A Simple Mix Proportion Design Method Based on Frost Durability for Recycled High Performance Concrete Using Fully Coarse Recycled Aggregate

Durability design of recycled high performance concrete（RHPC） is fundamental for improving the use rate and level of concrete waste as coarse recycled aggregate（CRA）. We discussed a frostdurability-based mix proportion design method for RHPC using 100 % CRA and natural sand. Five groups of RHPC mixes with five strength grades（40, 50, 60, 70 and 80 MPa） were produced using CRA with four quality classes, and their workability, 28 d compressive strengths and frost resistances（measured by the compressive strength loss ratio and the relative dynamic modulus of elasticity） were tested. Relationships between the 28 d compressive strength, the frost resistance and the CRA quality characteristic parameter, water absorption, were then developed. The criterion of a CRA maximum water absorption limit value for RHPC was suggested, independent of its source and quality class. The results show that all RHPC mixes achieve the expected target workability, strength, and frost durability. The research results demonstrate that the application of the proposed method does not require trial testing prior to use.

Equal Volumes of Sand and Gravel Concrete Mix Ratios in Cameroon and Its Effect on Concrete Compressive Strength

In recent years, the rationalization of concrete mix ratios which batches equal volumes of sand and gravel in building projects has been gaining grounds in the Cameroon construction industry. The main objective of this study is therefore to investigate if the concrete produced with rationalized mix ratio can be adopted as conventional mix ratio in terms of minimum required compression strength of concrete for buildings. Specifically this work compared the conventional mix ratio of 350 kg of cement: 400 liters of sand: 800 liters of gravel for a cubic meter and the rationalized batch of 350 kg of cement: 600 liters of sand: 600 liters of 5/15 gravel, 15/25 gravel and a combination of 5/15 + 15/25 gravel. Average compressive tests’results for both the conventional and the rationalized mix ratios were found to meet the minimum compressive strength of 65% at 7 days, 90% at 14 days and 99% at 28 days for gravel size combination 5/15 + 15/25. Single size gravel of 5/15 and 15/25 did not meet the minimum required compressive strength of 20 N/mm2 for the rationalized mix ratio at 28 days curing based on the minimum compressive strength required, this study arrives at the conclusion that the equal volumes of sand and gravel mix ratio of 350 kg/m3 of cement: 600 liters of sand: 600 liters of gravel mix ratio can be adopted as a conventional concrete mix ratio for gravel size 5/15 + 15/25.

Effect of Flaky Plastic Particle Size and Volume Used as Partial Replacement of Gravel on Compressive Strength and Density of Concrete Mix

Common ways of disposing waste plastic such as incineration and landfilling have negative impacts on the environment. Partial replacement of natural aggregate in concrete with waste plastic including polyethylene terephthalate (PET) is more environmental friendly and sustainable. The effect of adding 5% to 20% waste plastic by volume of natural coarse aggregate (“gravel”) and plastic particle size (3 to 7 mm) on the density and compressive strength of plastic-concrete mix after 28 days of curing was studied. The results showed that density of the concrete decreased from 2406.7 to 2286.7 kg/m3 as waste plastic increased from 5% to 20% v/v compared with 2443.3 kg/m3 recorded by concrete without waste plastic. Change in particle size from 3 to 7 mm has no significant effect on the density of the plastic-concrete mix. The compressive strength decreased as the volume and particle size of waste plastic increased. When waste plastic volume changed from 5% to 20% v/v, the compressive strength decreased from 20.5 to 15 MPa, 18.6 to 14.3 MPa and 17.2 to 13.8 MPa for 3, 5 and 7 mm waste plastic particle size respectively while the concrete without plastic has 21.33 MPa. Therefore, the addition of 5% (v/v gravel) of flaky waste plastic in the concrete produces a lightweight concrete which could offer economic benefit without substantially reducing the compressive strength of the plastic-concrete mix.

Effects of Curing Conditions on Strength Development of High Strength Concrete

This paper presents the results of a series of studies on the influence of curing conditions on the strength development of high strength concrete. The 1-, 3-, 7-, 14- and 28-day strengths of four different mixes of Grade 75 similar to 80 concrete, with or without pulverized fuel ash and/or condensed silica fume, under five different curing regimes were investigated. It is revealed that the curing conditions have significant influence on both the short term and long term strength development of the concrete and that concrete mixes of the same grade but containing different mineral admixtures show distinct favour for a curing regime. These results will be helpful for evaluating suitable curing methods for high strength concrete with different mix proportions.

