Different Curing Systems on Mechanical Properties of Ultra-High Performance Concrete with Coarse Aggregate

High durability and high tensile strength makes ultra-high performance concrete( UHPC) an ideal material for bridges,while its early shrinkage in the construction of cast-in-situ mass concrete leads structure crack-easily,which restricts the application of UHPC in deck system. Whether reasonable amount of coarse aggregate can influence the strength of UHPC and improve the shrinkage performance or reduce the cost is still in doubt. Besides,in order to improve its constructability and workability, whether autoclaved curing system of UHPC can be changed remains to be further researched. In response to these circumstances, a systematic experimental study on the strength of UHPC mixed with coarse aggregate in different ratios has been presented in this paper. The three curing systems,namely standard curing,180-200 ℃/1. 1 MPa autoclaved curing,and hot water curing were tested to reveal the relationship between UHPC's properties and curing systems,and the UHPC ' s microstructure was also preliminarily studied by scanning electron microscope( SEM). The experimental research can draw the following conclusions. Under the condition of the same mix ratio, autoclaved curing guarantees the highest compressive strength,followed by hot water curing and standard curing. The compressive strength of concrete increases with the temperature in the range of 25 to 90 ℃ hot water curing,and high temperature in precuring period can speed up the strength development of UHPC,but the sequence of precuring period does not obviously affect the results. In 90 ℃ hot water and autoclaved curing,the strength is over 150 MPa,and it has little relation with gravel ratio. While the value increases first and then decreases in a lower temperature curing with the increasing of gravel amount,even only about 80 MPa at room temperature. The strength increases moderately along with the increase of the curing age by standard curing,especially in the initial stage.

Mechanical Behavior Based on Aggregates Microstructure of Ultra-high Performance Concrete

We developed ultra-high performance concrete(UHPC)incorporating mullite sand and brown corundum sand(BCS),and the quartz sand UHPC was utilized to prepare for comparison.The properties of compressive strength,elastic modulus,ultrasonic pulse velocity,flexural strength,and toughness were investigated.Scanning electron microscopy and nanoindentation were also conducted to reveal the underlying mechanisms affecting macroscopic performance.Due to the superior interface bonding properties between mullite sand and matrix,the compressive strength and flexural toughness of UHPC have been significantly improved.Mullite sand and BCS aggregates have higher stiffness than quartz sand,contributing to the excellent elastic modulus exhibited by UHPC.The stiffness and volume of aggregates have a more significant impact on the elastic modulus of UHPC than interface performance,and the latter contributes more to the strength of UHPC.This study will provide a reference for developing UHPC with superior elastic modulus for structural engineering.

Effect of Aggregate Gradation on the Properties of 3D Printed Recycled Coarse Aggregate Concrete

A simplex centroid design method was employed to design the gradation of recycled coarse aggregate.The bulk density was measured while the specific surface area and average excess paste thickness were calculated with different gradations.The fluidity,dynamic yield stress,static yield stress,printed width,printed inclination,compressive strength and ultrasonic wave velocity of 3D printed recycled aggregate concrete(3DPRAC)were further studied.The experimental results demonstrate that,with the increase of small-sized aggregate(4.75-7 mm)content,the bulk density initially increases and then decreases,and the specific surface area gradually increases.The average excess paste thickness fluctuates with both bulk density and specific surface area.The workability of 3DPRAC is closely related to the average excess paste thickness.With an increase in average paste thickness,there is a gradual decrease in dynamic yield stress,static yield stress and printed inclination,accompanied by an increase in fluidity and printed width.The mechanical performance of 3DPRAC closely correlates with the bulk density.With an increase in the bulk density,there is an increase in the ultrasonic wave velocity,accompanied by a slight increase in the compressive strength and a significant decrease in the anisotropic coefficient.Furthermore,an index for buildability failure of 3DPRAC based on the average excess paste thickness is proposed.

