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1.
The behaviour of a granular material is primarily affected by its particle size distribution (PSD), which is not necessarily a soil constant as assumed in traditional soil mechanics. The PSD may change over time due to mechanical as well as environmental actions. In this study, a series of ring shear tests and one-dimensional compression tests were completed on carbonate sand, in both dry and saturated conditions. Samples were prepared with different initial uniform gradings, to investigate: (1) the influence of the saturation state and initial grading on mechanical and deformational behaviour of carbonate sands and (2) the evolution of the PSD as a result of breakage. The ring shear tests show that the residual friction angle remains almost constant, but dilatancy reduces with increasing saturation degree. In the one-dimensional compression test, the yield stress decreases with increasing saturation degree, but the compressibility (as defined by Cc) remains almost constant, irrespective of the saturation state. Moreover, saturated samples suffer more breakage than dry samples during ring shear tests, while there is no obvious effect of saturation state on particle breakage in one-dimensional compression. A recently proposed PSD model with only two parameters (λp and κp) is employed to model the evolution of PSD, as it can more broadly capture the whole PSD throughout the breakage process than existing breakage indices. Test results demonstrate that parameter λp is linearly related to Einav’s breakage index \( B_{\text{r}}^{*} \) and is dependent on initial grading, but independent of test mode. Parameter κp is in power relationship with \( B_{\text{r}}^{*} \) and is independent of initial grading or test mode. The evolution of parameters λp and κp is related to the input work for both ring shear and compression tests, with λp being hyperbolically related to input work and κp in power relationship with input work. Using such an evolution law provides an alternative approach to capture the effects of particle breakage in constitutive models. 相似文献
2.
在常规应力水平下颗粒发生破碎是钙质砂有别于其他砂土的重要性质之一,且由于颗粒破碎的存在,使用传统的本构模型无法很好地模拟钙质砂的力学行为。因此本文以最为普及的本构模型之一--邓肯-张E-B模型为基础,对其进行颗粒破碎方面的修正以得到一个能用于钙质砂的本构模型。具体方法为:首先本文采用Hardin提出的相对破碎Br这一指标来度量颗粒破碎的大小。之后研究分析得出了颗粒破碎对邓肯-张模型参数(内摩擦角φ、割线模量E50及体积模量B)的影响规律。然后通过颗粒破碎与输入能量之间的关系将各状态下无法直接确定的相对破碎Br与可确定的应力-应变状态联系起来。最终得到了一个考虑颗粒破碎的钙质砂修正邓肯-张E-B模型。为验证模型的准确性及适用性,本文还使用该模型对4种不同粒径范围且试验围压不同的钙质砂的三轴排水行为进行了模拟。结果表明拟合效果较好,模型能适用于各种不同粒径范围的钙质砂,并且在颗粒破碎较大的情况下明显优于传统邓肯-张模型。 相似文献
3.
针对取自我国南部某海域的钙质砂样本,做了以下两方面工作:一是通过电子显微镜获取了钙质砂颗粒的几何投影图像,利用图像处理技术对图形进行黑白二值化处理,获取单元颗粒形状轮廓边界,使用圆度和粗糙度2个参数对钙质砂的颗粒形状进行定义和量化。二是通过不同围压下的三轴固结排水剪切试验及试验前后的颗分测量对比,研究了颗粒破碎对钙质砂的变形、强度、能量耗散等特性的影响。研究表明,大粒径钙质砂(粒径大于2.0 mm)和小粒径钙质砂(粒径小于0.5 mm)形态比较接近圆形、颗粒表面相对光滑;相比而言,中间粒径(粒径介于0.5~2.0 mm之间)钙质砂形状较不规则,表面棱角较多。钙质砂在三轴排水剪切过程中发生颗粒破碎,试样向着级配均匀的方向发展。随着初始围压的增大,颗粒破碎程度加大,土样整体剪胀趋势减小,而破碎引起的能量耗散增加。而在高围压(初始围压为600 kPa)剪切过程中,仅考虑摩擦耗散,以及同时考虑摩擦、体积耗散两种情况下,计算得到的最大颗粒破碎耗散分别可达土样总输入塑性功的25%和18%。 相似文献
4.
