Enhanced strength in novel nanocomposites prepared by reinforcing graphene in red soil and fly ash bricks

Low-dimensional nanomaterials such as graphene can be used as a reinforcing agent in building materials to enhance the strength and durability. Common building materials burnt red soil bricks and fly ash bricks were reinforced with various amounts of graphene, and the effect of graphene on the strength of these newly developed nanocomposites was studied. The fly ash brick nanocomposite samples were cured as per their standard curing time, and the burnt red soil brick nanocomposite samples were merely dried in the sun instead of being subjected to the traditional heat treatment for days to achieve sufficient strength. The water absorption ability of the fly ash bricks was also discussed. The compressive strength of all of the graphene-reinforced nanocomposite samples was tested, along with that of some standard (without graphene) composite samples with the same dimensions, to evaluate the effects of the addition of various amounts of graphene on the compressive strength of the bricks.

Investigation of the medium calcium based non-burnt brick made by red mud and fly ash: durability and hydration characteristics

Red mud is a type of highly alkaline waste residue produced in the process of alumina smelting by the Bayer process.Based on the idea of medium calcium content,solid wastes such as red mud and fly ash were used to prepare non-burnt bricks;and the mass ratio of CaO/SiO2 was selected in the range of 0.88–1.42.Mechanical properties and durability were investigated with a compressive strength test.X-ray diffractometry(XRD),scanning electron microscope(SEM),and Fourier transform infrared spectroscopy(FTIR)techniques were used to characterize the hydration characteristic.The environmental performance was analyzed by Inductively Coupled Plasma Mass Spectrometry(ICP).The results indicated that the mechanical properties and the durability were optimal when the mass ratio of CaO/SiO2 was 1.23.The hydration products were mostly C–S–H gel,ettringite,Na4Ca(Si10All6)O32·12H2O and Ca3Al2(SiO4)(OH)8.They were responsible for the strength development,and the CaO/SiO2 mass ratio of 1.23 had the best polymerized structure.The results of an environmental performance test showed that the heavy metals in the raw materials were well-solidified in the brick.Therefore,this paper provides an effective solution for use of solid wastes in building material.

Experiment and Numerical Simulation on Axial Compressive Performance of Autoclaved Fly Ash Solid Brick Masonry Columns

To study the influence of slenderness on the axial compressive performance of autoclaved fly ash solid brick masonry columns, compression experiments were conducted on 12 samples of autoclaved fly ash solid brick masonry column and 4 samples of fired clay brick masonry column. The damage patterns and compressive performance were compared and analyzed. The experimental results indicate that the compressive bearing capacity decreases as slenderness increases from 3 to 18, and the compressive bearing capacity of the autoclaved fly ash solid brick masonry columns is lower than that of the fired clay brick masonry columns. The formulae for the axial compressive bearing capacity of autoclaved fly ash solid brick masonry columns were derived based on the experiments. The nonlinear FEA program ANSYS was adopted to simulate the behaviors of masonry columns. By comparing the simulation results and experimental results, it is shown that the simulation results agree well with the experimental ones. The rationality and applicability of the simulation results were verified.

Effects of NaOH Concentrations on Properties of the Thermal Power Plant Ashes-Bricks by Alkaline Activation

The use of the thermal power plant ashes including fly ash(FA) and bottom ash(BA) for producing unfired building bricks(UBB) using sodium hydroxide(NaOH) solution as an alkaline activator was investigated. A low applied forming pressure of 0.5 MPa and various NaOH concentrations of 5, 8, 10, and 12 M were used for the preparation of brick samples with different solution-to-binder(S/B) ratios of 0.35 and 0.40. The bricks were subjected to various test programs with reflecting the effect of both NaOH concentrations and S/B ratios on the brick’s properties. The compressive strength, unit weight, ultrasonic pulse velocity, and thermal conductivity of bricks increased with increasing NaOH concentration, whereas the contrary trend was found with increasing S/B ratio. Also, the water absorption of bricks was observed to reduce with increasing NaOH concentration and decreasing S/B ratio. As the results, the combined utilization of both low forming pressure and coal power plant ashes can produce the UBBs with low unit weight, low heat conductivity, and acceptable strength and water absorption rate as stipulated by TCVN 6477-2016. Furthermore, the outcomes of chemical analysis and microstructure observation also demonstrate that a high concentration of the Na OH promoted the geopolymerization process. Notably, the use of NaOH solution of either 10 M or above is recommended for the production of UBBs, which are classified as grade M5.0 or higher.

