Carbonation Resistance of Sulphoaluminate Cement-based High Performance Concrete

The influences of water/cement ratio and admixtures on carbonation resistance of sulphoaluminate cement-based high performance concrete （HPC） were investigated. The experimental results show that with the decreasing water/cement ratio, the carbonation depth of sulphoaluminate cement-based HPC is decreased remarkably, and the carbonation resistance capability is also improved with the adding admixtures. The morphologies and structure characteristics of sulphoaluminate cement hydration products before and after carbonation were analyzed using SEM and XRD. The analysis results reveal that the main hydration product of sulphoaluminate cement, that is ettringite （AFt）, decomposes after carbonation.

High-Performance and Multifunctional Cement-Based Composite Material

Concrete is a continuously evolving material, and even the definition of high-performance concrete has changed over time. In this paper, high-performance characteristics of concrete material are considered to be those that support the desirable durability, resilience, and sustainability of civil infrastructure that directly impact our quality of life. It is proposed that high-performance material characteristics include tensile ductility, autogenous crack-width control, and material “greenness.” Furthermore, smart functionalities should be aimed at enhancing infrastructure durability, resilience, and sustainability by responding to changes in the surrounding environment of the structure in order to perform desirable functions, thus causing the material to behave in a manner more akin to certain biological materials. Based on recent advances in engineered cementitious composites (ECCs), this paper suggests that concrete embodying such high-performance characteristics and smart multifunctionalities can be designed, and holds the potential to fulfill the expected civil infrastructure needs of the 21st century. Highlights of relevant properties of ECCs are provided, and directions for necessary future research are indicated.

Creep experimental test and analysis of high-performance concrete in bridge

Factors that have effect on concrete creep include mixture composition,curing conditions,ambient exposure conditions,and element geometry.Considering concrete mixtures influence and in order to improve the prediction of prestress loss in important structures,an experimental test under laboratory conditions was carried out to investigate compression creep of two high performance concrete mixtures used for prestressed members in one bridge.Based on the experimental results,a power exponent function of creep degree for structural numerical analysis was used to model the creep degree of two HPCs,and two series of parameters of this function for two HPCs were calculated with evolution program optimum method.The experimental data was compared with CEB-FIP 90 and ACI 209(92) models,and the two code models both overestimated creep degrees of the two HPCs.So it is recommended that the power exponent function should be used in this bridge structure analysis.

Experimental study on creep of high-performance concretes

In order to investigate the compression creep of two kinds of high-performance concrete mixtures used for prestressed members in a bridge,an experimental test under laboratory conditions was carried out.Based on the experimental results,a power exponent function was used to model the creep degree of these high-performance concretes(HPCs) for structural numerical analysis,and two series parameters of this function for the HPCs were given with the optimum method of evolution program.The experimental data were compared with CEB-FIP 90 and ACI 92 models.Results show that the two code models both overestimate the creep degree of two HPCs,so it is recommended that the power exponent function should be used for the creep analysis of bridge structure.

风电塔筒用C80高性能混凝土配合比设计研究

本文以天津地区某混凝土塔筒工程实例为依托,对C80截锥状塔筒用混凝土的配合比进行优化设计,研究水胶比和砂率对混凝土工作性能、力学性能及表观效果的影响。综合各项性能测试结果表明:当C80截锥状塔筒用混凝土的水胶比为0.22,砂率为32%时,混凝土的工作性能、力学性能较优,且能够满足工程实际需求,可为该类现场预制塔筒构件用高强高性能混凝土的配合比设计提供技术参考。

基于响应面法的UHPC复合胶凝材料体系优化研究

采用基于响应面法(RSM)的D-optimal最优化设计方法设计了超高性能混凝土(UHPC)净浆配合比,研究了复合胶凝材料组分对UHPC净浆湿堆积密实度、力学性能、干燥收缩性能的影响,结合XRD、SEM等微观测试结果分析了复合胶凝材料组分间的相互作用机理。结果表明:粉煤灰和硅灰可有效提高UHPC净浆的湿堆积密实度,优化基体内部颗粒堆积状态;硫铝酸盐水泥和粉煤灰对UHPC净浆的早期强度影响显著,掺入硫铝酸盐水泥可大幅提高UHPC净浆的早期力学性能。

