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Calcium lignosulphonate (CL)-sodium bicarbonate (SB) (a total of 0.7% by weight of cement and CL to SB ratio of 1:1.8) will cause the fluidity of fly ash cement paste to decrease rapidly. It is the variation of the status of ettringite crystallization that causes this phenomenon. Experimental results show that CL-SB affects the liquid-phase composition of fly ash cement paste remarkably. As a result, ettringite crystallizes out in the shape of needles from the solution. These needle-like crystal particles are distributed in the solution at a certain distance from the surface of clinker particles. At the initial hydration stage, the crystallization of ettringite is stronger in fly ash cement with calcined gypsum than in fly ash cement with gypsum. 相似文献
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通过实验室球磨机制备出比表面积分别为280m2/kg、370m2/kg和670m2/kg的3种水泥熟料,与不同掺量的粉煤灰配制成不同颗粒级配的粉煤灰水泥,并测试了粉煤灰水泥浆体的抗压强度、自收缩、孔隙率和显微结构。结果表明:提高熟料细度能在很大程度上降低粉煤灰水泥浆体的孔隙率并提高复合水泥浆体早期抗压强度;粉煤灰的掺入降低了水泥体系的自收缩,提高了粉煤灰水泥浆体的体积稳定性;粉煤灰水泥浆体背散射图像表明,提高熟料细度可显著减少粉煤灰水泥浆体中未水化的水泥颗粒含量,并在一定程度上减少未水化粉煤灰颗粒含量。 相似文献
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采用石灰、水泥、粉煤灰对磷石膏进行改性处理,测定了改性磷石膏中硫酸根的溶解性能,对比了原状磷石膏与改性磷石膏对水泥物理性能的影响,并结合X射线衍射(XRD)和扫描电镜(SEM)分析了改性前后磷石膏对水泥不同龄期水化产物的影响。结果表明:随着石灰掺量的增加改性磷石膏的pH逐渐增大,当石灰掺量为4%(质量分数)时磷石膏的pH达到12.22,此时磷石膏中的可溶性磷、氟转化成难溶性的磷酸盐、氟化钙;随着水泥和粉煤灰掺量的增加,改性磷石膏的溶解性能呈现降低趋势。当石灰掺量为4%、水泥掺量为10%(质量分数)、粉煤灰掺量为10%(质量分数)时,改性磷石膏经过7 d养护在水中浸泡8 h所得滤液中硫酸根的质量浓度为0.30 g/L,比未改性磷石膏在水中浸泡8 h所得滤液中硫酸根的质量浓度降低了81.8%。与掺加未改性磷石膏的水泥浆体相比,掺加改性磷石膏的水泥浆体的水灰质量比由0.41降低到0.38、初凝时间和终凝时间分别缩短34.6%和27.2%、28 d抗压强度提高21.1%。石灰、水泥、粉煤灰改性处理磷石膏后,生成的水化硅酸钙和钙矾石等水硬性产物包裹在石膏颗粒表面,使硫酸根在水中的溶出速率降低,减少了对水泥中铝酸三钙的影响,使得硬化体内部结构变得致密、力学性能显著提高。 相似文献
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Blended cements prepared with two fly ashes were used as matrices in glass fiber reinforced cement (GRC) composites in an attempt to improve their durability. The hydrated matrices from the two blended cements investigated here had similar strength and composition. Both fly ashes reduced the Ca(OH)2 content to the same extent but in both cases the pH level was only slightly reduced compared to the portland cement matrix. In spite of these similarities, the GRC prepared with one fly ash showed considerable improvement in durability while the other one had only a small positive effect. SEM observations indicated that the improved durability in one case was associated with modification in the microstructure of the hydration products deposited in between the glass filaments, resulting in a much more open structure compared to that of portland cement matrix or the other blended cement. It is therefore suggested that the potential of the blended cement matrix to improve the durability of GRC is associated with its ability to modify the microstructure of the paste at the glass interface. This characteristic is not necessarily related to the overall composition of the blended cement matrix and to the reactivity of fly ash with Ca(OH)2. 相似文献