Local Aggregate in Production of Concrete Mix in Jordan

Concrete properties such as unit weight and compressive strength are highly dependable on the properties of aggregate. Current research aims to study the effect of aggregate properties on concrete considering the resource of aggregate. The properties of aggregate and fine sand were studied (specific gravity, density, absorption, and abrasion). Also, the properties of concrete were studied (density, unit weight, and compressive strength). Samples of coarse and medium aggregates, and fine sand were collected from different areas in Jordan (Ajloun, Amman, Aqaba, Irbid, Jerash, Karak, Ma’an, Madaba, Salt, Zarqa, and Tafila) to be tested and used in concrete mix. Aggregate from South of Jordan has higher values in specific gravity and bulk density (Aqaba, Ma’an, and Karak aggregates). Also, the same aggregate samples have lower values in absorption and abrasion (Ma’an, Aqaba, Karak, and Tafila). For the properties of concrete that include density, unit weight, and compressive strength, all samples have achieved the design properties and strength in the current study. For density and unit weight, samples from South of Jordan have higher values (Ma’an and Aqaba). And for compressive strength, Ma’an, Irbid and Amman concrete samples have the highest values at 7-day, while the 28-day compressive strength comes highest for Zarqa, Ma’an, Irbid and Amman. From the results of the current study, the compressive strength at 7-day and 28-day is related to the density of coarse and medium aggregate, abrasion, and absorption. The higher the density, the higher the compressive strength. And the lower abrasion and absorption, the higher the compressive strength of concrete. Current research will be useful in selecting the source of aggregate to produce a considerable concrete strength.

Effects of Recycled Aggregate Content on Pervious Concrete Performance

A recycled aggregate(RA)was prepared by crushing and sieving demolished discarded concrete pavements and was subsequently tested and analyzed to determine its various physical properties.On this basis,pervious concrete(PC)mix proportions were designed.Coarse RA particles with sizes of 5–10 and 10–20 mm were selected.Concrete specimens were prepared with a water–cement ratio of 0.3,an aggregate–cement ratio of 4.5,the substitute rates of RA with 0,25%,50%,75%and a single-/double-gap-graded RA mix(mass ratio of particles with sizes of 5–10 mm to particles with sizes of 10–20 mm:1:1,1:2,2:1,2:3 and 3:2).Various properties of the RA-containing PC(RPC)were determined by analyzing the compressive strength,splitting tensile strength,effective porosity,permeation coefficient and impact and abrasion resistance of the specimens.The results showed the following:The density of the RPC decreased with an increasing RA replacement ratio.The density of the RPC prepared with a double-gapgraded RA mix was lower than that prepared with a single-gap-graded RA(particle size:10–20 mm)mix.The permeation coefficient of the RPC increased with increasing porosity.The splitting tensile strength of the RPC was positively correlated with its compressive strength.The compressive strength of the RPC decreased with increasing porosity.The regression analysis showed that the impact and abrasion resistance of the RPC increased with increasing compressive strength.In addition,all of the RPC specimens met the strength and permeation requirements.This study can provide theoretical support for the application of RPC.

Mechanical Properties and ITZ Microstructure of Recycled Aggregate Concrete Using Carbonated Recycled Coarse Aggregate

The effect of carbonation treatment and mixing method on the mechanical properties and interfacial transition zone（ITZ） properties of recycled aggregate concrete（RAC） was investigated. Properties of recycled concrete aggregate（RCA） were tested firstly. Then, five types of concretes were made and slump of fresh concrete was measured immediately after mixing. Compressive strength and splitting tensile strength of hardened concrete were measured at 28 d. Meanwhile, the microstructure of RAC was analyzed by backscattered electron（BSE） image. It was found that the water absorption ratio of carbonated recycled concrete aggregate（CRCA） was much lower when compared to the untreated RCA. Comparatively, the apparent density of CRCA was not significantly modified. The concrete strength results indicate that the mix CRAC-2 prepared with CRCA by adopting two-stage mixing approach shows the highest compressive strength value compared to the other mixes. The microstructural analysis demonstrate that the mix CRAC-2 has a much denser old ITZ than the untreated RAC because of the chemical reaction between CO2 and the hydration products of RCA. This study confirms that the ITZ microstructure of RAC can be efficiently modified by carbonation treatment of RCA and encourages broadening the application of construction and demolition wastes.

