增大而增大;试样的Hardin破碎率与塑性功的关系为幂函数关系;在本次试验条件下,单一粒径试样的屈服应力与单颗粒的特征应力存在近似线性关系。 相似文献
16.
针对微生物诱导碳酸钙沉积 (MICP)固化钙质砂脆性强、抗拉强度低等问题,通过制备“8”字形MICP固化钙质砂试样并开展直接拉伸试验,对纤维加筋的改善作用、纤维-MICP联合加固机理及纤维掺量、纤维长度等影响因素进行了研究。结果表明:纤维加筋能够显著提高抗拉强度、峰值位移和残余强度,减轻峰值强度点的脆性破坏现象,但受纤掺量和长度的影响,总的来说,抗拉强度随纤维掺量的增加和长度的加长呈先增后减的趋势。相比无纤维试样,添加最优纤维掺量(0.6%)时,试样的抗拉强度增长了172.4%,峰值变形提升了158.1%。机理可解释为纤维增加了微生物的吸附量,促进碳酸钙在纤维与钙质砂之间以及纤维表面的沉积,增大纤维与钙质砂之间的界面作用力,整体提升钙质砂的抗拉强度特性。纤维的添加能够显著改变试样的变形特征,无纤维添加试样曲线仅有初始误差阶段和弹性阶段两个阶段,添加纤维后曲线表现为四个阶段包括初始误差阶段、弹性阶段、损伤破坏阶段和残余阶段。纤维掺量影响的内因是纤维与钙质砂的界面作用力和纤维空间分布状态随纤维掺量的变化而变化,纤维长度的影响主要和破坏面附近纤维数量和单位长度所能承担的拉应力相关。研究成果对以钙质砂为地基的岛礁工程的稳定性、安全性具有一定的指导意义。 相似文献
17.
桩基附近土颗粒的运动行为与宏观力学表现密切相关,对揭示界面剪切机制具有重要意义。利用自主研制的大型直剪仪,结合三维数字图像相关技术(3D-DIC)全场位移测量分析系统,开展了钢−钙质砂界面循环剪切试验,研究了界面附近砂颗粒的运动行为演化规律。结果表明:界面峰值剪切应力和发挥的界面摩擦角随循环次数的增大而增加,体变特性以剪缩为主;钙质砂颗粒左右移动的幅度与距界面的垂直距离成反比,钙质砂颗粒的位置随循环次数的增大逐渐向正剪切方向移动,试验结束时上剪切盒左侧区域的钙质砂颗粒向正剪切方向移动的距离最大;钙质砂颗粒在单个循环内出现有规律的上下移动,向下移动的幅值更大,位于上层的钙质砂颗粒向下移动的位移值大于下层;钙质砂颗粒的运动速度在沿单方向剪切时,呈现出慢−快−慢的变化规律,位于上剪切盒右侧区域的钙质砂的体变特性较左侧区域更显著;网格位移值和缺失数量随循环次数的增大而增加,在试验后期趋于稳定,试验结束时的破碎带厚度为 6.21 mm。 相似文献
18.
The engineering properties of solid waste produced by the combustion of Western oil shale are evaluated and discussed. Index properties and their variability, moisture—density relationships, shear strength, stress—strain characteristics, and hydraulic conductivity were evaluated in laboratory tests. Cementation caused by the formation of hydrous cements when combusted oil shale is exposed to water was found to be the most significant factor affecting its engineering properties. With increasing initial water content, shear strength increases and hydraulic conductivity decreases significantly, primarily because of cementation. Implications for the design of waste disposal embankments are discussed. 相似文献
19.
Calcareous sand is a typical problematic marine sediment because of its angular and porous particles. The effects of internal pores on the mechanical properties of calcareous sand particles have rarely been investigated. In this paper, the apparent morphology and internal structure of calcareous sand particles are determined by scanning electron microscopy and computed tomography tests, finding that the superficial pores connect inside and outside of the particles, forming a well-developed network of cavities and an internal porosity of up to 40%. The effects of particle morphology and internal porosity on the mechanical responses of particle were investigated by conducting photo-related compression test and 3D numerical simulations. Two failure modes are observed for the porous calcareous sand, i.e., compressive failure indicates that the particle skeleton is continually compressed and fragmented into small detritus without obvious splitting, and tensile failure indicates that the particles are broken into several fragments when the axial force clearly peaks. Calcareous sand particles with a high internal porosity or with small and dense pores often exhibit compressive failure, and vice versa. The particle strength is considerably reduced by increasing the internal porosity, but affected by pore size in nonlinear correlation. The crushing stress–strain points can be well fitted by an exponential curve, which is supplied for discussion.
相似文献20.
为了研究橡胶砂的剪切特性,采用室内大型直剪仪,研究了4种橡胶砂级配(1种间断级配、2种连续级配、1种开级配)、3种橡胶掺入量(10%、30%、60%)、3种竖向应力(30、60、90 kPa)对橡胶砂强度特性和体变特性的影响;并在室内直剪试验的基础上,按照相同级配和橡胶掺量建立纯砂和橡胶砂的离散元数值模型,从颗粒接触状态和颗粒位移角度探讨橡胶砂内在力学机制。研究结果表明:在低橡胶含量下,橡胶砂的剪应力曲线趋势和纯砂一致,但其抗剪强度均低于纯砂;橡胶砂剪切应力随竖向应力的增大而增大,4种级配的橡胶砂中连续级配SR2抗剪强度最高;橡胶颗粒的掺入能有效抑制砂土的剪胀,其中间断级配SR1橡胶砂抑制土体剪胀效果最好,剪胀量相较于纯砂减少了37.6%;橡胶砂的内摩擦角随着橡胶掺入量的增大而减小,同一橡胶掺量下连续级配SR2橡胶砂的内摩擦角最大;橡胶颗粒在橡胶砂力链网络中主要参与弱力链的形成,橡胶砂剪切带宽度小于纯砂的剪切带宽度。 相似文献