电解锰渣-赤泥-粉煤灰路面砖的力学性能及浸出毒性研究

针对大宗工业固废回收利用难的问题,实现多种固废减量化、无害化、资源化的目标,通过利用取自中国西南地区企业的石膏类、碱性及硅铝质三类典型大宗固废中的电解锰渣、赤泥、粉煤灰协同处理的无害化渣制备环保型透水混凝土路面砖(permeable concrete paving bricks,PCB),研究了水洗、掺渣量对所制备PCB的力学性能与浸出毒性的影响,并通过X射线衍射(XRD)和扫描电子显微镜(SEM)对最佳性能PCB的物相组成与微观形貌结构进行分析.结果表明:①随着无害化渣与水洗无害化渣掺入量的提升,路面砖的劈裂抗拉强度、线性破坏荷载发生明显变化,总体呈下降趋势.当无害化渣掺入量为6%、水洗无害化渣掺入量为14%时,经28 d养护,所制备砖体的劈裂抗拉强度分别为4.09和3.46 MPa,达到了《透水路面砖和透水路面板》(GB/T 25993-2010)中规定的f_(ts)4.0与f_(ts)3.0等级.②路面砖的重金属与NH_(4)^(+)-N的浸出毒性均低于《水泥窑协同处置固体废物技术规范》(GB 30760-2014)的要求.路面砖的主要物相中方解石、石英与钙矾石是主要支撑性物质.研究显示,电解锰渣、赤泥、粉煤灰协同处理的无害化渣可替代部分原材料制备透水混凝土路面砖,满足力学性能与浸出毒性相关标准,能有效促进固体废弃物的减量化与资源化,建议进一步开展砖体在实际应用场景中的环境风险试验,以期为电解锰渣、赤泥、粉煤灰的综合利用技术发展提供更明确的支撑.

粉煤灰加入量对钼尾矿制备烧结砖性能的影响

以某钼尾矿为主要原料,外掺一定量的粉煤灰制备钼尾矿烧结砖,探究粉煤灰加入量对钼尾矿烧结砖性能的影响。结果表明:粉煤灰的最佳外掺量为6%,此条件下制备的钼尾矿烧结砖的抗压强度为25.87 MPa,抗折强度为12.85 MPa,体积密度为1.83 g/cm^(3),吸水率为13.65%,烧失重为8.17%,各项指标均达到了建筑用砖的标准。

内掺粉煤灰/再生砖粉的再生砂浆收缩及冻融耐久性

全组分再生砂可有效缓解再生细骨料基再生砂浆常存在的高吸水性及多孔隙的缺陷,研究将粉煤灰(FA)、再生砖粉(RBP)2种固体废弃物作为掺合料对全组分再生砂再生砂浆收缩、冻融耐久性的影响。结果显示,掺FA的再生砂浆28 d收缩率、慢冻25次后质量损失率、强度损失率普遍低于掺RBP的。掺30%FA的再生砂浆28 d收缩率、质量损失、强度损失分别比同掺量RBP的再生砂浆降低7%、45%、5%。微观结构表明,相比于拥有内养护、抵抗收缩效应的RBP,具有中空特征及微珠润滑效应的FA更能有效提高再生砂浆的收缩及抗冻耐久性。