Mix design optimization of seawater sea sand coral aggregate concrete

With the resource shortage in coastal areas,the construction of concrete structures using freshwater and river sand has brought great economic and environmental costs.The use of seawater,sea sand,and coral aggregates in concrete mixes has become an alternative solution for coastal and marine structures,especially for offshore structures and artificial islands.In this study,378 seawater,sea sand,and coral aggregate concrete(Coral-SWSSC)specimens were prepared,and their mechanical properties were investigated comprehensively through compressive tests to explore the optimized mix design at different grades.Results showed that the mechanical properties of Coral-SWSSC were strongly correlated with the water-to-binder ratios,coastal particle gradings,and pretreatment method of coastal particles.Based on the experimental results,mix proportion designs of CoralSWSSC were proposed for concrete from C20 to C50 grades,and the failure mechanism of Coral-SWSSC at different grades was discussed according to their respective failure modes.The findings of the current study provide knowledge on the optimized design of Coral-SWSSC,which can be used to promote the application of Coral-SWSSC in offshore,marine,and ocean engineering.

Development of mix design method based on statistical analysis of different factors for geopolymer concrete

The present study proposes the mix design method of Fly Ash(FA)based geopolymer concrete using Response Surface Methodology(RSM).In this method,different factors,including binder content,alkali/binder ratio,NS/NH ratio(sodium silicate/sodium hydroxide),NH molarity,and water/solids ratio were considered for the mix design of geopolymer concrete.The 2D contour plots were used to setup the mix design method to achieve the target compressive strength.The proposed mix design method of geopolymer concrete is divided into three categories based on curing regime,specifically one ambient curing(25°C)and two heat curing(60 and 90°C).The proposed mix design method of geopolymer concrete was validated through experimentation of M30,M50,and M70 concrete mixes at all curing regimes.The observed experimental compressive strength results validate the mix design method by more than 90%of their target strength.Furthermore,the current study concluded that the required compressive strength can be achieved by varying any factor in the mix design.In addition,the factor analysis revealed that the NS/NH ratio significantly affects the compressive strength of geopolymer concrete.

高温蒸汽养护复掺混凝土力学性能时变特性与模型研究

为研究高温蒸汽养护下粉煤灰-矿粉机制砂混凝土(简称复掺混凝土)力学性能时变特性与模型,本文结合某高速公路高温蒸汽养护复掺混凝土预制梁项目,设计了蒸汽-标准养护、蒸汽-自然养护和标准养护三种养护方式,测试了不同阶段复掺混凝土的抗压强度、劈裂抗拉强度和弹性模量,探究了抗压强度与劈裂抗拉强度、弹性模量的关系。结果表明:合适的蒸汽养护方式能促进复掺混凝土抗压强度、劈裂抗拉强度和弹性模量更快增长,其中对抗压强度形成作用最显著,后期的力学性能不倒缩;蒸汽养护恒温阶段复掺混凝土的力学性能具有最大的增长率,其次是升温阶段,降温阶段力学性能增长率最小;蒸汽-标准养护方式下复掺混凝土的抗压强度时变模型可取对数或对数与幂函数复合函数,劈裂抗拉强度、弹性模量时变模型可取幂函数。

基于响应面法的机制砂路面混凝土配合比优化及其性能研究

为实现多目标性能机制砂混凝土配合比设计,本文采用Box-Behnken响应面法进行试验设计,探究了石粉掺量、浆体体积分数及水胶比对机制砂路面混凝土性能(坍落度、28 d抗压强度和磨损量)的影响,并结合SEM和XRD对硬化浆体的微观结构进行了分析。结果表明,通过响应面法建立的回归模型能够精确预测各因素与性能之间的关系,精度达95%以上。在各因素中,水胶比对坍落度和抗压强度的影响最显著,而对磨损量的影响较小。经优化,得到最佳的机制砂路面混凝土配合比:水胶比0.36,浆体体积分数25%,石粉掺量10%(质量分数)。此外,掺量不超过10%的石粉改善了界面过渡区,有助于提升混凝土的力学性能。

再生混凝土的配合比设计研究综述

混凝土是基础设施建设中使用最广泛的材料,从废弃混凝土中回收再生骨料制作混凝土,可以减少自然资源的消耗以及处理废弃混凝土带来的环境污染问题。本文阐述了再生混凝土配合比传统与人工智能设计方法的研究现状,对研究中使用的具有代表性的方法进行了整理归纳;针对两种方法的特点以及存在的问题进行总结,提出人工智能设计方法具有广阔的发展潜力与研究前景;同时,对基于人工智能的再生混凝土配合比设计方法进行了展望,可为进一步完善和发展再生混凝土配合比设计方法提供参考。