利用南海钙质砂和阿拉伯湾钙质砂,进行侧限压缩试验,对其压缩特性进行分析,得到了相应的压缩指数;采用相对破碎率为度量指标,评价了钙质砂在压缩试验过程中的颗粒破碎情况。同时根据试验数据得到了不同初始相对密实度的砂样的塑性功,通过建立塑性功与相对破碎率以及塑性功与压缩指数之间的关系,探讨了颗粒破碎对钙质砂压缩特性的影响。研究显示,在本次试验条件下,颗粒破碎是导致钙质砂压缩变形的主要因素,钙质砂的中值粒径以及碳酸钙含量等因素对其颗粒破碎程度有明显影响;钙质砂的相对破碎率与其输入的塑性功有关,并且受到初始相对密实度的影响,采用相对密实度进行归一化后,两者呈现较好的幂函数关系;通过建立钙质砂压缩指数与塑性功之间的关系,进一步建立了钙质砂的压缩指数与相对破碎率之间的关系,经相对密实度归一化后,两者也呈现幂函数规律,此规律可以用于评价颗粒破碎对钙质砂压缩特性的影响。 相似文献
5.
钙质砂是海洋沉积物中的一种,富含碳酸钙或其他难溶碳酸盐类物质的特殊介质。由于其颗粒质脆,受力后易产生破碎,表现出与常规陆源砂不同的力学性质。通过对取自南沙群岛永暑礁附近海域的钙质砂进行三轴剪切试验,分析了钙质砂颗粒破碎与剪胀对其抗剪强度的影响。试验结果表明,颗粒破碎与剪胀对钙质砂强度有着重要影响,低围压下剪胀对其强度的影响远大于颗粒破碎,随着围压的增加,钙质砂颗粒破碎加剧,剪胀影响越来越小,而颗粒破碎的影响则越来越显著;颗粒破碎对强度的影响随着围压的增大而增大,当破碎达到一定程度后颗粒破碎渐趋减弱,其影响也渐趋于稳定。 相似文献
6.
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
7.
为了掌握南海钙质砂压缩变形特征及其微观机制,对3种不同粒组(S1:1.43~2mm、S2:0.5~1mm、S3:0.5~2mm)的钙质砂进行100~3200kPa压力范围的压缩试验,利用自制的砂土微观结构提取装置和图像处理软件(PCAS)获得并分析了钙质砂压缩过程中微观结构。结果表明:(1)钙质砂的大小、形状和级配对颗粒的破碎具有显著影响,当压力较低时(<800kPa),粒径较大的S1组以砂颗粒棱角破碎为主;粒径较小的S2组没有明显破裂,相对规则的颗粒形态使S2粒组在该压力范围内主要因颗粒的滚动与重分布导致压缩;级配良好的S3组除部分低宽度断肢状颗粒外其余大小、形态颗粒无明显破裂。(2)当压力较大时(>800kPa),S1组钙质砂逐渐转向以颗粒的整体破坏为主的破碎形式;S2、S3两组试样随着密实度的提高,砂颗粒的破坏以整体破碎为主。基于对破碎过程中试样微观结构变化的提取与分析,总结并提出了控制钙质砂颗粒破碎的4种接触模式:点-线接触、线-面接触、面-面接触和复合接触,可用于判断不同条件下的颗粒破碎形式。最后,讨论了钙质砂在破碎过程中颗粒几何参数的变化。 相似文献
8.
钙质砂的颗粒易碎性是造成其变形和强度特性不同于石英砂的重要性质。本文基于临界状态理论,通过一系列试验定量地描述钙质砂临界状态线随颗粒破碎的演化规律。本文试验分两个阶段进行:第1阶段研究了60~2000 kPa围压条件下钙质砂的力学特性和颗粒破碎特征;第2阶段以不同破碎率的试样为母本重塑制样,在100~300 kPa围压条件下,剪切至破碎临界状态线。试验结果表明:在较小围压(<300 kPa)条件下,松砂和密砂均表现出明显的剪胀和应变软化特性;而高围压(>1 MPa)条件下,显著的颗粒破碎会造成试样的持续剪缩;颗粒破碎存在明显围压阈值,对于松砂而言,在围压小于300 kPa条件下,颗粒基本不发生破碎;在e-lg p'平面内,破碎临界状态线的截距Δe Γ和斜率λ c均会随着修正相对破碎率B r*的增大而减小,即颗粒破碎会使临界状态线发生下移和逆时针转动;而在q-p'平面内,钙质砂的临界状态点落在同一条直线上,即存在唯一的临界状态应力比M cr和临界摩擦角φ cr。 相似文献
9.
