BE734149A - - Google Patents

Description

  

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  Mortar compositions for dry laying and grouting of tiles

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The present invention relates to mortar compositions for dry laying and grouting of tiles and, in particular, for improving the strength properties of ceramic tiles laid by means of such compositions.



   It is known that floor covering tiles, subjected to ordinary or intensive service traffic, are sometimes defective. The most damaging items are the stiletto heels of ladies' shoes as well as the trolleys. and similar devices. The mortar used for the placement of the bars exerts an influence on the capacity of resistance to the damage caused by this traffic. Steel, fiber, resin or hard rubber wheels of the trolleys are also susceptible to damage to the tiles and the extent of the damage caused differs depending on the mortar used.



   In addition, the tiles are often exposed to the action of various heavy objects, for example falling dishes or pots which damage the tiles if the mortar used is not suitable.



   It has been observed that the mortars for dry and / or thin-bed laying, introduced on the market for a little over a decade and which have achieved extraordinary success, are however, in general, not enough. resistant to the action of traffic of the aforementioned type. As a result, the tiles made using these mortars tend to crack and break with use. This problem is so serious that it is not uncommon for architects not to recommend the use of dry laying mortars, despite the many advantages that these have.



   According to the present invention, it has been found that one can substantially increase, surprisingly, the properties and characteristics of haberdashery for dry laying and grouting, by the addition of certain agents which substantially reduce the ability of dry grouting. water absorption of these compositions, without however completely eliminating this ability.



   The advantages of using these agents are a marked reduction in breakage, splitting and cracking of tiles subjected to heavy traffic. Consolidating agents or water absorption inhibitors which can be used according to the invention include organic siloxane polymers, for example fluid silicones and silicone emulsions, glycol esters, certain carbonic acid esters. , certain esters of phosphoric acid and / or mixtures of the aforementioned substances.



   Tile laying and masonry construction was generally carried out using mortars consisting of Portland cement, lime and sand

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   added with water in an amount necessary to give them good workability as well as to partipate to the action of the hardening by which the cement forms a gel. However, the hardening of the cise takes place for one. This is an appreciable period and the retention of water in the mortar in an amount sufficient to maintain the good progress of the hardening, until the final stage, poses several problems.



   The usual hydraulic cement mortars tend to leave considerable quantities of water first by evaporation in the atmosphere but much more by absorption in the tiles, or else in the masonry or any other support on which they are deposited. When the water gate is too large, hardening is incomplete and the mortar has a soft, chalky consistency and the resulting bond is weak or nonexistent.



   To overcome these difficulties, it is necessary with the usual mortars to maintain a high humidity during the whole operation of laying the tiles. To this end, the absorbent tiles are pre-soaked in order to prevent the absorption of the water in the mortar; thick, heavy and generally multiple basecoats of mortar are placed on the support and generally humid atmospheric conaitions are maintained throughout the setting.



   These working methods naturally require large amounts of material, as well as considerable labor for the preparation of the mixture, the placement and trowel treatment of the substrate, as well as for the handling of the pre-soaked tiles. . In addition, the need to maintain humidity conditions for the installation of tiles by means of usual Portland cement-based mortar makes their use impossible or impracticable when the substrates are made of gypsum boards or plaster. .



   In recent years, that is to say in the last decade, the manufacture and sale of mortars having the property of retaining water have been developed for the installation of ceramic tiles. on walls and floors.



   Of those compositions endowed with a water retention capacity, make it possible to avoid the application of thick layers and the maintenance of humid conditions, as is the case for traditional installations. In addition, they can be used to achieve a good bond between ceramic tiles and a wide variety of substrates, such as masonry, gypsum board, concrete and a wide variety of others. types of surfaces used under varying application conditions.

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   Such compositions also have the property of being able to be applied in a thin layer, that is to say that they can be used in an application.
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 dry atmosphere for the menu ùa avuches which are much thinner than those required when using traditional mortars based on hydraulic cement.



