NL2028277B1 - Masonry mortar composition - Google Patents

Abstract

This invention relates to a masonry mortar composition for masonry mortar, comprising between 5 and 25 wt.% inorganic binder, wherein this binder consists of calcium aluminate cement, wherein this calcium aluminate cement comprises: - between 30 wt.% and 80 wt.% Al2O3; - less than 0.1 w% Cl“; - less than 0.4 wt% alkali; - less than 0.3 wt.% 803. In addition, this invention relates to an assembly of a masonry mortar with such a masonry mortar composition and bricks. Furthermore, this invention also relates to masonry erected with such an assembly.

Description

P762NL Masonry Mortar Composition This invention relates to a masonry mortar composition for masonry mortar and to an assembly of a masonry mortar with such a masonry mortar composition and bricks for erecting masonry.

Masonry mortar here refers to mortar according to EN 998-2. The invention applies to both the types G (performance masonry mortar), T and L described herein. Such masonry mortar has various applications and is typically intended to be used in combination with facing bricks to erect a facade.

Brickwork is defined as brickwork constructed in accordance with good building practices, as described in Info sheet 45 — Brick masonry implementation guideline of the KNB, December 2015 and in edition TV271 of the BBRI, February 2020.

A known problem with existing masonry mortars used to build up masonry is the occurrence of late efflorescence, which is persistent and permanent and shows a light, white-grey haze on the surface. Typically for this type of efflorescence, they only appear after a few months or even only after one or two years after completion of the building.

The efflorescence mentioned here can consist of hydrated or non-hydrated forms of CaSO,4, and possibly also as double salts with other cations such as Na, K or Mg, or in combination with CaCO3. These efflorescences are typically described as late gypsum efflorescence, as described for example in Bowler & Winter, 1996, Britisch Ceramic Transactions, 95-2, 82-86, or in KNB, 2016, Schoon Metselwerk: Causes and Prevention of White Rash or still in Brocken & Nijlen, 2004, 13th Intl. Brick & Block Masonry Conference, Amsterdam.

The object of this invention is to provide a masonry mortar composition for masonry mortar with which this known problem can be greatly reduced.

This object of the invention is achieved by providing a masonry mortar composition for masonry mortar, comprising between 5 and 25 wt.% inorganic binder, this binder consisting of calcium aluminate cement, wherein this calcium aluminate cement comprises: - between 30 wt.% and 80 wt. % Al,03; - less than 0.1 w% CI; - less than 0.4 w° of alkali; - less than 0.3 w% SO3.

The percentages used here and below are respectively mass percentages of the total masonry mortar and mass percentages of the total binder, which are determined according to the test method in accordance with EN 196-2. The alkali content is expressed as Na2O equivalent (Na2O+0.658 K2O). With masonry mortar with such a masonry mortar composition, the aforementioned problem of late gypsum efflorescence is greatly reduced.

A known accelerated method to measure these secondary gypsum efflorescences for this purpose is described in Chwast's thesis, 2017, Gypsum eflorescence on clay brick masonry.

Ph.

D.

Thesis, KU Leuven.

Such a masonry mortar does not or hardly bleed by itself, so that when used in combination with facing bricks it entails a considerable reduction of the known problem.

Efflorescence caused by the mortar and caused by the interaction of mortar with brick can be prevented here.

The masonry mortar according to this invention can be processed into masonry with a wide range of bricks with different initial absorption classes (according to EN 771).

A masonry mortar according to the invention does not require any additional processing or barrier between brick and mortar, such as a hydrofuge. With existing masonry mortars, certain bricks must first be dipped in a hydrofuge solution to be processed in masonry in order to counteract the problem mentioned. With a masonry mortar with a masonry mortar composition according to this invention, no such additional processing of the bricks is required for the same end result. Masonry with masonry mortar with a masonry mortar composition according to this invention thus continues to have the same positive properties of existing masonry, whereby the risk of efflorescence is considerably limited. In contrast to hydrophobized facing bricks, no adapted mortar should be used here because of the reduced suction power of the brick.

