Workability and Strength of Ceramsite Self-Compacting Concrete with Steel Slag Sand

This study focuses on the workability and compressive strength of ceramsite self-compacting concrete with fine aggregate partially substituted by steel slag sand(CSLSCC)to prevent the pollution of steel slag in the environment.The SF,J-ring,visual stability index,and sieve analysis tests are primarily employed in this research to investigate the workability of freshly mixed self-compacting concrete containing steel slag at various steel slag sand replacement rates.The experiment results indicate that CSLSCC with the 20%volume percentage of steel slag(VPS)performs better workability,higher strength,and higher specific strength.The 7-day compressive strength of CSLSCC with the 0.4 of the water-binder ratio(W/B),decreases with the increase of steel slag content,while the 28-day compressive strength increases significantly.The ceramsite self-compacting concrete with good comprehensive performance can be obtained when the substitution rate of steel slag sand for fine aggregate is less than 20%(volume percentage).

Effect of Ceramsite Structure on Microstructure of Interfacial Zone and Durability of Combined Aggregate Concrete

Structure characteristics of three kinds of ceramsite with different water absorption and the influence on microstructure of interfacial zone as well as performance of chloride permeabil-ity and frost resistance of combined aggregate concrete were investigated. The results show that, dense shell and closed internal pore have sharp effects on lowering water absorption of ceramsite. However, the ceramsite with high water absorption has obvious effect on the densification of interfa-cial paste which would develop a structure with lower porosity, finer aperture and higher microhard-ness. Furthermore, the impermeability and frost-resistance of concrete can be improved due to the ef-fect of water absorption and releasing by ceramsite with higher water absorption.

Effects of Different Calcining Temperatures on the Properties of Ceramsite Prepared by High-carbon Gasification Slag

The structure and characteristics of high-performance lightweight aggregates produced by high-carbon gasification slag were investigated by X-ray diffraction,scanning electron microscopy,thermogravimetry/differential thermogravimetr,differential scanning calorimetry-Fourier transform infrared,and mercury intrusion porosimetry,respectively.The experimental results show that the ceramsite undergoes two weightless stages in the calcining process.With the increase in the calcining temperature,a large number of pores are formed inside the ceramsite,its structure becomes denser,but the calcining temperature band of the ceramsite becomes narrow.The crystalline phase of the ceramsite changes at different calcining temperatures and the mineral phase changes from the earlieralbite,quartz,oligoclase,hematite,etc,to a silica-aluminum-rich glass phase.The 1130℃ is a more suitable calcining temperature,and the cylinder compressive strength of ceramics is 11.59 MPa,the packing density,apparent density,porosity,and water absorption are 939.11 kg/m^(3),1643.75 kg/m^(3),28.11%,and 10.35%,respectively,which can meet the standards for high-strength lightweight aggregates.

Ceramsite Containing Iron Oxide and its Use as Functional Aggregate in Microwave Absorbing Cement-based Materials

Electromagnetic（EM） wave absorbing cement-based composite has promising applications in protecting civil and military buildings from electromagnetic interferences. A new idea of preparing EM wave absorbing cement-based composite is proposed by using ceramsite containing iron oxide as EM wave absorbing functional aggregate. The ceramsite was synthesized by adding 10 wt% Fe3O4 into clay and sintering at 1 200 ℃, which shows obvious dielectric and magnetic loss properties for electromagnetic wave. The maximum reflection loss（RL） of the concrete specimens prepared with the ceramsite is between-10.2--10.7 dB（corresponding to absorption greater than 90% EM energy） in the bandwidth of 8-18 GHz. In addition, the compressive strength at 28 days age of the concrete is 46 MPa, showing the potentiality of being used as structural components in buildings.

Evaluation method of cracking resistance of lightweight aggregate concrete

The cracking behavior of lightweight aggregate concrete(LWAC) was investigated by mechanical analysis, SEM and cracking-resistant test where a shrinkage-restrained ring with a clapboard was used. The relationship between the ceramsite type and the cracking resistance of LWAC was built up and compared with that of normal-weight coarse aggregate concrete(NWAC). A new method was proposed to evaluate the cracking resistance of concrete, where the concepts of cracking coefficient ζt(t) and the evaluation index Acr(t) were proposed, and the development of micro-cracks and damage accumulation were recognized. For the concrete with an ascending cracking coefficient curve, the larger Acr(t) is, the lower cracking resistance of concrete is. For the concrete with a descending cracking coefficient curve, the larger Acr(t) is, the stronger the cracking resistance of concrete is. The evaluation results show that in the case of that all the three types of coarse aggregates in concrete are pre-soaked for 24 h, NWAC has the lowest cracking resistance, followed by the LWAC with lower water absorption capacity ceramsite and the LWAC with higher water absorption capacity ceramsite has the strongest cracking resistance. The proposed method has obvious advantages over the cracking age method, because it can evaluate the cracking behavior of concrete even if the concrete has not an observable crack.