石灰石煅烧黏土超高性能混凝土抗压力学性能研究

为加快推进低碳建材产品的研发应用,设计并制备石灰石煅烧黏土超高性能混凝土(LC^(3)-UHPC),研究石灰石和煅烧黏土掺量对LC^(3)-UHPC流动度和抗压强度的影响。试验结果显示:随着石灰石煅烧黏土对水泥替代率的增加,LC^(3)-UHPC的抗压强度整体呈下降趋势;当煅烧黏土与石灰石质量比为1∶2、石灰石煅烧黏土对水泥的替代率为30%时,抗压强度最大,为最优配合比;抗压强度越高,形状效应对抗压强度的影响越小。

减缩剂对水泥砂浆及超高性能混凝土收缩性能的影响

研究了不同掺量的减缩剂(SRA)对水泥砂浆塑性收缩开裂、水泥水化热、水泥砂浆毛细管负压的影响,以及SRA掺量(1%、3%、4%)对超高性能混凝土(UHPC)抗压强度和收缩性能的影响。结果表明:SRA可显著降低水泥砂浆的开裂面积、平均和最大裂缝宽度,当SRA掺量为4%时,缓解塑性收缩开裂的效果最佳,开裂面积、平均和最大裂缝宽度与基准组相比分别降低了52.1%、35.0%和48.4%;SRA通过延缓毛细管负压的发展,降低了水泥砂浆的塑性收缩开裂;随着SRA掺量的增加,UHPC的抗压强度提高越明显,UHPC的收缩显著降低;当减缩剂掺量为4%时,UHPC的28 d抗压强度达140.0 MPa,收缩率最低。

高韧性纤维水泥稳定碎石路用性能研究

反射裂缝是沥青路面半刚性基层中常有出现的问题,研究提出将自主研发的特种高韧性纤维掺入到水泥稳定碎石中,达到改善其抗裂性能的目的,通过测定多种纤维掺量水泥稳定碎石的无侧限抗压强度、劈裂强度、单轴压缩模量及收缩系数,分析该特种高韧性纤维对水稳碎石材料性能影响的变化规律。试验结果表明:随着纤维掺量逐渐大,水泥稳定碎石养护7、28、90 d的无侧限抗压强度和劈裂强度均呈现先增大后减小的趋势,且各种指标强度均在1‰纤维掺量时最大,单轴压缩模量在2‰下有最大值。养护90 d的无侧限抗压强度和劈裂强度在掺入1‰纤维后分别提高14.1%和9%;掺加特种高韧性纤维能够改善水稳碎石材料的收缩性能,纤维掺量为1‰时,温缩系数和干缩系数分别比不掺时提高14.1%和12.8%。

低碱高硅率中抗硫酸盐水泥生产实践

通过优选碱含量低的原材料、采用高硅率生料配料、改进熟料煅烧工艺、合理控制水泥粉磨指标,研发生产了水泥碱含量<0.30%、14d线性膨胀率<0.030%,熟料铝酸三钙<4.0%、硅酸率为3.50左右的低碱高硅率中抗硫酸盐水泥,满足了水工混凝土、碱及硫酸盐含量较高地区的地下混凝土结构工程对特种水泥的质量需求。

精铣刨高性能水泥混凝土路面降噪效果测试与分析

高性能水泥混凝土路面(HPPC)与精铣刨工艺相结合,可使路面形成微露石子、纵向纹理的效果,从而降低胎噪。采用随车声强法测试SMA沥青路面、普通水泥混凝土路面和精铣刨高性能水泥混凝土路面在小型轿车和重卡两种车型、不同车速下的噪声值。测试结果表明:小型轿车、重卡在精铣刨高性能水泥混凝土路面的噪声值比SMA路面高1~2dB,且小型轿车在精铣刨HPPC路面的噪声均值落入噪声分区的中端控制区下游和低端容许区,降噪效果明显;精铣刨HPPC路面较其他两种路面能够更好地降低1250Hz以上的高频段噪声。