   Laying and Pointing mortars for dry working and / or for thin-bed hardening consist of hydraulic cement and one or more polymeric materials, capable of acting, at least in part, as retention agents. 'water or as viscosity modifiers as has been described, for example, in the United States patents filed by VILE COUNCIL OF AMERICA under the numbers 2,934,932, 2,962,467, 2,959,489, 2,990,382 , 3,030,258 and 3,243,307. Such compositions are generally packaged in a single package and are powdery.

   For processing, approximately 11 to 40% water is added relative to the weight of the dry composition and the resulting mass is mixed, generally using a machine. obtaining a unitary plastic mass * elm which can be easily used with a trowel.

   Dry laying and jointing mortars or for thin-layer curing generally contain, as agents for water retention or viscosity modifying agents, the-; the following substances: a cellulose ether, such as methylcellulose, hydroxyethylcellulose, arboxymethylhydroxyethylcellulose, methylhy-
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 droxypropylce1lu1ose, ethylydroxyethylcellalose, methylcarbonimethoxy-cellulose and methylhydroxyethOxyce Iluluse. These cellulose ethers are soluble in water and have an aqueous solution viscosity of between about 10 and 100,000 cent.1poiae., Or tneM plus, measured at 20 ° C in a 2% aqueous solution.

   The * OOl8p08it.lon. for dry-laying wvrtiers, described above, are particularly suitable for placing ceramic tiles, since with such cGlllP081t.lona it is not necessary to wet oe4elabio * mt the support on which one wishes to fix the tiles, nor the tiles themselves, when 11. are absorbent. These! Positions for mortars have the further advantage of being able to be used which forms a layer * rela% 1V-% aimes (eg having a thickness of about 0.6 cm) for the laying of 08I'I'8UX in c4raa1que. Other advantages of dc8dt.t8 mortars are cited dam patents -M1aw * 8 rather hut as well as q <M 08 10 text of the present brewt.



  It was found that during the pom of 08l'1'881 & X in C! 4rut.qu8 8UJ 'them using 1IIOI't.181'8 for the oplei t - du t.J'p8 <t <efit, if srrise triqu88-

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 ment that these tiles crack, shatter and dei'ont when subjected to heavy traffic, for example to ladies' heels or to cart wheels. This observation is very serious because it limits the use of mortar compositions for dry laying in certain areas of the floors.



   The object of the present invention is to obtain mortar compositions for the dry laying and grouting of tiles, having improved usable properties and capable of withstanding much more intensive service traffic than is required. was possible until now.



   The other aims of the invention are as follows: - to designate additives for dry and thin-layer workable mortars, in order to improve the properties of use of such mortars - to describe mortars for dry and thin-layer working thin, containing a hydraulic cement and a polymer additive capable of retaining water, these mortars being able to be used for the realization of floor tiles having a great resistance to the impact - describe mortars as defined above, having the ability to greatly reduce the absorption capacity of water, without however completely eliminating this capacity.



   The aforementioned objectives as well as others can be achieved, within the framework of the present invention, by incorporating in the compositions based on hydraulic cement and on polymeric materials, described above, an agent capable of reducing the absorption capacity of water of these compositions.



   It has been found surprisingly that the above mortars, containing agents capable of reducing the water absorption capacity up to a third or half of the value obtained in the absence of these agents, have properties of considerably higher use than mortars not containing these agents. Such results are quite unexpected.



   Agents suitable for carrying out this invention are materials capable of reducing the water absorption capacity of mortars.



   Wall this * agents include silicone oils and emulsions of silloones, @artaine esters of phosphoric acid, certain esters of carbonic acid esters of glycois and polyglycols and slurries of the aforementioned substances.