矿物掺合料对再生砖骨料混凝土影响研究

废弃黏土砖经过破碎机,破碎成粒径合乎混凝土骨料要求的碎块,取代天然碎石,配制再生砖骨料混凝土。通过抗压强度试验、劈裂强度试验测试再生砖骨料混凝土力学性能,研究分析粉煤灰、硅灰等矿物掺和料对其影响。试验结果表明:①再生砖粗骨料混凝土的强度小于普通混凝土;②粉煤灰对于再生砖粗骨料混凝土的早期抗压强度有不利的影响,但是可以促进后期强度和劈裂抗拉强度的提高;③掺入硅灰可以显著提高再生砖粗骨料混凝土的抗压、抗拉强度,是解决再生砖粗骨料混凝土强度偏低的有效措施。

回弹法检测蒸压粉煤灰砖抗压强度

基于某既有工程砌体结构中取样的蒸压粉煤灰砖,通过回弹测试及抗压强度试验,研究了在不同竖向压力、试验方法、碳化程度下对回弹值的影响。参考现行相关标准及有关学者提出的测强曲线,将65个标准试件试验得到的抗压强度值和回弹值进行数据回归拟合处理,提出适合该工程的回弹法推定蒸压粉煤灰砖抗压强度一般公式,并进行了相应的工程验证。结果表明,回弹值在30~37的蒸压粉煤灰砖由该公式推定其抗压强度准确度较高,可为类似检测工程提供参考,对完善我国砌块强度检测标准具有参考价值。

掺垃圾焚烧飞灰制烧结砖物相及相变研究

研究了生活垃圾焚烧飞灰的微观形貌、差热分析、矿物及化学组成,利用飞灰、陶泥、石英砂及长石研制烧结砖,并分析了最佳配比烧结砖的物相、相变及浸出毒性。实验结果显示:飞灰属二氧化硅–三氧化二铝–金属氧化物体系,主要化学成分是二氧化硅与三氧化二铝等,可用作烧结砖的原材料;飞灰中含有类玻璃微珠,玻璃相含量超过50%;温度高于1240℃时飞灰显示出较强的活性;烧结砖主晶相是石英、莫来石、堇青石、硅灰石、顽火辉石与钙铁榴石;这些晶相在温度升高的过程中逐步形成,其含量随着温度的升高先增加后减少;玻璃相含量随温度的升高不断增加;最佳配比烧结砖重金属浸出毒性均达标,重金属的浸出率远低于坯体。

垃圾焚烧飞灰制备透水砖及其影响因素研究

为响应我国建设无废城市号召建设海绵城市,以垃圾焚烧飞灰替代部分胶凝材料与矿渣、偏高岭土、脱硫石膏与钢渣、碎石为骨料采用冷固法制备了环保透水砖,分析了粗细骨料体积比、颗粒级配、水胶比、飞灰参量等因素对透水砖性能的影响。结果表明:最佳的工艺参数为粗细骨料体积比为1.4、颗粒级配为DP3(钢渣细骨料2.36~4.75 mm、粗骨料粒径4.75~9.5 mm)、水胶比为0.26、飞灰参量为20%在4 MPa压力下成型其透水系数3.93 cm^(2)/s、抗压强度32.53 MPa、抗折强度可达4.01 MPa,满足相关标准要求,将飞灰替代部分水泥制备透水砖,不仅可以减少资源浪费,还能降低环境污染。

蒸压电石渣粉煤灰砖的制备和性能

对硅质原料粉煤灰和钙质原材料电石渣进行了化学分析和矿物分析，通过研究原材料对制品的强度、密度、收缩以及抗碳化等性能的影响，提出生产不同强度等级蒸压粉煤灰砖配料方案；研究表明有效CaO含量超过65％的电石渣可等量取代生石灰生产蒸压粉煤灰砖，掺量在8％时可生产MU10～MU15蒸压粉煤灰砖并应用XRD和SEM扫描，分别观察晶体组成及形貌特征，表明含有对强度和耐久性具有改善作用的钙矾石、水石榴石和水化硫铝酸钙。

