Mechanics Behavior of Ultra High Toughness Cementitious Composites after Freezing and Thawing

Mechanical behaviors of UHTCC after freezing and thawing were investigated,and compared with those of steel fiber reinforced concrete（SFRC）,air-entrained concrete（AEC） and ordinary concrete（OC）.Four point bending tests had been applied after different freezing-thawing cycles（0,50,100,150,200 and 300 cycles,respectively）.The results showed that residual flexural strength of UHTCC after 300 freezing-thawing cycles was 10.62 MPa（70% of no freezing thawing ones）,while 1.58 MPa（17% of no freezing thawing ones） for SFRC.Flexural toughness of UHTCC decreased by 17%,while 70% for SFRC comparatively.It has been demonstrated experimentally that UHTCC without any air-entraining agent could resist freezing-thawing and retain its high toughness characteristic in cold environment.Consequently,UHTCC could be put into practice for new-built or retrofit of infrastructures in cold regions.

Uniaxial Compressive Properties of Ultra High Toughness Cementitious Composite

Uniaxial compression tests were conducted to characterize the main compressive performance of ultra high toughness cementitious composite （UHTCC） in terms of strength and toughness and to obtain its stress-strain relationships. The compressive strength investigated ranges from 30 MPa to 60 MPa. Complete stress-strain curves were directly obtained, and the strength indexes, including uniaxial compressive strength, compressive strain at peak stress, elastic modulus and Poisson＇s ratio, were calculated. The comparisons between UHTCC and matrix were also carried out to understand the fiber effect on the compressive strength indexes. Three dimensionless toughness indexes were calculated, which either represent its relative improvement in energy absorption capacity because of fiber addition or provide an indication of its behavior relative to a rigid-plastic material. Moreover, two new toughness indexes, which were named as post-crack deformation energy and equivalent compressive strength, were proposed and calculated with the aim at linking up the compressive toughness of UHTCC with the existing design concept of concrete. The failure mode was also given. The study production provides material characteristics for the practical engineering application of UHTCC.

Preparation of Self-compacting Ultra-high Toughness Cementitious Composite

A self-compacting ultra-high toughness cementitious composite （UHTCC） reinforced by discontinuous short polyvinyl alcohol （PVA） fibers, which exhibits self-compacting performance in the fresh state and strain-hardening and multiple cracking behavior in the hardened state, was developed through controlling flow properties of fresh mortar matrix at constant ingredients concentrations determined by micromechanical design and ensuring uniform fibers dispersion. The superplasticizer was utilized to adjust its flow properties in the fresh state. A series of flow tests, including deformability test, flow rate test, and self-placing test, were conducted to characterize and quantify the fluidity performance of fresh mortar matrix and self-compactability of fresh UHTCC. It is revealed that the utilization of superplasticizer is efficient in producing the fresh mortar matrix with desirable fluidity and the resulting self-compacting UHTCC. In addition, results of four point bending tests on the developed self-compacting UHTCC confirm the insensitivity of mechanical performance of self-compacting UHTCC to the presence of external vibrations as well as the flexural characteristics of deformation hardening and multiple cracking.

海水干湿循环作用下UHTCC动态压缩性能试验研究

为研究应变率和海水干湿循环周期对超高韧性水泥基复合材料(UHTCC)动态压缩性能的影响,采用直径75 mm的分离式霍普金森压杆系统对0~120 d海水干湿循环作用后的UHTCC试件开展动态压缩试验.通过改进ZWT非线性黏弹性本构模型,提出了一种考虑海水干湿循环作用的UHTCC试件的动态本构模型.结果表明,UHTCC试件的动态抗压强度增强因子随着干湿循环周期的增加逐渐减小.在同一冲击气压下,随着干湿循环周期的增加,UHTCC试件的峰值应力和耗能先增大后减小,并分别在60和90 d时达到峰值.在相同干湿循环周期下,UHTCC试件的峰值应力、动态抗压强度增强因子和耗能均随应变率的增大而增大,表现出明显的应变率效应.改进的动态本构模型能够较好地描述海水干湿循环作用下UHTCC试件的动态压缩应力-应变关系.