In-situ testing has shown that this invention also greatly reduces the problem of salt efflorescence occurring during or immediately after the construction phase. These efflorescences can consist of highly soluble salts, originating from the masonry itself, and include single or combinations of hydrated or non-hydrated forms of Na2SO:4 K;SO4 and MgSO:. Lime efflorescence can also fall under this. This masonry mortar composition can thus provide protection against the so-called initial efflorescence, which can already disfigure buildings during the construction phase.

The characteristic shear strength of masonry mortar with such a masonry mortar composition according to this invention is above the requested minimum requirement of 0.15 N/mm? according to EN 1052-3. Depending on the brick used and its initial water absorption class, the characteristic shear strength varies between 0.24 N/mm? and 0.34 N/mm.

The masonry mortar composition contributes to a sustainable, safe building solution. Masonry mortar with such a masonry mortar composition has a lower alkalinity and does not contain chromium in contrast to traditional masonry mortars. Preferably, the calcium aluminate cement of a masonry mortar composition according to this invention comprises: - between 35 wt.% and 70 wt.% Al,03; - less than 0.1 w% CI; - less than 0.2 wt% alkali; - less than 0.1 w% SO2.

Further preferred, a masonry mortar composition preferably comprises between 10% and 20% inorganic binder.

The masonry mortar composition according to this invention may further comprise more specifically between 70 wt% and 95 wt% aggregate according to EN 13139. Preferably, the masonry mortar composition comprises between 75% and 90% aggregate.

Further preferably, washed quartz sand is provided as aggregate to minimize the presence of soluble alkalis and sulphates. Even more preferably, this washed quartz sand is also dried.

The masonry mortar composition further preferably comprises between 0 wt% and 5 wt% organic binder. More specifically, this masonry mortar composition preferably comprises between 0.4 wt% and 2.5 wt% organic binder. More specifically, such an organic binder can be provided in the form of redispersible polymer powder in order to improve the physical properties in function of the required shear, bending tensile and compressive strength.

In addition, the masonry mortar composition may more specifically comprise between 0 wt% and 3 wt% additives. The masonry mortar composition preferably comprises between 0 wt% and 2 wt% additives.

Furthermore, the masonry mortar composition preferably comprises between 0.1% and 0.5% cellulose ether and derivatives, in order to control the processing, finishing and binding in function of the layer thickness of the masonry mortar, masonry mortar composition, conditions and absorbency of the brick.

In addition, a masonry mortar composition according to this invention may also comprise conventional fillers (aggregates) according to EN 13139. This masonry mortar composition preferably comprises less than 1 wt% alkali and less than 0.08 wt% soluble sulfates and even more preferably less than 0.1 wt% alkali and less than 0.02 wt% soluble sulfates.

In addition, the object of this invention is also achieved by providing an assembly of a masonry mortar and bricks, wherein the masonry mortar comprises a masonry mortar composition according to the invention described above.

The bricks of such an assembly can be more specifically characterized by an initial water absorption of less than 3 kg/m2.min and a soluble content of sulfates of less than 0.01 wt.% or more than 0.1 wt.%. The initial water absorption is determined according to EN771 and the w% according to IC analysis.

Masonry built with such an assembly will not show efflorescence as described above.

Alternatively, the bricks of an assembly according to this invention may be more specifically characterized by an initial water absorption of more than 3 kg/m? min and a milliequivalent ratio of the proportion of soluble Ca content to the total proportion of cations of more than 0.9 meq.

The meq ratio is thereby measured according to ICP analysis. Brickwork built with such an assembly can still show some efflorescence in the accelerated test according to Chwast, 2017 due to the strict nature of the accelerated test, in which all salts present are removed from the mortar system. In practice, such an assembly shows no to very low risk of said efflorescence. Practical tests have shown that even the most risky bricks in combination with this masonry mortar with a masonry mortar composition according to this invention can produce virtually bleed-free masonry, provided the processing instructions are observed and attention is paid to the execution of the masonry. Naturally, with a masonry mortar composition according to this invention, salt efflorescence originating from external factors cannot be prevented. For example, CaSO or other salts, which are caused by the leaching of, for example, hardening concrete in the construction, cannot be prevented from blooming on the facade. With an assembly according to the invention, efflorescence that can be caused by the mortar, the interaction of mortar with brick or only by the brick will be counteracted. Finally, the object of this invention is also achieved by providing brickwork that is erected with an assembly according to this invention described above.