SFCC现场导热系数与温度场实测及预测方法研究

为确定钢纤维页岩陶粒混凝土(SFCC)现场实际的导热系数,与桥面板施工同步制作了不同钢纤维体积分数的SFCC试件,采用热板法进行测定,校核并扩展了导热系数预测公式,并且对高温沥青摊铺时SFCC桥面板的温度场进行了实测和数值模拟.结果表明:环境湿度为67%时,SFCC的实测导热系数为0.915~1.409 W/(m·K),增加钢纤维体积分数可提高SFCC导热系数;考虑湿度和钢纤维影响后的扩展Maxwell公式预测值与实测值吻合良好;高温沥青摊铺时桥面板SFCC混凝土内的温度梯度可达20.5℃,超过规范日温差,采用数值模拟可有效计算桥面板温度场.

陶粒混凝土力学性能试验及数值模拟研究

陶粒混凝土具有轻质高强、保温隔热性能好和抗震性能优异等特点被作为功能性材料应用于非承重结构中。通过试配得到陶粒混凝土的基础配合比,在此基础上进行力学性能试验,研究陶砂取代率、粉煤灰掺量以及聚丙烯纤维体积掺量对陶粒混凝土配合比设计的影响。结果表明:陶砂取代率为50%,粉煤灰掺量为20%时,陶粒混凝土的力学性能更优异,更轻质高强;掺入适量的聚丙烯纤维可以改善陶粒混凝土的脆性特征。建立二维细观模型来对陶粒混凝土抗压强度、弹性模量、受压应力-应变全曲线进行数值模拟,并与试验结果进行对比分析,建立的二维细观模型较为可靠,可用来预测陶粒混凝土的基本力学性能。

钢纤维掺量对陶粒混凝土梁长期变形的影响规律

为探究钢纤维掺量对陶粒混凝土梁徐变的影响规律,通过长期变形观测试验、理论推导式和有限元建模的方法对不同钢纤维掺量的陶粒混凝土梁的徐变性能开展研究。首先,对4种钢纤维掺量的陶粒混凝土梁开展了连续180 d的徐变挠度观测,获得徐变挠度-加载时间关系曲线、钢纤维掺量对徐变挠度的影响规律曲线;随后,参照ACI209徐变系数计算式和ACI435徐变计算式建立了隐含钢纤维掺量的陶粒混凝土梁徐变计算式;最后,按试验梁参数建立了有限元模型。研究结果表明:陶粒混凝土试件梁加载前期徐变增长较快,随着时间推移徐变增长速率逐渐变缓,加载至120 d后趋于稳定;钢纤维掺量对陶粒混凝土梁徐变影响明显,钢纤维掺量低于0.5%,掺加钢纤维对陶粒混凝土梁的徐变值影响小;钢纤维掺量在0.5%~1.0%时,增加钢纤维掺量能有效地较大幅度降低长期荷载作用下的徐变值;但当钢纤维掺量超过1.0%后降低的效果有所减弱;陶粒混凝土梁徐变计算式计算结果与试验实测值吻合较好,能够很好地反映出陶粒混凝土梁的徐变变化规律;有限元模拟进一步验证了钢纤维掺量对陶粒混凝土梁徐变的影响规律和徐变计算式。

双掺陶粒轻质高强混凝土的力学及耐久性能试验研究

通过在混凝土中掺入黏土陶粒和页岩陶粒,使其具备较高强度的同时具有较低的干表观密度和较好的耐久性能,旨在探索制备28 d干表观密度不大于1950 kg/m3、28 d强度不小于50 MPa的轻质高强混凝土(Lightweight High-Strength Concrete,缩写:LWHSC)的方法。同时研究了黏土陶粒和页岩陶粒双掺对轻质高强混凝土抗压强度、干表观密度和耐久性的影响。结果表明,所制备的LWHSC的抗压强度试件破坏形态无异于普通混凝土,但使用黏土陶粒部分替代页岩陶粒可有效降低LWHSC干表观密度;适当增加胶凝材料用量并辅以优化陶粒的双掺比例,对除抗冻性以外的其它耐久性能具有一定的改善作用。研究成果可为认识、优化和开发页岩陶粒和黏土陶粒双掺LWHSC及其在工程中的应用提供参考。