Theoretical analysis on bending behavior of functionally graded composite beam crack-controlled by ultrahigh toughness cementitious composites

Ultrahigh toughness cementitious composites (UHTCC) obviously show strain hardening property under tensile or bending loading. The failure pattern of the UHTCC components exhibits multiple fine cracks under uniaxial tensile loading with prominent tensile strain capacity in excess of 3%, with merely 60 μm average crack width even corresponding to the ultimate tensile strain state. The approach adopted is based on the concept of functionally-graded concrete, where part of the concrete, which surrounds the main longitudinal reinforcement in a RC (reinforced concrete) member, is strategically replaced with UHTCC with excellent crack-controlling ability. Investigations on bending behavior of functionally-graded composite beam crack controlled by UHTCC has been carried out, including theo- retical analysis, experimental research on long composite beams without web reinforcement, validation and comparison between experimental and theoretical results, and analysis on crack control. In addition to improving bearing capacity, the results indicate that functionally-graded composite beams using UHTCC has been found to be very effective in preventing corrosion-induced damage compared with RC beams. Therefore, durability and service life of the structure could be enhanced. This paper discusses the development of internal force and crack propagation during loading process, and presents analysis of the internal force in different stages, moment-curvature relationship from loading to damage and calculation of mid-span deflection and ductility index. In the end, the theoretical formulae have been validated by experimental results.

Theoretical analysis and experimental investigation on flexural performance of steel reinforced ultrahigh toughness cementitious composite (RUHTCC) beams

UHTCC (ultrahigh toughness cementitious composite), which is a kind of ultrahigh toughness cemen- titious composites material, exhibits pseudo strain hardening feature when subjected to tension load, and has enormous ductility and prominent crack dispersal ability. Accordingly, UHTCC can improve mechanical behavior of ordinary concrete structure especially its durability, and has been regarded as historical breakthrough to traditional cementitious materials. In this paper, the study focuses on flexure behavior of steel reinforced beam made of UHTCC. Based on the plane section assumption, along with two equilibrium equations of force and moment, the formulae to calculate the flexural load capability for the reinforced ultrahigh toughness cementitious composite (RUHTCC) beam were developed under the assumption that the compression stress- strain relationship in the UHTCC material is a bilinear model. Following this, the simplified formulae were further evolved by effective rectangle stress distribution approach in order to facilitate design of practical engineering. Two effective parameters introduced in effective rectangle approach were determined. The mathematical expressions to evaluate limited rein- forcement ratio, flexural stiffness as well as ductility index were proposed, too. Last, two series of dif- ferent reinforcement ratios of the RUHTCC beams were tested in four-point flexure loading. For com- parison purposes, ordinary RC (reinforced concrete) beams also were prepared. Both moment curva- ture curves and load mid-span displacement curves were recorded and compared with the theoretical calculations. A good agreement between them was found, which validates the proposed theoretical formulae. For ductility index, a slightly big difference between the experimental values and the calcu- lated ones exists. The experimental results show that, compared to control RC beams, the RUHTCC beam can improve both flexural capacity and ductility index, and the degree of improvement will de- crease with the increase in the reinforcement ratio. Particularly, the results also reveal that lager crack width in control beams can be greatly reduced by formation of tightly-spaced fine cracks in UHTCC, which offers more durable structures.

木纤维对UHTCC干缩性能影响研究

为改善超高韧性水泥基复合材料(UHTCC)的干缩性能,选用未改性与硅烷改性木纤维和PVA纤维混杂作为UHTCC增强体,研究了两种木纤维掺量对UHTCC干缩性能的影响,并结合X射线断层扫描(XCT)和扫描电镜(SEM)对其微观孔隙结构进行分析。结果表明掺入1%、2%和3%硅烷改性木纤维的UHTCC在90d的干缩变形比未掺木纤维的UHTCC分别减小了4.76%、9.62%和11.62%。掺入木纤维会减小UHTCC的干缩变形,高掺量木纤维对UHTCC干缩变形的减小速度会变慢。同掺量硅烷改性木纤维UHTCC的干缩变形均要小于未改性组,硅烷改性可有效提升木纤维与基体的粘结强度。

型钢UHTCC短柱的抗震性能研究

将具有良好控裂耗能能力和抗剥落性能的水泥基材料UHTCC应用于型钢混凝土SRC短柱,制作并完成了7个型钢-UHTCC(SUHTCC)短柱和1个SRC对比短柱的拟静力试验。试验主要变量为:配箍率、轴压比和翼缘栓钉布置。结果表明:UHTCC的使用可有效避免SRC短柱粘结裂缝的滋生,减缓剪切主裂缝的扩展,能够将SRC短柱的脆性剪切粘结混合破坏模式转变为延性较好的剪切破坏模式,大幅提升短柱的震后完整性;对SUHTCC短柱,增大配箍率对承载力几乎没有影响,但需确保箍筋最大间距以延缓粘结破坏,高配箍率的试件能显示出较好的峰后滞回曲线,具有较高的极限变形和耗能;轴压比对抗震破坏形态和力学性能影响较小,高轴压比下依然拥有较高的大变形能力和良好的抗震耗能;与型钢翼缘没有布置栓钉的SUHTCC试件相比,布置栓钉的SUHTCC短柱表现出更为饱满的峰前抗震滞回曲线,对峰前行为的影响较为显著,但峰后破坏加快导致延性降低。最后采用3种不同规范对SUHTCC短柱受剪承载力进行了预测,初步验证了现行JGJ138-2016规范受剪承载力计算公式的适用性,并对SUHTCC短柱的剪切变形进行了定量分析,讨论了各参数对剪切变形的限制能力。

