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天然丝光沸石作为火山灰质材料对砂浆凝结过程的影响。

Effects of a Natural Mordenite as Pozzolan Material in the Evolution of Mortar Settings.

作者信息

Costafreda Jorge L, Martín Domingo A, Presa Leticia, Parra José Luis

机构信息

Escuela Técnica Superior de Ingenieros de Minas y Energía, Universidad Politécnica de Madrid, C/Ríos Rosas, 21, 28003 Madrid, Spain.

Laboratorio Oficial para Ensayos de Materiales de Construcción-LOEMCO, Calle Eric Kandel 1, TecnoGetafe, 28906 Getafe, Spain.

出版信息

Materials (Basel). 2021 Sep 16;14(18):5343. doi: 10.3390/ma14185343.

DOI:10.3390/ma14185343
PMID:34576568
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8471035/
Abstract

This paper shows the results of a study focused on the evolution and properties of mortars made with a mixture of portland cement (PC) and natural mordenite (Mor). To begin, samples of mordenite, cement and sand were studied with X-ray diffraction (XRD), X-ray fluorescence (XRF) and granulometric analysis (GA). Next, mortars with a ratio of 75% PC and 25% mordenite were prepared to determine their initial and final setting times, consistency and density. Continuing, the density, weight and compressive strength of the specimens were determined at 2, 7, 28, 90 and 365 days. Finally, the specimens were studied using SEM, XRD and XRF. The results of the study of the mordenite sample showed a complex constitution where the major mineral component is mordenite, and to a lesser degree smectite (montmorillonite), halloysite, illite, mica, quartz, plagioclase and feldspar, in addition to altered volcanic glass. Tests with fresh cement/mordenite mortar (CMM) showed an initial setting time of 320 min and a final setting time of 420 min, much longer than the 212-310 min of portland cement mortar (PCM). It was established that the consistency of the cement/mordenite mortar (CMM) was greater than that of the PCM. The results of the density study showed that the CMM has a lower density than the PCM. On the other hand, the density of cement/mordenite specimens (CMS) was lower than that of portland cement specimens (PCS). The CMS compressive strength studies showed a significant increase from 18.2 MPa, at 2 days, to 72 MPa, at 365 days, with better strength than PCS at 28 and 365 days, respectively. XRD, XRF and SEM studies conducted on CMS showed a good development of primary and secondary tobermorite, the latter formed at the expense of portlandite; also, ettringite developed normally. This work proves that the partial replacement of PC by mordenite does not have a negative effect on the increase in the mechanical strength of CMS. It indicates that the presence of mordenite inhibits the spontaneous hydration of CA and controls the anomalous formation of ettringite (Ett). All this, together with the mechanical strength reported, indicates that mordenite has a deep and positive influence on the evolution of the mortar setting and is an efficient pozzolan, meaning it can be used in the manufacture of mortars and highly resistant pozzolanic cement, with low hydration heat, low density, stability in extremely aggressive places and a low impact on the environment.

摘要

本文展示了一项关于由波特兰水泥(PC)和天然丝光沸石(Mor)混合物制成的砂浆的演变和性能的研究结果。首先,用X射线衍射(XRD)、X射线荧光(XRF)和粒度分析(GA)对丝光沸石、水泥和沙子的样品进行了研究。接下来,制备了比例为75%PC和25%丝光沸石的砂浆,以确定其初凝和终凝时间、稠度和密度。接着,在2天、7天、28天、90天和365天时测定了试件的密度、重量和抗压强度。最后,使用扫描电子显微镜(SEM)、XRD和XRF对试件进行了研究。丝光沸石样品的研究结果显示其组成复杂,其中主要矿物成分是丝光沸石,其次是蒙脱石(蒙脱石)、埃洛石、伊利石、云母、石英、斜长石和长石,此外还有蚀变火山玻璃。对新鲜水泥/丝光沸石砂浆(CMM)的测试表明,其初凝时间为320分钟,终凝时间为420分钟,比波特兰水泥砂浆(PCM)的212 - 310分钟长得多。已确定水泥/丝光沸石砂浆(CMM)的稠度大于PCM。密度研究结果表明,CMM的密度低于PCM。另一方面,水泥/丝光沸石试件(CMS)的密度低于波特兰水泥试件(PCS)。CMS抗压强度研究表明,强度从2天时的18.2MPa显著增加到365天时的72MPa,在28天和365天时分别比PCS具有更好的强度。对CMS进行的XRD、XRF和SEM研究表明,原生和次生雪硅钙石发育良好,次生雪硅钙石以氢氧化钙为代价形成;此外,钙矾石正常发育。这项工作证明,用丝光沸石部分替代PC对CMS机械强度的增加没有负面影响。这表明丝光沸石的存在抑制了CA的自发水化,并控制了钙矾石(Ett)的异常形成。所有这些,连同所报告的机械强度,表明丝光沸石对砂浆凝结的演变有深刻而积极的影响,并且是一种有效的火山灰质材料,这意味着它可用于制造砂浆和高抗性火山灰质水泥,具有低水化热、低密度、在极具侵蚀性的地方具有稳定性以及对环境影响小的特点。

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La roca magica: uses of natural zeolites in agriculture and industry.
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