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粉煤灰与水泥浆体间界面的形貌特征 总被引:27,自引:4,他引:27
用SEM和EDS研究了粉煤灰掺入水泥后与水泥浆体间所形成界面的形貌特征,结果表明,在水泥水化初期,粉煤灰表面呈三种状态:(1)被CSH单层膜包裹;(2)被CH-CSH双层膜包裹;(3)嵌入块状CH晶体内,在水泥水化后期,粉煤灰颗粒表面层已完全与水泥水化产物发生反应,且形成若干层反应物,呈致密的粒状或环状凝胶体。 相似文献
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垃圾焚烧飞灰胶凝活性和水泥对其固化效果的研究 总被引:21,自引:0,他引:21
垃圾焚烧飞灰是生活垃圾焚烧后烟气除尘器收下的物质,其主要成分属CaO-SiO_2-Al_2O_3-Fe_2O体系,与目前常用的高炉矿渣、粉煤灰等辅助性胶凝材料非常接近,因其中含有能被水浸出的重金属物质而被认为是危险废物,必须对之进行稳定及固化处理。通过试验研究了掺入垃圾焚烧飞灰的硬化水泥浆体的力学性能和水化机理,考察了水泥固化垃圾焚烧飞灰的效果,探讨了垃圾焚烧飞灰作为辅助性胶凝材料利用的可行性。研究表明:垃圾焚烧飞灰的水化反应活性较低,它的掺入在一定程度上延缓了水泥的水化过程,虽然其水化过程可以形成适量的钙矾石,对强度发展有利,但掺量较大时会显著降低水泥强度;采用水泥稳定及固化垃圾焚烧飞灰的效果良好,垃圾焚烧飞灰中重金属可以通过包容、替代或吸收等形式固化进水化产物结构中。 相似文献
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Khandaker M.Anwar Hossain 《Cement and Concrete Research》2003,33(10):1601-1605
This paper reports the results of investigation to assess the suitability of volcanic ash (VA) and pumice powder (VPP) for blended cement production. Tests were conducted on cement where Portland cement (PC) was replaced by VA and VPP within the range of 0 to 50%. The physical and chemical properties of VA and VPP were critically reviewed to evaluate the possible influences on cement properties. The investigation included testing on both fresh and hardened states of cement paste. The standard tests conducted on different PC-VA and -VPP mixtures provided encouraging results, comparable to those for fly ash (FA) cement, and showed good potential of manufacturing blended Portland volcanic ash cement (PVAC) and Portland volcanic pumice cement (PVPC) with higher setting time and low heat of hydration using up to 20% replacement. 相似文献
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Effect of fly ash on the kinetics of Portland cement hydration at different curing temperatures 总被引:1,自引:0,他引:1
This paper describes the effect of fly ash on the hydration kinetics of cement in low water to binder (w/b) fly ash-cement at different curing temperatures. The modified shrinking-core model was used to quantify the kinetic coefficients of the various hydration processes. The results show that the effect of fly ash on the hydration kinetics of cement depends on fly ash replacement ratios and curing temperatures. It was found that, at 20 °C and 35 °C, the fly ash retards the hydration of cement in the early period and accelerates the hydration of cement in the later period. Higher the fly ash replacement ratios lead to stronger effects. However, at 50 °C, the fly ash retards the hydration of the cement at later ages when it is used at high replacement ratios. This is because the pozzolanic reaction of the large volumes of fly ash is strongly accelerated from early in the aging, impeding the hydration of the cement. 相似文献
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Hydration of fly ash cement 总被引:1,自引:0,他引:1