ECC全包裹普通混凝土复合试件的力学性能

为综合利用工程用水泥基复合材料(ECC)在力学性能上和普通混凝土在成本上的优势,本工作提出了一种制备ECC全包裹普通混凝土复合试件的方法,通过进行抗压、抗拉及抗弯等试验系统研究了其基本力学性能,并采用数值分析方法对配筋复合梁进行了正截面受弯性能研究。结果表明:在复合试件受力破坏时,ECC和混凝土界面未出现滑移,两种材料黏结可靠实现了协同受力;相对普通混凝土试件而言,复合试件的抗压强度、抗拉强度及抗弯强度均有所提升,尤其是抗弯强度的提升最为显著,对于截面尺寸为100 mm×100 mm的梁,当ECC厚度分别为10 mm和15 mm时,抗弯强度可提高27.4%和57.1%;复合试件具有良好的延性变形能力,破坏后可保持一定的完整性,整体具备高韧性特征;与普通钢筋混凝土梁相比,配筋复合梁有效利用了ECC材料的性能优势,显著提升了配筋梁的承载和变形能力。

无腹筋RUHTCC梁抗剪性能试验研究

为了探究超高韧性水泥基复合材料(UHTCC)的抗剪性能,以配筋率和剪跨比为参数,对跨中荷载作用下的6根钢筋增强UHTCC(RUHTCC)梁和4根钢筋混凝土(RC)对比梁进行了受弯试验.对比研究了RUHTCC梁的抗剪性能,包括裂缝扩展形态、荷载-挠度曲线、剪切开裂荷载、极限剪切能力以及剪切强度等.试验结果表明,随着配筋率的增大和剪跨比的减小,RUHTCC梁的破坏模式由弯剪破坏转变为剪压破坏,极限剪切承载能力逐渐增大.RUHTCC梁的极限剪切能力约为RC梁的2倍,平均抗剪强度约为UHTCC抗拉强度的0.86倍;RUHTCC梁表现出稳态的多条细密斜裂缝扩展模式,在正常使用极限状态下,其最大裂缝宽度低于0.1 mm.基于RUHTCC梁良好的裂缝控制能力以及较高的富余剪切承载能力,不需设置最小配箍率.

UHTCC三点弯曲梁裂纹扩展的数值模拟研究

为了探究超高韧性水泥基复合材料(简称UHTCC)断裂性能,选取三点弯曲梁作为研究对象,应用ABAQUS软件中的扩展有限元方法(XFEM)分析模块,模拟分析了加载条件下三点弯曲梁的裂纹扩展过程和规律,并进行了UHTCC力学参数敏感性分析。根据数值模拟结果,分析了三点弯曲梁的起裂荷载、失稳最大荷载、起裂韧度、临界等效裂缝长度、失稳断裂韧度等指标。结果表明,数值模拟结果与物理试验结果总体一致,UHTCC比普通混凝土具有很好的抗开裂能力和延性;在弹性模量、抗拉强度、断裂能参数原值的基础上,分别提高30%和降低30%。分析了3个力学参数对三点弯曲梁的起裂荷载、失稳最大荷载及其对应的裂缝张开位移影响程度。参数敏感性分析结果表明,弹性模量愈小,抗拉强度愈大,材料断裂失稳延性愈明显,而断裂能对断裂失稳延展性影响不明显。研究成果为UHTCC的材料设计、推广应用以及相应的结构分析等具有参考价值。