粉煤灰基质-草坪砖栽培环境对坪草生长的影响

为了解决停车场、甬路、渠坝与草坪争地的矛盾 ,增加城市绿地面积 ,在已研究粉煤灰草坪基质最佳混合比例的基础上 ,进一步探讨草坪砖作为草坪栽培环境 (砖孔内填入粉煤灰混合基质 ,简称砖孔环境 )的肥力效应与生物效应。为了对比分析 ,特此设置了土孔环境 (在土壤中挖取与草坪砖形状和容积相同的孔并填入粉煤灰混合基质 )与土灰环境 (在粉煤灰混合基质中按照草坪砖孔模式划出同样大小的圈 )种植黑麦草作为对照。研究结果表明 :坪草 N、K、Na、Cu、Zn等含量以砖孔环境最高 ,土灰环境和土孔环境较低 ,差异显著 ,说明砖孔环境能为植物生长提供较多的养分元素 ;砖孔环境中的坪草含有的 Fe、Cu、Zn浓度远高于坪草最佳需求量 ,今后不再需要补充铁肥、铜肥和锌肥。试验还表明砖孔环境的蒸散率最小 ,基质含水量最大 ,基质势最高 ,持续供水能力强 ,抗旱效果十分明显。砖孔环境与土孔环境中的草坪草屑累积量差异不显著 ,但均比土灰环境中的高 ,且差异显著。

煤矸石-粉煤灰烧结砖的研制

利用煤矸石和粉煤灰烧结砖不但可减少固体废弃物的排放,还可创造可观的经济效益。利用阜新本地煤矸石和粉煤灰,经原料制备、原材料的处理、砖坯成型和烧结等工艺,可生产出满足国家质量标准的烧结砖。经制备工艺正交试验,制品抗压强度主要受材料配比和烧结温度的影响,其次是升温速率和保温时间。由于助熔剂的加入,煤矸石-粉煤灰砖的焙烧温度可以由1200℃降低到1100～1150℃。由试验分析的结果,合理的材料配比为:灰矸比3∶7,外加2%玻璃粉;合理的砖坯成型水分为12%,砖坯成型压力为30 MPa;合理的烧成制度为:升温速率80min/h,烧成温度1150℃,保温时间100 min。研制的烧结砖呈粉红色至砖红色,与普通粘土砖基本相同,外观规整,无裂纹其它大的缺陷且无石灰爆裂现象。产品从制坯到烧成的过程中各方向的变形均满足质量要求。本文研究为普通黏土烧结砖厂技改成煤矸石-粉煤灰砖厂提供了有力的技术保障。

利用湖泊底泥和粉煤灰制备瓷质砖的实验研究

将湖泊底泥引入瓷质砖的生产 ,既可消除污染 ,又能减少传统的瓷质砖生产中所需的粘土 .以武汉市东湖底泥和湖北黄石电厂粉煤灰为主要原料 ,辅以伟晶花岗岩、石英为添加剂 ,设计 4个底泥含量分别为 4 0 %、5 0 %、6 0 %和 70 %的配方 ,每一配方压制 6片生坯 ,分别在 1 1 90 ,1 1 75 ,1 1 6 0 ,1 1 30 ,1 1 1 5和 1 1 0 0℃下烧成 .XRD分析显示瓷坯中的莫来石晶相随烧成温度的升高而增加 .在 1 1 6 0～ 1 1 75℃烧成的瓷坯的吸水率和断裂模数测试结果分别为 0 .0 8%～ 0 .2 0 %和 39.36～ 5 1 .0 8MPa ,表明利用湖泊底泥和粉煤灰作为主要原料可以烧制瓷质砖 ,二者的总用量可达 75 %～ 80 % .