珊瑚礁沉积的钙质砂与石英砂的物理力学性质有较大差别。对取自南海岛礁的钙质砂进行了单次往返环剪试验以分析钙质砂的抗剪强度特性,试验中考虑了相对密实度和竖向应力对结果的影响,并与相同级配和试验条件下的石英砂进行对比分析。结果表明:钙质砂正向剪切时应力-位移曲线为软化型,具有明显的残余强度特性,而反向剪切时则表现为硬化型,正向和反向剪切强度基本一致;石英砂正向剪切和反向剪切均表现为软化型。钙质砂正向剪切和反向剪切残余强度与峰值强度的比值在0.75~0.93之间;石英砂正向剪切和反向剪切残余强度与对应峰值强度的比值在0.89~0.96之间。相同级配和试验条件下,钙质砂残余强度均大于石英砂,且强度比值基本保持在1.05~1.3之间。在100、200 kPa竖向荷载作用下,钙质砂0.5~2.0 mm的颗粒发生了破碎,破碎率分别为4%和6%。 相似文献
10.
基于二维离散单元法,对沉桩过程中钙质砂颗粒破碎情况进行了模拟。采用簇粒来模拟易破碎的钙质砂颗粒,并用形状与变形特性相同的聚粒单元来模拟不可破碎颗粒,对这两种单元特性进行对比,分析不同桩型的沉桩过程、桩周土体的力学响应、沉桩过程中钙质砂的颗粒破碎现象。结果表明:破碎颗粒将引起桩侧土体级配的重新调整,与桩体接触好于不可破碎土体;桩处于颗粒破碎的钙质砂中,其沉桩速度较快,对地基土扰动小于未发生颗粒破碎的情况;对于不同桩型、不同土层,桩体压入过程中,桩周土体应力场分布具有相似性;靠近桩端附近,土中水平应力和竖向应力急剧增大,形成应力核;同等条件下发生颗粒破碎的钙质砂地基土中,桩端应力峰值高于不可破碎土体。 相似文献
11.
钙质砂为海相沉积的多孔介质,是防护工程分配层的理想填充材料。利用改进的铝制分离式霍普金森压杆(split Hopkinson pressure bar,简称SHPB),分别对颗粒级配以及相对密实度相同的南海钙质砂和福建石英砂进行了83组一维冲击试验,得到了应力波透射率、冲击响应和吸能效率曲线,分析了应变率、相对密实度和含水率对两种砂冲击特性的影响。结果表明,相同的荷载和边界条件下,钙质砂的刚度仅为石英砂的1/10。由于内孔隙的存在,钙质砂对冲击波的衰减作用大于石英砂,在承载性能允许的情况下,适当减小相对密实度、增加含水率可有效提高分配层消能效果。 相似文献
12.
针对岛礁大型构筑物修建过程中由于高应力而导致作为地基材料的钙质砂发生破碎,进而引发地基沉降变形问题。本文采用高压固结仪对钙质砂开展了一系列终止压力为16 MPa的侧限压缩试验,研究了高应力水平下钙质砂的压缩破碎特性。同时基于显微图像采集和处理技术对钙质砂颗粒的形状参数(圆度和完整度)进行了定量化表征,研究了钙质砂的形状分布规律。最终分别探讨了级配特征(如平均粒径、不均匀系数)、形貌特征等因素对钙质砂压缩和破碎特性的影响。结果表明:随着平均粒径的增大,钙质砂颗粒的形状不规则程度逐渐增加,其棱角也越发育。随着竖向应力的增大,在e-logp平面内,不同粒径钙质砂的压缩曲线逐渐会聚并相交于一条直线,初始粒径对其压缩特性的影响逐渐减小以致消失。而不同级配钙质砂的压缩曲线也发生会聚,但未相交于一条直线。当试样的不均匀系数(C u)相近时,其压缩破碎量随着平均粒径(d 50)的增大而逐渐增加,当试样的d 50相近时,其压缩破碎量随着C u增大而逐渐减小。上述研究成果将对南海岛礁大型工程建设提供重要科学依据。 相似文献
13.