     Specific examples of absorption capacity reducing agents

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 of water which can be used in the context of the invention are the polyethylene glycol esters of long chain fatty acids, such as monopalmitate
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 tetraethylenic glycol, hecaethylenic glycol monolaurate, nonaethylenic glycol monostearate, nonaethylenic glycol dioleate, tridecaethylenic glycol monoarachidate, tricosaethylenic glycol monobehenate, glycol dibehenicoseethylenate;

   long-chain polyglycols in which a hydroxyl group is esterified with an acid
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 graz higher and the other hydroxyl group is ethereal with a low molecular weight alcohol, such as methoxypolyethylenic glycol monostearate in which the polyglycol ether used has an average molecular weight of 550.



  A combination of two or more of these agents can also be employed.



   The glycol and polyglycol esters referred to in the present invention can be used alone or in combination with glycols, for example ethylenic, diethylene, propylene, polyethylene glycols and the like.



   The compounds formed by the reaction of glycols with organic acids, with elimination of water, are particularly suitable. Typical substances along these lines are high molecular weight fatty acid esters such as fatty acids containing 12 to 18 or more carbon atoms in the molecule. Among the examples of suitable fatty acids are lauric, myristic, palmitic, oleic, stearic, ricinoleic and linoleic acids. Among suitable specific compounds are diglycol laurate and diglycol oleate. A dose of the aforementioned esters of between 0.05 and 0.5%, relative to the weight of the dry mortar, and generally between about 0.1 and 0.3%, is sufficient to obtain very good results.

   Complete elimination of water absorption capacity in
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 mortar is neither nlfce.8 & ire, nl desirable.



  As an agent * reducing the absorption capacity of water, it is also possible to use a "partial ester" of polyhydric alcohol and a higher fatty acid ocontaining a hydroxyl group in Mina, optionally with the addition of oils, areas, d 'emulsifying agents * or other desirable materials. The expression "partial ester" means an ester of polyhydric alcohol in which at least
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 one of the bydrojwles groups remains free or not esterified.



  For the production of the freeite partial ester, any P01JbJdI'1qu amwopri 'alcohol can be used, among others the 113001. étkwldnique, diethylenique and tfietttylenique, pPopy1éniqu. Glycol, sorbitol, ni% O1 eto. .. Of "" any hydroxylated vmS aid may be useful, among others,

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   mono-, di- or trihydroxystearic aciaes, ricinoleic acid, hydrogenated ricinoleic acid, hydroxy fatty acids from fish oil, hydroxy fatty acids from cottonseed oil, hydroxy fatty acids from cottonseed oil. beef foot or other suitable hydroxy fatty acid.



   When the agents reducing the water absorption capacity, of the aforementioned type, are in the liquid state, preferably by adsorbing them onto a solid support, in order to then introduce them into the composition in the form of a powder which can flow freely. Among the inert solids or suitable fillers on which the liquid agents can be fixed by adsorption, the following substances may be mentioned: zirconium silicate, silica airgel, fixed white, talc, pyrophyllite, dif - various clays, diatomaceous earth, micro-sieves, crystalline metallic aluminosilicates (molecular sieves) and other similar materials.



  The solid support is generally found in a finely divided state and has a large surface area. Particularly advantageous support materials are zirconium silicate, silica airgel and sand, used alone or in combination with each other.



   In practice, the liquid water absorption capacity reducing agent can be absorbed over all or a small part of one or more solid ingredients, forming a component of the mortar or grouting mixture. for example aable, lime or hydraulic cement. It is mixed in this form with the remainder of the ingredients forming the composition. In the case of compositions comprising latex emulsions, the agent for reducing the water absorption capacity can be added to the emulsions, or dispersed in the form of a powder of good flowability of the type mentioned in the cement powder to which the emulsion is added.



   Among the water absorption capacitance reducing agents which are preferably used, mention may be made of polar-oriented organic silicone polymers which are insoluble in water, for example oils and silicone emulsions. , phosphoric acid esters, glycol and polyglycol esters of long flesh fatty acids. (for example those containing more than 12 carbon atoms in the chain). The glycols used for the preparation of the glycol and polyglyrol esters may be those which have been desired above.



     In practice, silicone oils and emulsions are preferably adsorbed on inert solids such as "SUPEHCIL", charcoal, portland cement, bentonite and pumice.