复材网格-UHTCC复合增强钢筋混凝土梁抗弯性能试验研究

文中进行7根复材(FRP)网格增强超高韧性纤维水泥基(UHTCC)复合加固钢筋混凝土梁的抗弯性能试验,将FRP网格类型、FRP网格增强率、FRP-UHTCC复合层黏结长度作为试验变量,分析各变量对FRP-UHTCC复合增强混凝土梁弯曲性能的影响。在试验研究的基础上,给出FRP-UHTCC复合增强混凝土梁的抗弯承载力计算方法。试验结果表明,FRP-UHTCC复合层与混凝土间没有发生相对滑移现象,可以有效抑制加固层端部剥离破坏,加固梁的破坏模式为FRP网格中纵向纤维筋被拉断破坏。BFRP格栅与UHTCC黏结基体没有发生脱黏现象,优于BFRP编织网与UHTCC的黏结效果。随着FRP网格增强率的增大,加固梁的抗弯承载力得到显著提高。与未加固的普通混凝土梁相比,加固梁的开裂、屈服和极限荷载最大提高幅度分别为97%、35%和33%。计算结果表明,预测值与试验值吻合较好,可以有效地预测FRP-UHTCC复合增强混凝土梁的抗弯承载力。

配筋率对RUHTCC梁弯曲性能的影响研究

钢筋增强超高韧性水泥基复合材料(RUHTCC)梁的弯曲性能与配筋率、UHTCC拉压材料性能以及截面尺寸相关。以配筋率为研究的影响因素,理论给出RUHTCC梁3个特征配筋率即最小配筋率、最大弹性配筋率以及最大界限配筋率的计算式。以这3个特征配筋率为边界,理论分析破坏模式从受拉破坏到受压破坏不同情况下梁极限承载力、中性轴高度、曲率、开裂长度以及最外层边缘拉应变的变化规律。提出最优化配筋率的概念,并指出它的大小接近于最大弹性配筋率。进行4种不同配筋率RUHTCC梁和两组RC对比梁的弯曲试验,讨论配筋率对弯曲性能包括承载力、变形、延性以及裂缝开展情况的影响和配筋率对RUHTCC梁较RC梁弯曲性能提高程度的影响。结果表明,对不同配筋率的RUHTCC梁,配筋率越大,极限承载力增加,屈服变形增大,但极限变形减小,延性降低,裂缝宽度的变化不明显。同一配筋率下,RUHTCC可提高RC梁的承载力和延性,在屈服时刻裂缝宽度可控制在0.1mm以内,极大提高了结构的耐久性,但随配筋率的增大,提高程度降低。试验与理论预测进行对比,结果较为吻合。

超高韧性水泥基复合材料力学性能及早期收缩研究

研究了水胶比和聚乙烯(PE)纤维掺量对超高韧性水泥基复合材料(UHTCC)抗压和抗折强度、弯曲韧性以及早期收缩性能的影响,并结合扫描电子显微镜(SEM)分析了UHTCC的微观结构。结果表明:随着水胶比的增大,UHTCC抗压和抗折强度均降低,而其弯曲韧性呈先降低后增长的变化趋势;增大PE纤维掺量可以显著提升UHTCC抗折强度和弯曲韧性,但会降低其3 d抗压强度,增大其7 d和28 d抗压强度。在早期收缩性能方面,水胶比增大会降低UHTCC早期自收缩,但其早期干燥收缩有所增大。而UHTCC早期自收缩和干燥收缩均随PE纤维掺量的增大而降低。微观结构分析发现PE纤维掺量增大容易导致纤维团聚;水胶比的增大会降低UHTCC基体的密实度和纤维-基体界面黏结力,不利于UHTCC力学性能的发展。

亚高温作用对钢-PE混杂纤维水泥基复合材料压缩性能的影响

为研究亚高温作用对钢-聚乙烯混杂纤维水泥基复合材料(S/PE-HFRECC)压缩性能的影响,开展了其经历亚高温冷却后的静态压缩试验。以控制纤维体积总掺量为2%并改变两种纤维掺量的方式,将钢纤维和PE纤维混杂掺入水泥基材料中,制成PE2、S0.5PE1.5、S1PE1、S1.5PE0.5和S2类型的试件。对经不同温度作用后的各纤维配比试件静态压缩试验结果进行分析,结果表明:(1)钢纤维主要发挥增强作用,PE纤维主要发挥增韧作用。(2)当试验温度在200℃及以下时,试件的静态抗压强度不会因温度的上升而有明显变化;在300℃时,各类试件的静态抗压强度均有不同程度的提升,其中S1.5PE0.5和S2试件的抗压强度最高;在400℃时,除S2试件外其他试件的抗压强度均存在下降现象。(3)各类型试件的峰值应变均随温度升高逐渐增大。当温度相同时,各类型试件的峰值应变与PE纤维的掺量呈正相关,说明PE纤维的加入能提高试件的变形能力。(4)S2试件的应力峰值前韧度随着温度的升高而升高,其他试件随着温度的升高表现为先增大后减小的趋势;S2试件在400℃时应力峰值前韧度达到最大值,其他试件则在300℃时韧度最大;当温度≯300℃时,S1.5PE0.5的试件应力峰值前韧度高于其他试件。