钙质砂是一种特殊的海洋沉积物,开展钙质砂在爆炸作用下动力响应特性研究具有重要的理论意义和工程实用价值。通过室内小型爆炸试验,研究饱和钙质砂在爆炸作用下土压力、孔隙水压力和质点振动加速度等参数的变化规律。结果表明:饱和钙质砂中爆炸应力波随距离增大而衰减,但随爆心距增大衰减速度呈减小趋势;随试样相对密度增大爆炸应力波的衰减速度趋缓;爆炸引起的超孔隙水压力在10~30 ms内到达峰值,在前3 min内快速消散,消散幅度达90%以上;双发雷管微差起爆相对于单发起爆,最大单段起爆药量相同,但微差起爆由于爆炸应力波的叠加,使得钙质砂动力响应加剧。与相同试验条件下石英砂爆炸响应对比表明,相同测点处钙质砂动力响应弱于石英砂,应力波在钙质砂中衰减速度远比石英砂快,说明饱和钙质砂对爆炸应力波有着极强的吸收和衰减作用;爆炸近区钙质砂颗粒大量破碎,形成爆炸破碎和压缩区,形成这几个区域所耗损的爆炸冲击能量大约占总能量的25%左右。 相似文献
14.
通过对钙质砂进行不排水条件下声发射试验,探讨了不同围压、剪切速率、初始孔隙比和级配下钙质砂声发射规律。试验结果表明:低围压(围压低于400 kPa)时,钙质砂声发射活动频率随着围压的升高而增加;围压增至800 kPa时,声发射活动频率有所下降。低剪切速率下,钙质砂剪切试验明显分为颗粒破碎阶段和颗粒滑移阶段,随着剪切速率增大,二者之间较模糊,不能明显区分;松散和密实状态下,钙质砂声发射活动规律相似,钙质砂声发射活动频率均高于中密状态钙质砂;级配较好的钙质砂,声发射率峰值出现在试样发生剪切破坏前;级配稍差,试样声发射率相对均匀,声发射率峰值出现在邻近试验结束时。 相似文献
15.
钙质砂是一种海洋沉积物,与陆源砂比起来,钙质砂受力后易产生颗粒破碎,从而使其力学性质发生变化。对取自南沙群岛永暑礁附近海域的钙质砂进行了不同围压、不同应变下的三轴剪切试验,对试验前后的试样进行了颗粒大小分析试验。试验结果表明,钙质砂在三轴剪切作用下颗粒破碎十分严重,同时用Hardin模型对其破碎进行了度量,并就围压、剪切应变与破碎之间的关系进行了分析。 相似文献
16.
为了揭示钙质砂在一维压缩回弹作用下的压缩变形、颗粒破碎特性以及声发射规律,对钙质砂进行了3种相对密实度下不同粒组的一维压缩回弹实验和声发射实验。通过对不同粒组、不同相对密实度的钙质砂进行一维压缩实验和同步的声发射实时监测,获得其压缩、回弹和声发射特性,最后通过筛分获得实验后的颗粒粒径分布,得出相对破碎势B r。实验结果表明:钙质砂的压缩变形由颗粒位置调整和破碎两部分组成,其中颗粒破碎是产生压缩变形的主要因素,回弹曲线近似一条直线,表明压缩变形为不可恢复的塑形变形;压力相同时颗粒粒径越大,相对破碎势B r越大。颗粒形状不同致使颗粒间填充作用与嵌合作用不同,影响颗粒的滑移与重排列,进而影响颗粒的压缩变形。两种砂的声发射计数率随粒径增大而增大,且都集中出现在800~3200 kPa的压缩阶段,钙质砂的压缩变形及破碎特性与其声发射特征具有一致性,钙质砂声发射计数率与时间关系曲线和应力与时间关系曲线吻合较好,可通过声发射计数率与时间关系曲线来反映钙质砂的力学特性。钙质砂存在一个声发射事件最少的“临界孔隙比”,本次实验中1~2 mm钙质砂临界孔隙比为1.33~1.41,试样的初始孔隙比偏离该临界值时,声发射活动会有不同程度提高。 相似文献
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The settling behaviour of particulate suspensions and their deposits has been documented using a series of settling tube experiments. Suspensions comprised saline solution and noncohesive glass‐ballotini sand of particle size 35·5 μm < d < 250 μm and volume fractions, φs, up to 0·6 and cohesive kaolinite clay of particle size d < 35·5 μm and volume fractions, φm, up to 0·15. Five texturally distinct deposits were found, associated with different settling regimes: (I) clean, graded sand beds produced by incremental deposition under unhindered or hindered settling conditions; (II) partially graded, clean sand beds with an ungraded base and a graded top, produced by incremental deposition under hindered settling conditions; (III) graded muddy sands produced by compaction with significant particle sorting by elutriation; (IV) ungraded clean sand produced by compaction and (V) ungraded muddy sand produced by compaction. A transition from particle size segregation (regime I) to suppressed size segregation (regime II or III) to virtually no size segregation (IV or V) occurred as sediment concentration was increased. In noncohesive particulate suspensions, segregation was initially suppressed at φs ~ 0·2 and entirely inhibited at φs ≥ 0·6. In noncohesive and cohesive mixtures with low sand concentrations ( φs < 0·2), particle segregation was initially suppressed at φm ~ 0·07 and entirely suppressed