蒸压粉煤灰砖砌体抗剪性能试验

目的研究蒸压粉煤灰砖砌体沿通缝截面的抗剪性能,为编制《蒸压粉煤灰砖建筑技术规范》和完善我国《砌体结构设计规范》(GB50003-2001)提供试验依据.方法利用9块砖组砌成双剪试件,对24个蒸压粉煤灰砖砌体试件及24个烧结黏土砖砌体试件进行通缝抗剪试验,对比分析两种砖的破坏形态及抗剪强度.结果蒸压粉煤灰砖砌体抗剪强度较烧结黏土砖砌体抗剪强度提高了12%.将试验结果进行回归分析,给出蒸压粉煤灰砖砌体抗剪强度平均值的计算公式为fv,m=0.04f2.结论建议新型蒸压粉煤灰砖砌体抗剪强度的标准值及设计值仍按规范取值.蒸压粉煤灰砖砌体具有良好的抗剪性能,可以在实际工程上替代烧结黏土砖使用.

蒸压粉煤灰砖墙片抗震性能试验

目的研究蒸压粉煤灰实心砖墙体抗震性能、破坏形态和设计方法,为编制蒸压粉煤灰砖技术规程提供依据.方法通过对3片蒸压粉煤灰砖墙片在低周往复水平荷载作用下试验,分析墙片的破坏特征.结果得到墙片的滞回曲线、骨架曲线、延性系数;蒸压粉煤灰实心砖素墙片在伪静力作用下为脆性破坏,抗剪承载力较高,抗震性能较差,延性较差;蒸压粉煤灰砖墙片延性比为3.64～4.31;试件承载力实测值是验算值的1.76～3.08倍.结论蒸压粉煤灰砖墙体抗震能力是偏于安全的,笔者所提建议可供编制蒸压粉煤灰砖建筑技术规程参考.

免蒸压免烧结粉煤灰多孔砖砌体力学性能试验研究

免蒸压免烧结粉煤灰多孔砖是一种新型承重墙体材料,为使其在地震区村镇建筑中得到推广应用,进行了多孔砖砌体抗压强度和抗剪强度试验,分析了砌体裂缝开展及破坏过程。试验结果表明:免蒸压免烧结粉煤灰多孔砖砌体的受压、受剪破坏过程及特征与普通黏土砖砌体类似,但具有更大的脆性;抗压、抗剪强度均小于普通黏土砖砌体;采用6次多项式的受压本构关系数学模型,反映了免蒸压免烧结粉煤灰多孔砖砌体受压应力-应变全过程,计算值与实测数据比较接近。

免蒸免烧粉煤灰多孔砖墙体抗震性能试验研究

免蒸压免烧结粉煤灰多孔砖是一种新型承重墙体材料。本文通过三片墙体低周反复荷载试验,系统研究了粉煤灰多孔砖墙体的力学性能和抗震性能,包括墙体的破坏特征、滞回曲线、刚度、延性、骨架曲线及受剪承载力等。试验结果表明,免蒸压免烧结粉煤灰多孔砖墙体的破坏形态与普通黏土砖墙体相似,主要呈剪切破坏;墙体具有较高的受剪承载力、延性和耗能能力,适宜在地震区村镇建筑中推广应用。

水泥含量与防氡涂料对粉煤灰砖氡释放的影响

以氡屏蔽率为主要评判指标,研究水泥加入量对煤渣/粉煤灰砖氡释放的影响;使用自制的防氡涂料研究涂层厚度对煤渣/粉煤灰砖氡释放的影响。结果表明:随着水泥加入量的增加,不同水泥量模块的氡析出浓度先明显增加,水泥加入量35%时,模块析出氡浓度达到最大值,然后呈缓慢下降趋势;随涂覆厚度的增加,防氡效率上升,当涂覆厚度为2.0 mm时,防氡效率为98.96%。机理研究表明:水泥量增加,产生的水化反应产物增多,将填充至水泥石内部的孔隙空洞,增加密实度,降低氡的释放,但水泥中粉煤灰等原料会带来氡的释放;涂层表面是一种连续致密均匀的结构,孔隙率极低,防氡基元材料紧密堆积,形成了层层叠加的致密结构,对氡源起到很好的密闭作用。