Influence Mechanism of Curing Regimes on Interfacial Transition Zone of Lightweight Ultra-High Performance Concrete

This study aims to clarify the effects of curing regimes and lightweight aggregate(LWA)on the morphology, width and mechanical properties of the interfacial transition zone(ITZ) of ultra-high performance concrete(UHPC), and provide reference for the selection of lightweight ultra-high performance concrete(L-UHPC) curing regimes and the pre-wetting degree LWA. The results show that, under the three curing regimes(standard curing, steam curing and autoclaved curing), LWA is tightly bound to the matrix without obvious boundaries. ITZ width increases with the water absorption of LWA and decreases with increasing curing temperature. The ITZ microhardness is the highest when water absorption is 3%, and the microhardness value is more stable with the distance from LWA. Steam and autoclaved curing increase ITZ microhardness compared to standard curing. As LWA pre-wetting and curing temperatures increase, the degree of hydration at the ITZ increases, generating high-density CSH(HD CSH) and ultra-high-density CSH(UHD CSH), and reducing unhydrated particles in ITZ. ITZ micro-mechanical properties are optimized due to hydration products being denser.

粗骨料超高性能混凝土应用研究

为满足桥梁工程中桥面板材料轻质高强的市场需求,在活性粉末混凝土中掺入粒径不大于8 mm的粗骨料,制成含粗骨料超高性能混凝土。这种混凝土具有力学性能佳、材料自重轻、早期收缩小和造价较低等特点。首先阐述含粗骨料超高性能混凝土的配制原理及各掺合料对其性能的影响,其次分析其力学性能、疲劳性能和高温性能,最后展示了其在南京江心洲长江大桥的工程应用状态,并提出了其尚待深入研究的问题和发展方向。

桥梁动力效应对粗骨料UHPC的影响

为解决粗骨料超高性能混凝土(UHPC)在桥梁工程可能遭受的桥梁动力效应问题,通过小型振动台进行模拟桥梁振动,以振动幅度和频率为振动参数,研究了桥梁振动对粗骨料UHPC的力学性能、超声波波速及粗骨料沉降系数的影响规律.试验结果表明:1 mm的振动幅度可以有效改善孔结构,对粗骨料UHPC的力学性能和超声波波速具有促进作用;当振动幅度大于1 mm时振动会引入内部缺陷,并且粗骨料离析程度增大,刚性骨架被破坏,抗压强度、弹性模量和超声波波速降低;当振动频率增大时,能够有效改善钢纤维与基体的黏结性能,增强粗骨料UHPC的弯曲韧性;在实际粗骨料UHPC用于桥梁施工过程中应注意控制桥梁振动幅度,不应超过3 mm。

针片状颗粒对高强混凝土性能的影响研究

从粗骨料针片状颗粒角度出发,研究其含量和粒径对高强混凝土性能的影响。选取掺加5%、15%和25%针片状颗粒含量的粗骨料配制混凝土,对混凝土的工作性能、力学性能和耐久性能进行试验研究;选取5~10 mm、10~16 mm和16~20 mm共三种粒径区间的针片状颗粒,探究粒径大小对混凝土性能的影响规律。结果表明:针片状颗粒含量增加,高强混凝土和易性和泵送性能变差,混凝土抗压强度降低,混凝土收缩增大,且对高强混凝土耐久性能不利;混凝土拌合物坍落度和扩展度、硬化混凝土各龄期抗压强度均随着粗骨料中针片状颗粒粒径增大而降低;综合考虑针片状颗粒对高强混凝土性能影响规律,建议控制针片状颗粒含量不超过5%;同时,在计算针片状颗粒含量时,需在标准计算方法基础上按不同粒径针片状颗粒分别乘以其对应的影响系数进行修正,以实现对粗骨料粒形更好的控制。

含粗骨料超高性能混凝土的单轴受拉力学性能

考虑粗骨料掺量、钢纤维掺量及长径比等因素,研究了含粗骨料超高性能混凝土(UHPC-CA)的单轴受拉力学性能,揭示了纤维增强的机理和粗骨料的作用机制.结果表明:随着粗骨料掺量的增加,UHPC-CA的单轴抗拉强度与变形性能均下降;钢纤维掺量增加、长径比增大对UHPC-CA的受拉力学性能有较大的提升作用;钢纤维与基体间具有良好的握裹力,在基体内出现裂缝后,主要依靠握裹作用承受拉应力;粗骨料的掺入削弱了钢纤维空间分布的均匀性,同时引入了薄弱的粗骨料-基体界面过渡区,对UHPC-CA的受拉性能产生了不利的影响.