This invention will now be further elucidated on the basis of the following detailed description of an embodiment of a masonry mortar composition and masonry according to this invention. The purpose of this description is only to provide illustrative examples and to point out further advantages and features of the invention, and thus should not be construed as limiting the scope of the invention or the patent rights claimed in the claims. A dry masonry mortar with a masonry mortar composition containing 79.08 wt% dried quartz sand, 20.00 wt% inorganic binder, 0.90 wt% organic binder and 0.02 wt% cellulose ether was used. Test pieces were made of this masonry mortar for bending tensile strength and compressive strength in accordance with NBN EN 1015-11, for shear strength in accordance with NBN 1052-3. The shear strength test pieces were made with 2 types of bricks, namely: bricks with an initial water absorption of 3 kg/m?.min and bricks with an initial water absorption of 1 kg/m?.min. These test pieces were stored for 28 days in accordance with NBN EN 1015-11 (bending tensile strength and compressive strength) and in accordance with NBN EN 1052-3 (shear strength).

Based on the mortar, test walls and test pieces were made with the two types of brick. The test walls (2m x 2.5m) have been set up outside in Belgium, which has a moderate climate with cool humid summers and mild rainy winters. The facade masonry faces south-west for maximum exposure to rain, wind and sun and is anchored in a quick-build brick with a cavity made of Scm. The whole has a roof that favors maximum drainage on the facing brick. The test walls with the proposed solution are flanked by test walls with a CEM I mortar recipe that unmistakably showed late gypsum efflorescence in the so-called ATM test. The latter are taken as a reference in order to guarantee that the conditions with another masonry mortar do cause late efflorescence. The test pieces have been subjected to the so-called ATM test as described in the aforementioned Chwast, 2017.

After two years, the test walls with the proposed masonry mortar in the aforementioned outdoor conditions show no initial and late efflorescence, in contrast to the reference test walls. After the accelerated ATM test, this test set-up, in which hardened and carbonated mortar adheres to the test stone, shows little or no efflorescence. This means that less than 5% or less than 10% of the surface shows efflorescence, where this percentage was determined using the ratio of the surface area covered with efflorescence to the total surface of the test stone by means of photo software.

The invention can be used in both in situ and prefab situations.

Claims (12)

Conclusions Masonry mortar composition for masonry mortar, comprising between 5 and 25 wt% inorganic binder, wherein this binder consists of calcium aluminate cement, wherein this calcium aluminate cement comprises: - between 30 wt% and 80 wt% AlLO3; — less than 0.1 w% CI; — less than 0.4 wt% alkali; — less than 0.3 w% SO3. A masonry mortar composition according to claim 1, characterized in that the masonry mortar composition further comprises between 70 wt% and 95 wt% aggregate. A masonry mortar composition according to claim 2, characterized in that the aggregate is washed quartz sand. A masonry mortar composition according to any one of the preceding claims, characterized in that the masonry mortar composition further comprises between 0 wt% and 5 wt% organic binder. A masonry mortar composition according to claim 4, characterized in that the masonry mortar composition further comprises between 0.1 wt% and 2.5 wt% organic binder. 6. Masonry mortar composition according to any of the preceding claims, characterized in that the masonry mortar composition further comprises between 0% and 3% additives. A masonry mortar composition according to any one of the preceding claims, characterized in that the masonry mortar composition further comprises between 0.1% and 0.5% cellulose ether and derivatives. A masonry mortar composition according to any one of the preceding claims, characterized in that the masonry mortar composition comprises less than 1 wt% alkali and less than 0.08 wt% soluble sulphates. 9. Assembly of a masonry mortar and bricks, characterized in that the masonry mortar comprises a masonry mortar composition according to any one of the preceding claims. Assembly according to claim 9, characterized in that the bricks are characterized by an initial water absorption of less than 3 kg/m2.min and a soluble content of sulphates of less than 0.01 wt% or more than 0.1 wt%. . Assembly according to claim 9, characterized in that the bricks are characterized by an initial water absorption of more than 3 kg/m”min and a milliequivalent ratio of the proportion of soluble Ca content to the total proportion of cations of more than 0.9 meq. 12. Brickwork erected with an assembly according to any one of claims 9 to 11.