A customary procedure in the protection of monumental buildings is the consolidation of decaying stone by the application of commercial products containing tetraethoxysilane (TEOS). These products polymerize within the porous structure of the decaying stone, significantly increasing the cohesion of the material. However, TEOS-based consolidants suffer practical drawbacks, such as cracking of the network during the drying phase, and significant blocking of the rock pores. These limitations are related to the growth of a dense microporous network of the xerogel inside the stone material, which is typical from TEOS sols. Therefore, the purpose of this work is to increase porosity of the product by including colloidal particles in the starting sol. We prepared a colloid-polymer composite gel using TEOS and a commercial silica colloid. The percentage by weight of silica colloid particles to total silica was 54%. Ethanol and dibutyltindilaurate (DBLT) were chosen as solvent and catalyst, respectively. This catalyst promotes the gelation at a neutral pH, preventing stone decay related to acid or basic catalysis. We characterized the properties playing a key role in consolidation. Data were compared with those obtained using a popular commercial product: Tegovakon V 100 produced by Goldsmith. In spite of the colloidal particle addition, sols exhibited viscosity values close to those of the commercial products, as a consequence of their dispersion in ethanol. A gelation time similar to that of commercial consolidants was maintained, whereas the contained sol was stable over a period of up to six months. Concerning textural parameters, the addition of colloid permitted to obtain a crack-free, mesoporous material structure. This generated a crack-free material whereas the gel from Tegovakon V 100 exhibited cracking. We also evaluated the consolidant efficacy on a biocalcareous stone, one of the most common monumental building stone employed in the southwest of Spain. Three key parameters -penetration depth in the rock, mechanical properties and water vapour diffusivity- were measured. Stone permeation was similar to that from the commercial product. Notably, a significant improvement of compression strength of the stone was observed. Reduction in vapour diffusivity of the treated stone was slightly lower for our gel than for the commercial consolidant.
展开▼
机译:保护纪念性建筑物的一种常规程序是通过使用含有四乙氧基硅烷(TEOS)的商业产品来加固腐烂的石头。这些产品在腐烂的石头的多孔结构内聚合,从而大大提高了材料的内聚力。然而,基于TEOS的固结剂具有实际的缺点,例如在干燥阶段网络的破裂,以及岩石孔的显着阻塞。这些局限性与石材内部干凝胶的致密微孔网络的生长有关,这是TEOS溶胶的典型特征。因此,这项工作的目的是通过在起始溶胶中包含胶体颗粒来增加产品的孔隙率。我们使用TEOS和商业二氧化硅胶体制备了胶体-聚合物复合凝胶。二氧化硅胶体颗粒相对于全部二氧化硅的重量百分比为54%。分别选择乙醇和二月桂酸二丁基锡(DBLT)作为溶剂和催化剂。该催化剂在中性pH值下促进胶凝作用,防止与酸或碱性催化作用有关的石材腐烂。我们表征了属性在合并中起关键作用。将数据与使用流行的商业产品Goldsmith生产的Tegovakon V 100进行比较。尽管添加了胶体颗粒,但由于溶胶在乙醇中的分散,其溶胶的粘度值仍接近商业产品。维持类似于商业固结剂的胶凝时间,而所包含的溶胶在长达六个月的时间内是稳定的。关于质地参数,允许添加胶体以获得无裂纹的中孔材料结构。这产生了无裂纹的材料,而来自Tegovakon V 100的凝胶显示出裂纹。我们还评估了对生物钙质结石的加固效果,生物钙质结石是西班牙西南部最常用的纪念性建筑石之一。测量了三个关键参数-岩石的渗透深度,力学性能和水蒸气扩散率-。石头渗透与商业产品相似。值得注意的是,观察到了石头的抗压强度的显着改善。对于我们的凝胶,处理过的石材的蒸汽扩散系数降低略低于商业固结剂。
展开▼