UHTCC与钢材界面的剪切型断裂试验研究

为了将超高韧性水泥基复合材料(UHTCC)应用于大跨径钢箱梁桥,研究双材料界面的力学性能.采用无切口单边对称加载复合试件,研究UHTCC与钢材界面剪切型裂缝扩展过程.利用数字图像相关法(DIC),验证该方法用于定量测定双材料界面剪切型断裂韧度的可行性,探究不同界面处理方式对复合试件界面剪切型断裂韧度的影响.试验结果表明,采用UHTCC-钢材无切口单边对称加载复合试件,结合DIC技术可以实现界面纯剪切型断裂韧度的定量测试;不同界面处理方式对UHTCC与钢材界面剪切型断裂韧度的影响均较小;UHTCC与钢材界面具有较高的剪切断裂韧度,抗剪切性能良好.

钢丝网-喷射UHTCC薄板抗弯性能试验研究

喷射超高韧性水泥基复合材料(喷射UHTCC)具有显著的应变硬化和多缝开裂特性,但其抗拉和抗弯强度不高,因此工程中常常考虑与钢丝网组合使用。本文对喷射UHTCC、钢丝网喷射UHTCC和钢丝网复合砂浆的薄板试件分别进行了四点弯曲试验。其中,选取的钢丝网复合砂浆薄板直接拉伸的失稳破坏强度与喷射UHTCC薄板接近。试验表明,钢丝网喷射UHTCC薄板的抗弯强度和极限弯曲挠度分别比喷射UHTCC薄板提高了69.8%和59.0%,也比钢丝网复合砂浆薄板提高了3.9倍和73.3%。

基于正交试验的UHTCC配合比设计

利用正交试验设计了9组不同配合比的超高韧性水泥基复合材料,通过直拉与弯拉试验,研究了水胶比、粉煤灰掺量、纤维体积掺量对极限拉应力、拉应变、弯拉应力和跨中挠度的影响。结果表明:PVA纤维明显提高了UHTCC的抗拉性能及抗弯性能;纤维体积掺量对7 d极限拉应变和28 d极限拉应力、拉应变均有显著影响,极限拉应力、拉应变总体上随着纤维体积掺量的增大而增大,水胶比对7 d极限拉应变影响显著,粉煤灰掺量对极限拉应力、拉应变的影响较小;水胶比和纤维体积掺量对7 d极限弯拉应力均有显著影响,粉煤灰掺量和纤维体积掺量对28 d极限弯拉应力有显著影响,水胶比和纤维体积掺量对7 d极限跨中挠度影响极其显著,对28 d极限跨中挠度有一定影响;通过综合分析确定了既保证强度又具有高延性的UHTCC的最优配合比。

UHTCC与RPC界面剪切断裂试验研究

为探究超高韧性水泥基复合材料(UHTCC)与活性粉末混凝土(RPC)的界面黏结性能,采用双边缺口单边压缩试验方法,结合数字图像相关分析,测得了UHTCC/RPC复合试件界面的剪切断裂韧度。结果表明,双边缺口压缩试验是测定复合试件界面剪切断裂韧度的可行方法;复合试件界面剪切断裂有着很长的裂缝稳态扩展过程,与混凝土试件相比具有更为明显的延性;复合试件界面黏结良好,剪切失稳断裂韧度达到了整体浇筑的C60高强混凝土的1.37倍,具有优良的抵抗界面剪切断裂的性能。

高温后UHTCC与钢筋粘结性能

掺纳米二氧化硅和钢纤维的超高韧性水泥基材料(UHTCC)具有良好的力学和耐高温性能。为探究UHTCC与钢筋在高温后的协同工作性能,文中对配光圆钢筋和变形钢筋的UHTCC试件在经历不同高温后的表观形态及拉拔试验中的滑移和破坏现象进行观察研究。试验表明:随经历温度的升高,UHTCC与钢筋的粘结应力逐渐降低;光圆钢筋的极限粘结应力和相应的滑移量呈负相关,UHTCC高温后疏松多孔,塑性变形能力加强,导致钢筋大滑移量的产生;变形钢筋与UHTCC的粘结应力显著大于光圆钢筋,两者粘结应力随经历温度升高具有相对不同的变化趋势。最后,文中提出了一个光圆钢筋粘结强度折减公式,与实验值符合较好。