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  . J) ea MlaDp8 4 'and cI8 ombimt m 4' ..... - polJIl1oo1 and glycol ddpuda <ur a mppom mimics pavent 8t: re avadtspwaarnt used cone * reducing agents * of the 04kfflltld of abaorptian ci'eau.



  Although they are suitable for a ta9Cl1 <c <n <rtl * for all seo and / or undercoat laying, the compositions of the present invention are primarily intended for laying of vitreous tiles (non-adsorbing) on a horizontal support for the purpose of making a floor covering.



   According to the teachings of the present invention, it is also poaai- able to prepare conductive mortars for dry or thin-film poae, usable with electrically conductive ceramic tiles, with a view to obtaining a antistatic tiles, for example, in hospital operating rooms. These conductive mortars generally contain an electrically conductive component, such as carbon black or particles which make them conductive.

   The incorporation of the reducing agent has the water absorption capacity, in accordance with the invention in such conductive mortars, significantly improves the mechanical resistance characteristics of the latter.



   In practice, the reducing agent of the water absorption capacity is added in small doses.



   Depending on the type of agent that has been chosen, the amount to be used varies between about 0.01% and 1.0% in weight, relative to the weight of the dry mortar and usually between about 0.05% and 0.5% ae this weight. A sufficient quantity of the aforementioned agent is generally added so that the setting mortar
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 dry or in a layer iiiiituc, with hyaraulic cement and polymeric material, absorbs less than 26% by weight approximately water, and preferably less than 20% by weight approximately.



   Although it is possible to use a large variety of hydraulic cements, the best results are obtained with Portland cement and it is this which is preferably used. The amount of cement incorporated in the compositions can vary between about 20 and 97% by weight.



   The amount of polymeric water retention agents can vary between about 0.1 and 6% relative to the weight of the dry composition, and preferably between 0.2 and 3%.



   In general, the greater the viscosity of the retention polymer, the lower the amount to be used, and vice versa.



   As previously specified, inert constituents, such as sand and limestone, are preferably incorporated into the compositions.

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 in order to ensure a membership resiatanos ban. These fillers can also be used, such as pearlite, tale, pyrophyllite, various clays, diatomaceous earth and various pigments such as titanium dioxide, zinc oxide,. aluminum oxide, powdered baritones and the like.

   The amount of fillers and pigments incorporated into the compounds can vary up to about 400% based on the weight of the hydraulic cement, but is preferably between 10 and 75% about. the composition of dry mortar. If sand is used, for example, this is introduced in amounts of up to 75%, preferably between about 10 and 75%, based on the weight of the dry composition; if limestone is used, this is introduced in amounts of up to 45%, preferably between about 10 and 45%, based on the weight of the dry composition.



   The composition may additionally contain, if desired, other additives such as dimethylol urea, melamine-formaldehyde resins, polyvinyl alcohol, polyvinyl acetate and the like, in order to obtain particular properties. and special effects. To increase the gelation rate in a known manner, it is possible, if desired, to add halides of alkaline earth metals, such as chlorides, iodides, bromides and fluorides of alkaline earth metals, for example, halides of calcium, magnesium, strontium and barium, as well as mixtures of these salts.



   To prepare the compositions according to the invention, the hydraulic cement, the water-retaining polymers and the reducing agent of the water-absorbing capacity, with or without the modifying ingredients described above are dry mixed. to form such dry compositions, which can be easily activated by the addition of water, for the production of mortars and jointing products having the properties described above.



   In general, the amount of water to be added to the dry compositions, in order to prepare the jointing materials and the improved mortars can vary between about 11 and 40% relative to the weight of the dry composition, and this depending on the amount of 'modifying ingredients used. Usually, the amount of water to be added is between about 18 and 35% based on the weight of the dry composition.