沿海地区台风荷载下陶粒加气混凝土砌块填充墙斜裂缝试验研究

为研究沿海地区低抗震设防烈度条件下陶粒加气混凝土砌块填充墙的开裂原因,采用PKPM软件分析了某13层框架结构住宅在台风荷载和6度抗震设防烈度下结构的层间位移,结果表明:在该地区基本风压下,该工程的最大层间位移角与6度抗震设防烈度时基本相当。同时进行了一榀足尺框架模型试验,结果表明,当主体结构还在弹性阶段时,模型的整体刚度就急剧下降,填充墙就已经开裂。当试件的位移角达到1/1 092时,填充墙开裂严重,此时相当于刚度修正后的13层框架住宅案例在1.27kN/m^(2)的风压下的表现。因此按照目前的结构设计参数取值和施工构造措施,沿海地区陶粒加气混凝土砌块填充墙的开裂在所难免。为避免该斜裂缝发生,应在设计和施工阶段采取新的设计方法和构造措施。

初始加载龄期对陶粒混凝土梁徐变性能的影响

徐变性能对混凝土结构的承载性能有较大影响,初始加载龄期(养护龄期)对徐变有较大影响,基于4种不同初始加载龄期的陶粒混凝土梁,进行了为期200 d的徐变试验,研究初始加载龄期对陶粒混凝土梁徐变性能的影响规律试验研究,并建立基于ACI-209徐变计算模型和ACI-435长期挠度计算方法建立陶粒混凝土结构的徐变值计算式。结果显示:随着初始加载龄期的增加,陶粒混凝土梁的初始挠度、徐变挠度速度和最终挠度值均呈现减小的趋势,减小的幅度也随着加载龄期的延长而逐渐减弱;徐变值计算式的计算值与试验观测值较接近,所建立的计算式具有较好的准确性和适用性;综合考虑工期和经济指标,建议将90 d作为预制陶粒混凝土梁的加载龄期。研究结论可为陶粒混凝土结构徐变计算提供参考。

基于压电传感器的纤维陶粒混凝土冻融损伤检测

针对纤维陶粒混凝土低温下受到冻融损伤导致影响结构安全性问题,基于压电陶瓷传感器进行损伤检测。利用压电传感技术对冻融后的纤维陶粒混凝土试件进行检测,获得不同冻融次数下的应力波信号。当冻融次数增加,试件相对动弹模量和抗弯强度下降,压电陶瓷检测到的应力波信号幅值相应减小,基于应力波的衰减,采用小波包能量分析法将其转化为损伤指数,与冻融试验评价指标损伤程度和抗弯强度损失率进行拟合,吻合度较高。结果表明,纤维陶粒混凝土损伤指数与冻融损伤程度和抗弯强度损失率相关性较强,该纤维陶粒混凝土冻融损伤无损检测方法具有良好可行性。

粉煤灰陶粒轻质混凝土声屏障性能试验研究

混凝土是一种应用广泛、可使用多种固废制备的建筑材料。本研究将粉煤灰陶粒作为轻骨料,水泥-粉煤灰-硅灰-煤系偏高岭土作为复合胶凝材料,制备用作声屏障的粉煤灰陶粒轻质混凝土,并对其力学性能、吸声性能和抗碳化性能进行试验研究。结果表明:当粉煤灰-硅灰-煤系偏高岭土总掺量为胶凝材料总质量的10%时,试样的力学性能、抗碳化性能有所提高,吸声性能有所降低;随着粉煤灰-硅灰-煤系偏高岭土掺量进一步增加,试样的力学性能、抗碳化性能有所降低,吸声性能有所提高。1500 Hz及以下频率吸声系数变化幅度较小,2000 Hz时吸声效果最好,试样的平均吸声系数在0.44~0.58,降噪系数在0.74~0.89。

彩色陶粒混凝土冻融循环试验研究

为研究彩色陶粒混凝土的抗冻性能,本文对红色颜料不同掺量的彩色陶粒混凝土试件进行了300次冻融循环试验,并计算其质量损失率与相对动弹性模量;在此基础上,建立了彩色陶粒混凝土质量损失率、冻融损伤经验模型,并运用响应曲面法综合分析了冻融循环次数、红色颜料掺量对彩色陶粒混凝土质量损失率和冻融损伤度的影响程度。研究结果表明:掺加红色颜料可有效增强陶粒混凝土的抗冻性能。

玄武岩纤维对煤矸石陶粒混凝土抗冻性的影响

为促进废弃煤矸石在寒冷地区的建材资源化利用,研究了煤矸石陶粒作为粗骨料对混凝土抗冻性能的影响,探究了玄武岩纤维对煤矸石陶粒混凝土抗冻性能提升的效果。试验共设计了4种类型混凝土,纤维体积掺量分别为0%,0.1%,0.2%和0.3%。采用快速冻融循环试验,比较了纤维掺入对基体动弹性模量的影响规律,同时,利用图像识别技术引入分形维数定量表征试件冻融损伤程度。之后,开展了毛细吸水试验,对比了冻融损伤后基体的累积吸水量和毛细吸水系数的变化规律。结果表明,玄武岩纤维的加入能显著提高煤矸石陶粒混凝土的抗冻性能。随着纤维掺量的增加,煤矸石陶粒混凝土的动弹性模量损失率降低,基体表面冻融剥蚀明显缓解,引入分形维数可以定量地分析煤矸石陶粒混凝土外观形貌的变化规律。冻融损伤后,基体毛细吸水能力显著提高,而在相同的冻融循环下,基体的毛细吸水能力随着玄武岩纤维掺量的增加而降低。