膨胀土流态固化改性试验与配合比研究

流态固化改性是弃方资源化新方式,有助于解决道路工程中异形或狭隘空间难以回填压实问题.选取南宁地区中等膨胀土弃方,与水、水泥及标准砂混合配制流态固化土试样并开展室内土工试验,分析掺配比对试样膨胀性、强度、流动度及泌水率的影响规律.结果表明:试样膨胀性由掺灰比和掺砂比决定,受水固比影响小,当掺灰比大于18%且掺砂比超过6%时,试样呈现非膨胀特征.无侧限抗压强度主要来自水泥水化作用,随掺砂比的增加呈先增大后降低的变化,掺砂比上限宜控制在10%;水固比增加导致强度大幅下降,水固比大于80%后干湿循环条件下的强度衰减趋势显著.初始流动度与水固比、掺砂比及掺灰比正相关,受掺灰比影响最小;试样拌合完成后的90 min是流动度损失的主要阶段,流动度损失率为23%~32%,随后变化放缓.泌水率取决于水固比,受掺灰比影响较小.基于试验规律,经归一化分析得到膨胀土流态固化改性配合比设计流程.

CFB灰渣混凝土的组成设计与应用研究

随着循环流化床(CFB)锅炉清洁燃烧技术的大规模应用,所排放的CFB灰渣的处理成为亟待解决的问题。本文以碎石作粗集料、CFB炉渣作细集料以及CFB飞灰作矿物掺合料来制备CFB灰渣混凝土,探讨了CFB炉渣砂率、CFB飞灰掺量对CFB灰渣混凝土的工作性能与力学性能的影响,优化设计了CFB灰渣混凝土配合比,对比研究了CFB灰渣混凝土与机制砂混凝土抗Cl-渗透性能、抗冻性和干燥收缩等耐久性能,并进行了CFB灰渣混凝土小型预制构件的工程应用。结果表明:随着CFB炉渣砂率的增加,CFB灰渣混凝土的抗压强度先增大后降低,随着CFB飞灰掺量的增加,CFB灰渣混凝土的坍落度逐渐降低,抗压强度先增大后降低,优化的最佳配合比为水泥280 kg/m^(3)、CFB飞灰120 kg/m^(3)、矿粉40 kg/m^(3)、CFB炉渣620 kg/m^(3)、碎石1 013 kg/m^(3)、水223 kg/m^(3)、减水剂8.8 kg/m^(3);相比于机制砂混凝土,CFB灰渣混凝土具有良好的抗Cl-渗透性能、抗冻性和较小的干燥收缩,且采用CFB灰渣混凝土制备的小型预制构件在实际工程中具有更好的应用效果。

高强高保坍钢管拱机制砂自密实混凝土配制技术

根据重庆某钢管拱桥结构特征与“泵送顶升压注法”施工工艺特点,提出了高强高保坍钢管拱机制砂自密实混凝土性能需求。针对高强与超高工作性的矛盾问题,通过配合比参数优化、骨料优化、矿物掺合料复掺优化、外加剂复配优化和配合比综合优化等技术,配制出初始坍落度≥260 mm、扩展度≥600 mm、倒坍落度筒流出时间≤8 s、4 h工作性基本无损失、强度等级达C60以上的钢管拱机制砂自密实混凝土,形成了高强高保坍钢管拱机制砂自密实混凝土的配制技术,为工程实际施工提供了良好的技术支撑。

LNG储罐低温混凝土配合比及抗压强度试验研究

通过收集整理液化天然气(LNG)储罐混凝土实际配合比信息,并按规范要求进行了不同低温环境下的抗压强度测试,考察LNG储罐混凝土在低温环境下抗压强度的变化规律。结果表明:各储罐项目配合比用料基本一致,粉煤灰与矿粉用量略有差异,粉煤灰选用F类I级时,其混凝土抗压强度在常温及低温下都处于较高水平;矿粉选用S105级时,其混凝土抗压强度在低温下提升幅度最大。LNG储罐混凝土低温抗压强度随温度的降低明显增强,且温度越低,混凝土破坏越突然。在3个低温(-40℃、-120℃和-190℃)环境下,实测混凝土抗压强度分别是常温环境抗压强度的1.41、1.84和1.97倍,均满足规范要求。含水率是混凝土抗压强度低温增强的重要指标,但规范要求的低温环境混凝土抗压强度含水率影响系数与实际抗压强度的提升效果之间,规律并不明显。试验结果可为LNG储罐低温混凝土的配合比设计及安全性评估提供参考。