   The preferred compositions within the scope of this invention are the following:

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 Weight in%
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<tb> Cement <SEP> Portland <SEP> - <SEP> 18.7 <SEP> to <SEP> 89.7
<tb>
<tb> Sand <SEP> or <SEP> limestone <SEP> 10 <SEP> to <SEP> 75
<tb>
<tb> Ether <SEP> from <SEP> celluloae <SEP> 0.2 <SEP> to <SEP> 6
<tb>
 Reducing agent of water absorption capacity - 0.1 to 0.3
In the choice of improving agents and cellulose ethers used, it is advisable to avoid materials of the polyelectrolyte type, which produce flocculation of the hydraulic cement or else which precipitate themselves. The use of additives which prevent the hardening of hydraulic cement should of course also be avoided.



   The ability to retain water is one of the characteristics of dry-laying mortars. This property is measured by placing a 0.3 cm layer of the mixture previously added with water on the porous side of a standard commercial tile 181, divided into squares of 106 x 106 mm. A thin plate of glass is placed on top of the layer of mortar and the whole is laid out below a microscope lens. As the water leaves the mortar and migrates into the porous part of the tile, the layer of mortar contracts and, in doing so, displaces the plate downwards. This displacement is measured with precision in mm using a microscope, after which this data is plotted on a graph as a function of the square root of the duration in minutes.

   The inclination of the straight line, divided by 1000, gives the retention value. The dry-set mortars of the present invention are characterized by a water retention value greater than 10, preferably greater than 15. Most commercial dry-set mortars have a value. retention of between 35 and 50, while the usual jointing materials subjected to such a measure generally show values of 15 to 35.



   The mortars for dry laying in accordance with the present invention can also be characterized by the viscosity of the aqueous phase. These mortars, in the state in which they are when they can be applied with a trowel, are characterized for a viscosity of the aqueous phase greater than 500 centipoise, at 20 C.



   Low water absorption, by the composition in the cured state, is also a characteristic property which is determined as follows: The mortar is mixed in a pure planetary mix for 10 minutes and molded to obtain bars. not 2.5 x 15 x 0.6 cm thick which was cured for 6 days at 21 ° C in an atmosphere having a relative humidity of 50%.

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   They are then dried at 49 ° C. for 2 minutes. After cooling, the bars are weighed and placed in water in a vacuum chamber.



  The pressure in the chamber is lowered to 11 mm Hgz, then the vacuum is removed. The crossed out leaves are then soaked for 2 hours and a vacuum of 11 mm Hga is applied again, which then aupprimé. The water on their surface is removed and weighed again. The water absorption is expressed by the percentage of the variation in the weight of the bars after absorption of water and removal of it, that is to say the difference in% of the weight between the two weighings described. .



   The water absorption by the special (improved) morti, - ,, - determined as above should be less than 26% and preferably less than 20%.



   The teachings of this invention, applied to the preparation of a dry jointing material, provide a material having increased stain resistance which is a desirable property. The examples and the table below make it possible to illustrate and explain the nature of the present invention.



  Example
A series of tests were carried out with mortar compositions for dry laying with and without the addition of the reducing agent of the water absorption capacity. Mortar No. 1 had roughly the following composition:% by weight Sand 60 Light Portlana cement type 1 38.6 Methylcellulose (4000 cps Methocel) 0.48
In accordance with the table below, Mortar No. 1 was prepared by mixing the above-mentioned ingredients.



   Mortar # 2
Mortar No. 1 was used to which 0.25% of a product consisting of a mixture of hydrocarbons and a combination of polyglycol esters and glycol deposited on an inert support was added. As follows from the table, the addition of this agent made it possible to obtain a morLier having a lower water absorption capacity. Its use has also made it possible to improve the properties of the flooring produced by 50%.



   Mortar n 3% by weight Sand 50

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 Portland cement type 1 49.13 Methylcellulose (15,000 cps - Methocel) 0.87
Mortar # 4
Mortar No. 3 was used, to which was added 0.25% of the same product reducing the water absorption capacity as in mortar No. 2.



   This again resulted in a mortar having lower water absorption capacity and better working properties.