It is necessary to establish the material design system for the utilization of large amounts of fly ash as blended cement instead of disposing of it as a waste. Cement blended with fly ash is also required as a countermeasure to reduce the amount of CO2 generation. In this study, the influences of the glass content and the basicity of glass phase on the hydration of fly ash cement were clarified and hydration over a long curing time was characterized. Two kinds of fly ash with different glass content, one with 38.2% and another with 76.6%, were used. The hydration ratio of fly ash was increased by increasing the glass content in fly ash in the specimens cured for 270 days. When the glass content of fly ash is low, the basicity of glass phase tends to decrease. Reactivity of fly ash is controlled by the basicity of the glass phase in fly ash during a period from 28 to 270 days. However, at an age of 360 days, the reaction ratios of fly ash show almost identical values with different glass contents. Fly ash also affected the hydration of cement clinker minerals in fly ash cement. While the hydration of alite was accelerated, that of belite was retarded at a late stage. 相似文献
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分选与磨细粉煤灰对水泥胶砂性能的影响 总被引:1,自引:0,他引:1
研究了分选与磨细粉煤灰的颗粒分布与形貌的差异及对水泥胶砂性能的影响。研究结果表明:当勃氏比表面积相近,磨细粉煤灰的中位粒径大于分选细粉煤灰,其圆珠状颗粒较少,表面较为粗糙。在相同水胶比的条件下,掺分选粗粉煤灰的水泥胶砂流动度及强度均低;分选粗粉煤灰磨细后,不仅减少了颗粒的粘连,增加了比表面积,而且提高了粉煤灰的反应活性和水泥胶砂流动度及强度,虽其水泥胶砂流动度仍小于掺分选细粉煤灰的水泥,3d水泥胶砂强度也略低,但其28d水泥胶砂强度略高于掺分选细粉煤灰的水泥;在相同水泥胶砂流动度的条件下,掺磨细粉煤灰配制的水泥胶砂3d强度低于掺分选细粉煤灰的水泥,但随着水化龄期的增长,其差距逐步缩小,至60d时可超过后者。 相似文献
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Structural features of the transition zone between granular aggregate and portland cement paste were studied. Two types of aggregates were used, quartz and limestone. The transition zones are structurally characterized by a parameter referred to as “interfacial excess conductance” based on electrical conductivity methods. The experimental results indicate that the transition zone between quartz particles and portland cement paste is always less dense than bulk paste, regardless of the aggregate size, and that the thickness of this transition zone decreases with the decreasing of the aggregate size. The same general features occur for the transition zone between larger limestone particles and portland cement paste. A transition zone denser than bulk paste occurs, however, for much smaller limestone particles due possibly to chemical interaction between the limestone particles and portland cement paste. 相似文献
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研究了不同掺量的矿渣和粉煤灰对水泥脆性的影响及规律,同时就混合材改善水泥脆性的机理进行了分析。结果表明,混合材能够改善水泥的脆性,但只有掺量〉15%后效果才比较明显;混合材改善水泥脆性的机理,除了已有共识的二次水化反应消耗浆体中的Ca(OH)2和改善界面过渡带外,还包括以下机理:由于Ca(OH)2浓度的降低,使其不能饱和结晶,而形成薄弱的层状结构;水泥浆体成为相对低钙体系,利于纤维状钙矾石的形成;混合材的使用,降低了水泥的水化速率,减少了因化学收缩、自收缩、温差收缩等原因造成的微裂缝。 相似文献
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研究了海水环境下掺入硅灰、粉煤灰、矿渣对硫铝酸盐水泥抗压强度、化学收缩和水化产物的影响规律.结果表明:当硅灰的掺量为2.5%时,水泥浆体的抗压强度比空白组高.矿渣掺量为10%的水泥浆体28 d抗压强度明显超过掺入硅灰和粉煤灰时的强度,60 d强度高于空白组.掺入2.5%硅灰后,水泥浆体的化学收缩增大;在水化早期,粉煤灰和矿渣的火山灰活性很低,导致水泥浆体的化学收缩降低.掺入10%硅灰加快了硫铝酸盐水泥3 d水化反应,钙矾石生成量增多,水泥浆体早期强度比掺其它掺合料有所提高,但体积过快膨胀会破坏其内部结构,对水泥浆体的强度发展不利. 相似文献