粗骨料取代率对机制砂再生混凝土高温性能的影响

为探究不同粗骨料取代率对机制砂再生混凝土(RCM)高温性能的影响,以不同粗骨料取代率(0%、20%、40%、60%、80%、100%,质量分数)制备RCM并研究其单面受高温后的表面形貌、质量损失率、抗压强度、荷载变形曲线及微观形貌。结果表明,粗骨料取代率在40%~60%时,在低于600℃的高温试验下RCM表现良好。当温度在200℃时,各组试块表面形貌变化不大,质量损失率较小,抗压强度略微上升;当温度在400℃时,各组试块表面开始出现裂缝,质量损失率为4.35%~6.47%,抗压强度开始下降,此时粗骨料取代率影响不大;当温度达到600℃时,表面形貌变化明显,质量损失率上升到6.42%~8.70%,抗压强度最终降低到基准强度的80%左右,此时粗骨料取代率在40%~60%的试块表现良好;当温度达到800℃时,各组试块表面形貌变化进一步加剧,粗骨料取代率大于60%的试块受影响非常明显,同时各类性能参数表明混凝土已完全丧失工作性能。

基于GA-BP神经网络的粗骨料UHPC的抗压强度预测

为实现对粗骨料UHPC的抗压强度的预测和配合比设计方法的优化,搜集了国内外文献中168组粗骨料UHPC配合比和标准养护28 d抗压强度实测值,给出了各材料组分和抗压强度频数分布,并基于灰色关联分析法分析了各材料组分与抗压强度的关联关系,通过神经网络参数分析,建立了基于遗传算法的前馈神经网络,相比普通的BP神经网络具有更好的预测精度和泛化能力。最后基于建立的GA-BP神经网络给出了不同强度等级粗骨料UHPC配合比设计中粗骨料/胶凝材料、钢纤维体积掺量、砂胶比的建议取值范围。

粗骨料及混杂纤维对UHPC力学性能的影响

为评议粗骨料超高性能混凝土(CA–UHPC)的基体配合比设计方法及探究混杂纤维对其力学性能的影响,基于修正的安德森(MAA)模型提出CA–UHPC基体配合比的两种设计思路,对不同粗骨料体积掺量(10%,12%,14%,17%)及混杂纤维形式(平直钢纤维、端钩钢纤维、共聚甲醛(POM)纤维)的CA–UHPC开展轴拉试验、抗压强度及工作性能测试及微观结构分析.结果表明:采用MAA模型计算CA–UHPC的基体配合比,不论是否将粗骨料引入计算体系,均可实现CA–UHPC的紧密堆积状态,两种思路设计的CA–UHPC中粗骨料–UHPC基体界面及纤维–UHPC基体界面的粘结强度均较高;制备的混杂纤维CA–UHPC可实现工作性能与轴拉韧性的协同提升,其中平直钢纤维与端钩钢纤维混杂的CA–UHPC具备更优异的轴拉韧性,平直钢纤维与POM纤维混杂的CA–UHPC具备更优异的工作性能;拔出的POM纤维表面存在较多的细长絮状物,说明POM纤维对CA–UHPC轴拉韧性提升的机理为优异的化学粘结作用.