免烧陶粒及陶粒混凝土性能研究进展

基于固废制备的陶粒具有密度小、导热系数低等特点,成为替代天然骨料的一个重要发展方向。与烧结法相比,免烧结陶粒不仅可以有效回收利用工业废弃物和副产品,而且具有成本低、耗能低、制备简单等优点,符合国家双碳战略。本文系统梳理归纳了免烧陶粒制备工艺、制备参数及制备原料对陶粒品质的影响规律,得出免烧陶粒混凝土的导热系数低于1.0 W/(m·K),保温性能良好,具有作为保温材料的良好潜力;同时分析了免烧结陶粒替代天然骨料应用于混凝土中对其工作性能、力学性能和耐久性能的影响;阐述了陶粒混凝土作为墙板等构件在建筑上的应用,总结和归纳研究进展,并提出未来的研究方向。

陶粒泡沫混凝土基本力学性能试验统计分析

陶粒泡沫混凝土应用于建筑外墙或预制装配式墙板保温体系时需同时兼顾质轻和相应结构强度要求,且对材料相关性能的稳定性要求较高.本文以建筑渣土陶粒为集料,经过物理发泡制备了多批次陶粒泡沫混凝土,通过试验统计研究了陶粒泡沫混凝土立方体抗压强度的概率分布、基本力学性能参数及相互关系.结果表明:立方体抗压强度整体更服从对数正态分布,拟合判定系数达0.997.轴心抗压强度与立方体抗压强度呈较稳定的线性关系,换算系数区间在0.76~0.99,而劈裂抗拉强度与抗压强度呈幂函数关系.全体样本数据抗压强度稳定在5.9~7.6 MPa范围.此外,立方体抗压强度低于7.5 MPa的试块样本,其抗拉强度值的离散性较小.

单掺和双掺不同长径比钢纤维对全轻混凝土力学性能的影响

为研究单掺和双掺不同长径比钢纤维对免烧结粉煤灰陶粒全轻混凝土力学性能影响,选用体积掺量为1%的剪切钢纤维作为增强材料,以钢纤维长径比(18.75,25和31.25)和掺入方式(单掺、双掺)为试验参数,对LC30全轻混凝土进行立方体抗压强度、轴心抗压强度、抗折强度、劈裂抗拉强度和弹性模量试验。试验结果表明:钢纤维能明显改善全轻混凝土的力学性能;不同的长径比和掺入方式对全轻混凝土的抗折度和劈裂抗拉强度影响较大,对立方体抗压强度和轴心抗压强度影响较小,对弹性模量几乎没有影响。

HRB500钢筋轻骨料混凝土柱轴压承载力试验研究及可靠度分析

为了研究高强钢筋页岩陶粒混凝土轴压柱的承载力,制作了8根试件,研究了配筋率、配箍率、混凝土强度等对其承载力和破坏形态的影响。此外,得到了相关文献的有关统计参数,采用JC法,并利用Matlab软件编程迭代求解高强钢筋页岩陶粒混凝土轴压柱的可靠度指标。结果表明:在其他设计参数相同前提下,轴压柱的可靠度指标随着配筋率、配箍率、稳定系数以及截面面积的增大而增大,随着荷载效应比的增大而降低;JGJ/T 12—2019《轻骨料混凝土应用技术标准》中的轴心受压承载力计算公式可以满足GB 50068—2018《建筑结构可靠性设计统一标准》中的可靠指标要求。

陶粒泵送混凝土的研究现状综述

陶粒混凝土应用于超高层建筑中能降低建筑物自重,但其泵送过程中存在难点。对泵送过程中陶粒混凝土坍落度损失过大、陶粒上浮、混凝土离析分层及堵泵的解决方法进行总结。发现掺入矿物掺合料、选择高效减水剂或对陶粒预湿处理能降低拌合物坍落度损失;采用小粒径破碎型陶粒、掺入矿物掺合料、选择合适施工工艺或掺入外加剂能抑制陶粒上浮;掺入外加剂、控制振捣、搅拌或自由倾落高度能解决离析分层;采用高水灰比、掺入矿料、控制泵送速度或掺入外加剂能降低堵泵现象。