复合型掺合料高性能混凝土抗硫酸盐侵蚀性能研究

本文选用乌鲁木齐地区水泥、掺合料、外加剂等原材料,制备不同的高性能混凝土试件,从硫酸盐侵蚀的机理入手,研究掺加复合型掺合料高性能混凝土的抗硫酸盐侵蚀性能。结果表明:当水胶比为0.40或0.35,掺加30%复合型掺合料时,高性能混凝土可以抵抗SO_(2)^(2-)浓度10000mg/L及以下硫酸盐环境水的侵蚀;水胶比≤0.30、掺30%复合型掺合料的高性能混凝土,与水胶比≤0.40、掺50%复合型掺合料的高性能混凝土均能抵抗SO_(4)^(2-)浓度20250mg/L及以下硫酸盐环境水的侵蚀;水胶比和复合型掺合料的掺量均是影响高性能混凝土抗硫酸盐侵蚀性能的重要因素,随着水胶比的降低,高性能混凝土的抗硫酸盐侵蚀能力逐渐增强,而在相同水胶比条件下,随着复合型掺合料掺量的降低,与之相对应的高性能混凝土的抗侵蚀能力随之下降。

超高性能混凝土中纤维的界面效应及其与水泥基材的匹配性研究

为了解决超高性能混凝土脆性大和易开裂的问题,增加其抗拉强度和韧性,研究建立了室内试验模型,通过单纤维拉拔试验研究不同纤维类型和纤维埋置深度对水泥基材界面的黏结性能影响。结果表明,在相同的水泥基材料条件下,不锈钢纤维的抗拔荷载最大,束状单丝聚丙烯纤维的抗拔荷载次之,短切丝碳纤维的抗拔荷载远小于不锈钢纤维和束状单丝聚丙烯纤维,纤维类型对界面黏结强度、抗拔荷载影响规律一致;随着纤维埋置深度的增加,不锈钢纤维的和束状单丝聚丙烯纤维的最大拔出荷载均不断增加,而界面黏结强度均不断减小,短切丝碳纤维的最大拔出荷载和界面黏结强度变化不明显。

Preparation of Super Composite Cement with a Lower Clinker Content and a Larger Amount of Industrial Wastes

The effects of the grinding mode,fineness,gypsum kinds and dosage,mix proportions on properties of the composite cements consisting of slag,fly ash,limestone and a lower content clinker were investigated,respectively.The results show that when the proportions among slag,fly ash and limestone are appropriate,the grinding technology and system are reasonable,the optimized gypsums and additives are effective,the 52.5R grade cement (52.5R grade cement means a higher strength than 52.5 at early age) can be prepared by clinker dosage of 50% in weight,the 42.5R or 42.5,32.5 grade composite cement containing 40% and 30% clinker also may be made, respectively.Moreover,the high performance concrete prepared from the above composite cements was studied experimentally.

杂散电流环境下UHPC劣化特征研究

为研究杂散电流环境下超高性能混凝土(UHPC)的耐久性问题,采用电迁移加速锈蚀试验方法,研究了环境类型、氯离子浓度、胶材类型对杂散电流环境下UHPC锈蚀形态、超声波速损失率、损伤深度、孔隙率及强度损失的影响。结果表明:杂散电流环境下UHPC试件首先在表面产生裂缝、剥落等现象,随通电时间增加,损伤由表及里递进发展,内部纤维严重锈蚀并与基体分离;杂散电流环境下UHPC损伤深度随通电时间的增加近似呈二次函数增长,无氯离子环境或氯离子浓度小于1%(质量分数)时,对UHPC损伤深度的影响不显著,但随氯离子浓度增大,影响渐趋显著,氯离子浓度为3%时UHPC的损伤深度较1%时大1倍;相同条件下,UHPC越密实,抗杂散电流损伤的能力越强,在UHPC中掺入磷渣粉或粉煤灰有助于增强其耐蚀性能。