再生粗骨料强化工艺对再生混凝土力学性能及耐久性能的影响

分别采用级配强化、化学浆液强化和级配-化学浆液复合强化3种工艺对再生粗骨料进行品质提升,考察不同强化工艺对再生混凝土力学性能及耐久性能的影响。结果表明:当分形维数取2.6时,再生粗骨料的压碎指标最小,级配强化工艺对再生混凝土抗压强度的提升效果较好,但对弹性模量、抗碳化性能和抗冻性能的改善不明显;采用水泥外掺硅灰浆液强化的再生粗骨料可有效提高再生混凝土的弹性模量和抗冻性能,降低再生混凝土的碳化深度;级配-化学浆液复合强化工艺结合了两种单一强化工艺的特点,对再生混凝土力学性能和耐久性能的改善效果最佳。

粗骨料UHPC单轴拉伸性能及损伤本构模型

通过单轴拉伸试验,研究粗骨料用量和钢纤维的掺量、类型及混杂配比对粗骨料超高性能混凝土(CA-UHPC)受拉性能的影响,揭示了CA-UHPC破坏机理以及粗骨料与钢纤维的相互作用机制.结果表明:粗骨料引起的薄弱界面和空间阻隔作用削弱了钢纤维的增韧作用,CA-UHPC拉伸性能随粗骨料用量增大而降低,建议其用量不超过450 kg/m^(3);增大钢纤维掺量能改善CA-UHPC拉伸性能,且平直钢纤维的增韧作用更稳定;1.0%平直和1.0%端勾钢纤维混杂时,其与粗骨料匹配良好,钢纤维有效利用率达到25.4%,能够充分发挥混杂纤维的协同增韧作用.最后建立了考虑粗骨料和钢纤维影响的CA-UHPC受拉损伤本构模型.

含粗骨料超高性能混凝土静态稳定性研究

为改善含粗骨料超高性能混凝土(CA-UHPC)整体静态稳定性,采用图像技术分别研究了拌合物(未加纤维)流变参数、粗骨料掺量和粗骨料级配对不含纤维和含纤维CA-UHPC静态稳定性的影响规律。结果表明:粗骨料整体均匀性随粗骨料平均初始净距的减小而升高;当拌合物的屈服应力和塑性粘度较小时,纤维分布的均匀性会因纤维沉降而降低;纤维的加入降低了粗骨料的整体均匀性,同时粗骨料也会影响纤维的整体均匀性;对CA-UHPC体系而言,粗骨料平均初始净距的减小可以增加粗骨料分布稳定性,但过小的粗骨料平均初始净距会影响纤维的分布。因此,在粗骨料掺量一定时,可以通过适当调整粗骨料级配或砂率,在不影响粗骨料分布稳定性的前提下,提高纤维分布系数。

含粗骨料UHPC的强度尺寸效应与性能研究

研究了胶凝材料组成比例、钢纤维类型(平直型、端钩型)对含粗骨料超高性能混凝土(UHPC)强度尺寸效应、工作性和收缩性能的影响,分析了减缩剂掺量(0~2.0%)对含粗骨料UHPC收缩性能、力学性能、抗氯离子渗透性能和孔结构的影响。结果表明:适当增加粉煤灰掺量有利于改善含粗骨料UHPC的工作性,降低收缩;掺入钢纤维降低了含粗骨料UHPC的工作性,但抑制了收缩,且端钩型钢纤维抑制效果更显著;掺入1%钢纤维能够有效降低含粗骨料UHPC的强度尺寸效应,且平直型钢纤维的降低效果更好;掺入减缩剂明显降低了含粗骨料UHPC的收缩,但会使抗压强度降低,总孔隙率增大,抗氯离子渗透性能变差。

粗骨料空隙率对低砂率高性能混凝土工作性能的影响

为了明确粗骨料空隙率对低砂率高性能混凝土工作性能的影响,本文通过选择不同空隙率的粗骨料,研究其对高性能混凝土(HPC)工作性能的影响。结果表明:混凝土的坍落度和扩展度随着砂率的降低而下降,使用空隙率为40.7%的粗骨料比使用空隙率为45.8%的粗骨料制备的低砂率混凝土的坍落度和扩展度有明显提高,说明粗骨料空隙率较低时,混凝土的工作性能显著提高,为研究高石低砂混凝土技术及相关工程应用提供了参考。