at φm ≥ 0·13. The experimental results have a number of implications for the depositional dynamics of submarine sediment gravity flows and other particulate flows that carry sand and mud; because the influence of moving flow is ignored in these experiments, the results will only be applicable to flows in which settling processes, in the depositional boundary, dominate over shear‐flow processes, as might be the case for rapidly decelerating currents with high suspended load fallout rates. The ‘abrupt’ change in settling regimes between regime I and V, over a relatively small change in mud concentration (<5% by volume), favours the development of either mud‐poor, graded sandy deposits or mud‐rich, ungraded sandy deposits. This may explain the bimodality in sediment texture (clean ‘turbidite’ or muddy ‘debrite’ sand or sandstone) found in some turbidite systems. Furthermore, it supports the notion that distal ‘linked’ debrites could form because of a relatively small increase in the mud concentration of turbidity currents, perhaps associated with erosion of a muddy sea floor. Ungraded, clean sand deposits were formed by noncohesive suspensions with concentrations 0·2 ≤ φs ≤ 0·4. Hydrodynamic sorting is interpreted as being suppressed in this case by relatively high bed aggradation rates which could also occur in association with sustained, stratified turbidity currents or noncohesive debris flows with relatively high near‐bed sediment concentrations. 相似文献
18.
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
19.
钙质砂是一种碳酸钙含量达50%以上的海洋生物成因的颗粒状材料。从微观结构上来看,钙质砂颗粒棱角度高、形状不规则、强度低、易破碎,且颗粒含有内孔隙。内孔隙的存在深刻影响着钙质砂的压缩、剪切和破碎等力学性能。利用激光技术对南沙群岛永暑礁环礁泻湖的未胶结钙质砂颗粒进行飞秒切割,通过光学显微镜探查并获取了颗粒的内孔隙图像,借助MATLAB图像处理软件,对钙质砂颗粒的内孔隙进行了定量分析。结果表明:较大颗粒钙质砂的内孔隙断面孔隙度相对较大,小孔隙数量较多,而大孔隙所占空间则较大;对于1 mm以上的钙质砂,缝隙状内孔隙含量远低于等轴或不等轴孔隙,等轴与不等轴内孔数量大致相等。 相似文献
20.
Coral sand, which is an important filler resource in coastal areas, is continuously subjected to repeated waves or traffic loading. In this study, a series of oedometer tests are conducted on coral sand and silica sand under repeated loading, and the results are compared. The influence of the initial density and number and amplitude of repeated loading on the volumetric deformation, soil stiffness, and particle breakage are investigated. The results reveal that the volumetric deformation and particle breakage of coral sand mainly occur in the first loading stage and increase by increasing loading amplitude and reducing initial density. Compared to silica sand, the soil stiffness is lower and volumetric deformation is greater in coral sand during the initial loading stage. However, the opposite trend is observed for the subsequent loading. Finally, three power functions are proposed to predict the volumetric deformation and particle breakage of coral sand under repeated loading. 相似文献
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