高性能混凝土的早期抗压强度预测和极值寻优

高性能混凝土7 d抗压强度作为早期强度的重要指标,对建筑工程质量的影响不容忽视。为了实现高性能混凝土的抗压强度预测及极值寻优,本文基于Logistic混沌映射改进麻雀搜索算法(LCSSA)优化BP神经网络,建立LCSSA-BP预测模型。选取88组数据作为训练集、38组数据作为测试集,对比BP、支持向量机(SVM)、极限学习机(ELM)、人工蜂群算法优化BP神经网络(ABC-BP)、布谷鸟搜索算法优化BP神经网络(CS-BP)模型的预测结果。从数据集划分、输入变量数量的角度出发,验证了LCSSA-BP模型的预测精度。采用遗传算法进行抗压强度寻优,确定高性能混凝土配合比的最佳掺量。研究表明:相较于其他模型,LCSSA-BP模型具有更高的预测精度、更低的预测误差;当按照9-1划分训练集和测试集时,模型决定系数R^(2)为0.975,相关系数R为0.987;综合考虑变量的关联度和数据分布特性,选取水泥、高炉矿渣、水、粗骨料和细骨料作为输入变量时,模型R^(2)为0.954,R为0.977;遗传算法在高性能混凝土早期7 d抗压强度寻优和配合比设计方面具有较高的可行性和实用性。

复合石灰石粉-尾矿混合砂混凝土基本力学性能研究

为探究复合石灰石粉-尾矿混合砂混凝土中不同掺合料对其基本力学性能的影响,对配合比优化后的复合石灰石粉-尾矿混合砂混凝土为基准,以抗压强度、劈裂抗拉强度、抗折强度作为表征参数,分析复合石灰石粉-尾矿混合砂混凝土中尾矿混合砂、辅助胶凝材料(石灰石粉、矿渣及粉煤灰)、辅助胶凝材料中石灰石粉掺量以及尾矿混合砂中石灰石粉的含量对其基本力学性能的影响,并建立复合石灰石粉-尾矿混合砂混凝土强度随龄期级石灰石粉掺量发展的二参数预测模型。研究结果表明:尾矿混合砂能对复合石灰石粉-尾矿混合砂混凝土各龄期的抗压强度、劈裂抗拉强度以及抗折强度都有一定的提升作用,幅度分别约为10%、8%、11%。辅助胶凝材料的加入使得混凝土早期的抗压强度、劈裂抗拉强度以及抗折强度有明显的下降,后期会逐渐提升。随着辅助胶凝材料中石灰石粉的增加,混凝土抗压强度、劈裂抗拉强度以及抗折强度先增加后下降,而增加机制砂中的石灰石粉的含量能提高混凝土的抗压强度、劈裂抗拉强度以及抗折强度。建立复合石灰石粉—尾矿混合砂混凝土的强度预测模型,将拟合值与试验值对比发现预测模型精度较高。

振动搅拌对复合胶凝材料混凝土性能的影响

为研究振动搅拌对C50复合胶凝材料预制梁混凝土性能的影响,采用正交试验优化得到了混凝土最佳配合比,在最佳配合比下,对不同振动搅拌时间下混凝土的工作性、抗压强度和弹性模量进行了测试,并结合XRD、SEM分析了振动搅拌对混凝土力学性能的影响机理。结果表明:通过正交试验得到混凝土的最佳配合比为m_(水泥)∶m_(矿粉)∶m_(粉煤灰)∶m_(硅灰)∶m_(砂)∶m5~10 mm_(碎石)∶m10~20 mm_(碎石)∶m水∶m_(减水剂)=369∶27∶40.5∶13.5∶775∶214∶857∶144∶5.4;振动搅拌会使混凝土的流动性有所下降,当振动搅拌时间为90 s时,混凝土的出机坍落度和扩展度下降幅度最小;随着振动搅拌时间的增加,混凝土的抗压强度和弹性模量均呈先增加后降低的趋势,当振动搅拌时间为90 s时,混凝土的抗压强度和弹性模量达到最大;振动搅拌加快了水泥的水化速率,促进了C-S-H凝胶、Ca(OH)2晶体等水化产物的生成,水化产物能更充分地填充于混凝土界面过渡区的孔隙和裂缝处,增加了界面过渡区结构的致密性,从而提高了混凝土的强度。