中热及低热水泥配制超高性能混凝土的研究

分别采用低热水泥、中热水泥、普硅水泥及大掺量矿物掺合料配制超高性能混凝土(UHPC),研究了UHPC力学性能、体积稳定性及热学性能的变化。结果表明:普硅水泥配制的UHPC力学性能最好,采用中热、低热水泥或增加矿物掺合料掺量均会使混凝土的抗压及劈裂抗拉强度降低;中热、低热水泥可以减小UHPC的自收缩,增大干燥收缩,但UHPC自收缩和干燥收缩的收缩总量减小,且低热水泥的降低效果优于中热水泥,相较于普硅水泥,低热水泥配制的UHPC总收缩量减小了33%;中热、低热水泥配制UHPC可以降低混凝土的水化速率,同时延缓到达最大水化速率的时间;单纯采用低热水泥降低UHPC绝热温升效果有限,混凝土中心温度与普硅水泥配制的UHPC相差不大。

超高性能混凝土的工作性及力学性能影响因素研究

研究了矿渣粉掺量、硅灰掺量、钢纤维掺量和水胶比对超高性能混凝土(UHPC)工作性和力学性能的影响,并通过显著性分析探讨了各因素对UHPC性能的影响程度。结果表明:随着矿渣粉掺量的增加,UHPC的扩展度和28 d抗压、抗折强度均先增大后减小;随着硅灰掺量的增加,UHPC的扩展度和28 d抗压、抗折强度基本呈先增大后减小的趋势;随着钢纤维掺量的增加,UHPC的扩展度降低,28 d抗压、抗折强度增大;随着水胶比的增加,UHPC的扩展度增大,28 d抗压、抗折强度先增大后减小;钢纤维掺量对UHPC力学性能的影响程度最大,水胶比对UHPC工作性的影响程度最大;综合考虑工作性和力学性能,自密实UHPC的最佳配合比为矿渣粉掺量20%、硅灰掺量12%、钢纤维掺量2.0%、水胶比0.18。

超细复合掺合料在水泥和不同强度等级混凝土中的应用研究

本研究采用的超细复合掺合料由50%的S95矿粉和50%的粉煤灰组成,经过超细球磨机混合粉磨得到,探索了超细复合掺合料在水泥、不同强度等级混凝土及超高性能混凝土的应用方式,研究了其对水泥和混凝土性能的影响。研究表明:超细复合掺合料能替代10%~20%的成品P·O 42.5水泥,水泥3 d强度不降低,28 d抗折和抗压强度分别提高0.5 MPa和10 MPa以上,其他性能均能符合标准要求;在C30、C50和C80强度等级混凝土中超细复合掺合料完全替代矿粉,可提高混凝土的流动性和抗压强度,C30强度等级混凝土的耐久性能得到明显改善;在超高性能混凝土中超细复合掺合料替代20%~50%的水泥,超高性能混凝土流动性和28 d抗压强度均先增加后降低,替代量40%时为最优。

工业废渣资源化及其可持续发展(Ⅱ)——与水泥混凝土工业相结合走可持续发展之路

介绍了我国水泥混凝土工业的发展现状,论述了工业废渣的综合利用只有与水泥混凝土工业紧密结合才能走自身可持续发展之路,同时强调水泥混凝土依靠工业废渣提高耐久性的必要性。此外,还提出了将工业废渣作为辅助性胶凝材料制备绿色高性能水泥混凝土的方法和各种注意事项。

绿色高性能混凝土与建筑工程材料的可持续发展

讨论了绿色高性能混凝土（简称ＧＨＰＣ）的涵义，开发使用ＧＨＰＣ在保护环境、节约资源和能源等方面的社会意义，以及ＧＨＰＣ对原材料的要求和发展ＧＨＰＣ尚需进行的工作．