INFLUENCE OF THE RECIPES ON THE STRENGTH OF STRENGTH OF GEOPOLYMER COMPOUNDS WHEN CEMENTING LRW

Y. Fedorenko, A. Rozko, Yu. A. Olkhovyk
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Abstract

The influence of the composition of geopolymer binders (blast furnace slag, removal ash, liquid glass and KOH) on the properties, namely the compressive strength of the compounds formed during LRW cementation, is studied. To perform the work, compounds were made in which the masses of the components varied according to the plan of the factorial experiment in 23 – three factors on two levels. The factors chosen were: liquid glass, a mixture of slag with ash in a ratio of 1: 1 and potassium hydroxide. The mass of LRW imitation did not change in all experiments. The experiments were not duplicated, and the random error was assessed analytically. The calculations gave the equation that relates the compressive strength of the compounds to the mass of liquid glass, slag and ash, and potassium hydroxide. When constructing the equation, it was found that the variance of the batch of measurements by the Cochren’s criterion is homogeneous, the coefficients of the equation by the Student’s criterion are statistically significant, and the model (equation) by the Fisher criterion is adequate. The analysis of the equation showed that the strength limit is influenced by slag and ash, but the greatest influence is exerted by the pair interaction of liquid glass with ash and slag. The consequence of the interaction is the formation of a geopolymer network, which strengthens the compounds. The addition of potassium hydroxide reduces the strength of the samples due to excess potassium and sodium cations, for which there is no functional place (combination with Al atoms to change the electronic configuration to tetrahedral). For this case, an equation with a correlation coefficient R = 0.86 is obtained. The application of the method of steep ascent showed the possibility of increasing the strength limit by 1.5 times or more. In the future, it is planned to reduce the amount of ash in the binder or replace it with temperature-activated kaolin. Mechanical activation of the slag powder had a positive effect on increasing the compressive strength.
胶凝LRW时配方对地聚合物强度的影响
研究了地聚合物粘结剂的组成(高炉渣、除灰、液态玻璃和KOH)对LRW胶结过程中形成的化合物的性能即抗压强度的影响。为了完成这项工作,根据23的析因实验计划,在两个水平上的三个因素,制备了成分质量变化的化合物。选择的因素是:液体玻璃,炉渣与灰的1:1比例的混合物和氢氧化钾。在所有实验中,LRW的模仿量没有变化。实验没有重复,随机误差进行了分析评估。通过计算得出了化合物的抗压强度与液态玻璃、炉渣和灰烬以及氢氧化钾的质量之间的关系。在构建方程时,发现采用Cochren标准的一批测量值的方差是齐次的,采用Student标准的方程的系数具有统计显著性,采用Fisher标准的模型(方程)是充分的。对方程的分析表明,玻璃的强度极限受渣和灰的影响,但影响最大的是玻璃液与灰和渣的耦合作用。这种相互作用的结果是形成了一个地聚合物网络,从而加强了化合物。氢氧化钾的加入降低了样品的强度,因为过量的钾和钠阳离子没有功能位置(与Al原子结合使电子构型改变为四面体)。在这种情况下,得到相关系数R = 0.86的方程。陡升法的应用表明,可以将强度极限提高1.5倍以上。未来,计划减少粘结剂中的灰分量或用温度活化高岭土代替。矿渣粉的机械活化对提高其抗压强度有积极作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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