含粗骨料超高性能混凝土的力学及耐久性能

在UHPC中掺入粗骨料制备出含粗骨料超高性能混凝土(UHPC-CA),通过立方体抗压强度试验、劈裂抗拉强度试验、抗冻融循环试验及抗硫酸盐腐蚀试验,研究不同的粗骨料体积掺量(0、15%、30%、40%)和钢纤维体积掺量(0.5%、1.0%、1.5%、2.0%)对UHPC-CA力学性能和耐久性能的影响。结果表明:随着钢纤维掺量的增加,UHPC-CA立方体抗压强度总体呈上升趋势,但当钢纤维体积掺量达到2%时,部分组别抗压强度略有下降;随着粗骨料掺量的增加,UHPC-CA的抗压强度先增大后减小。随着钢纤维掺量的增加,UHPC-CA劈裂抗拉强度有所提高,当钢纤维体积掺量达到2%时,劈拉强度最大可提升86.9%,而粗骨料掺入会对劈拉强度产生不利影响。耐久性方面,钢纤维掺量的增加能够改善UHPC-CA的抗冻融和抗硫酸盐腐蚀性能,而粗骨料的掺入则会对其耐久性产生不利影响。

粗集料品质对混凝土性能的影响探讨

在当前建筑工程及桥梁工程建设中,混凝土应用范围广泛,为了确保其应用性能和优势发挥到最大化,关键任务就是要在混凝土材料预拌过程中,加强对其各项原材料质量的严格把控。其中,粗集料品质是影响混凝土性能的关键因素,若是在预拌施工时,忽视粗集料质量的管理,不仅会降低混凝土的预拌质量,影响其应用性能,而且还会给整个项目工程建设埋下一定的安全隐患。基于此,要在混凝土材料使用之前,对其粗集料的各项指标参数予以全面的检测,确保合格后再对其展开投入使用。本文通过实际工程案例,采取相应的试验检测方法对粗集料品质进行分析,并探索其对混凝土性能的影响,以供参考。

粗骨料对超高性能混凝土中钢筋黏结性能的影响

含粗骨料的超高性能混凝土(ultra-high performance concrete-coarse aggregate,UHPC-CA)拥有低成本、低收缩的优势,且适用于常温养护的现浇工程,因而具有广阔的应用前景。基于此,聚焦于UHPC-CA中的钢筋拉拔性能,开展了钢筋拉拔试验研究,分析了试件的黏结应力-滑移曲线,并系统性地探讨了粗骨料粒径、掺量以及钢纤维掺量三者如何协同作用于UHPC-CA中的钢筋黏结性能。研究发现:所有钢筋拉拔试件均呈现劈裂破坏的特征,揭示了UHPC-CA在特定条件下的力学行为特性。值得注意的是,粗骨料粒径、掺量以及钢纤维掺量对钢筋黏结性能的影响并非简单线性递增,而是存在一个最优区间,使得UHPC-CA的钢筋黏结性能达到最大化;当粗骨料粒径为5~8 mm、掺量为20%,且钢纤维掺量为2%时能够配制出具有最佳钢筋黏结性能的UHPC-CA,这一发现为实际工程应用提供了重要的参考依据。

沙漠砂-粗骨料UHPC配合比设计及性能研究

采用沙漠砂和粗骨料复配大掺量替代石英砂制备了超高性能混凝土(UHPC),通过正交试验研究了水胶比(0.16、0.18、0.20)、沙漠砂掺量(20%、40%、60%)、钢纤维掺量(1%、2%、3%)和粗骨料掺量(10%、20%、30%)对UHPC流动性和抗压强度的影响,并与未掺沙漠砂和粗骨料的基准组进行了对比。结果表明:沙漠砂-粗骨料UHPC的最佳配合比组合为水胶比0.16、沙漠砂掺量40%、钢纤维掺量2%、粗骨料掺量20%,此时,UHPC试件的28 d抗压强度较基准组提高了5.8%,流动度较基准组降低了10.4%,但流动度仍满足相关规范要求。