   Mortar # 5
The composition of Mortar No. 1 was used, to which 0.125% tri-n-butyl phosphate was added. A mortar was thus obtained having a lower water absorption capacity and the quality of the tiling which it made possible to achieve is comparable to that obtained with mortar no.1. Mortar no.6% by weight Gable 60 Portland cement type I, light 38.6 Hydroxyethylcellulose 0.48
Mortar # 7
The composition of mortar No. 6 was used to which 0.125% tri-n-butyl phosphate was added. As shown in the table, the mortar acquired a lower water absorption capacity. The properties of the tiling produced during his intervention were superior to those of the tiling obtained :? with mortar n 6.



   To test the mortars the following operative pout was used: A plate was prepared using these 5 x 5 cm porcelain tiles.



  On one half of the plate, the tiles were fixed by means of a mortar containing a reducing agent of the water absorption capacity, and on the other half - which served as a control - the mortar used was not contained no such agent.



   The mortar mixtures described * were placed in a mechanical mixer into which the necessary quantity of water (26% of the weight of the dry composition) was introduced and the mixture was gleaned until a smooth pite was obtained and uniform.



   This pite was laid on a concrete floor to form a layer of mortar approximately 0.47 bone thick. The layer of mortar was then spread using a notched trowel which forms silos on the
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 itself, after which we have placed this Mortar wn <p1aqa8 in oeoe- de ofl'881que.

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  Said plate was embedded in the mortar in order to flatten the grooves and create a continuous layer of mortar below the tiles. The spaces between the tiles and the mortar were then grouted using a commercial Portland cement. The mortar and jointing material were then left to cure for 28 days. The thus cured coating was subjected to the "Robinson Floor Tester" (cf. article, - of D.R.



  ROBINSON and JV FITZGERALD in "Flooring Magazine", December 1959, p.54 and 56) and the test was continued until the tiles laid with a mortar containing reducing agents had the capacity to water absorption have suffered visible damage.



   The difference between the behavior of the mortars with and without the aforementioned agents is compared with the table below and the results obtained have been commented on above.



   BOARD
Water absorption by dry hardened mortars
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<tb> Mortar <SEP>? Reducing agent <SEP> <SEP>% <SEP> of <SEP> absorption <SEP> Number <SEP> of <SEP> car-
<tb>
<tb> of <SEP> the <SEP> water capacity <SEP> average <SEP> of <SEP> two <SEP> the water <SEP> damaged
<tb>
<tb> absorption <SEP> this water <SEP> exterminations <SEP> in <SEP> test <SEP> of
<tb>
<tb>
<tb> present <SEP> floor <SEP> to <SEP> car-
<tb>
<tb>
<tb> networks <SEP> with <SEP> the
<tb>
<tb> mortar
<tb>
<tb>
<tb>
<tb>
<tb>
<tb> 1 <SEP> no <SEP> 44.6 <SEP> 90
<tb>
<tb>
<tb>
<tb> 2 <SEP> yes <SEP> 19.7 <SEP> 42
<tb>
<tb>
<tb>
<tb> 3 <SEP> no <SEP> 40.6 <SEP> 100
<tb>
<tb>
<tb>
<tb> 4 <SEP> yes <SEP> 16.6 <SEP> 38
<tb>
<tb>
<tb>
<tb> 5 <SEP> yes <SEP> 16.1 <SEP> 56
<tb>
<tb>
<tb>
<tb> 6 <SEP> no <SEP> 36.0 <SEP> 92
<tb>
<tb>
<tb>
<tb> 7 <SEP> yes <SEP> 17,

  0 <SEP> 48
<tb>
 

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The invention, in its broad aspect, is in no way limited to the examples, methods, compositions, combinations or improvements described above.



  Variations which fall within the scope of the claims may be made without departing from the principles of the invention and without sacrificing the main advantages thereof.



   In particular, as has been said above, it also applies in the case where the base mortar contains Portland cement, a cellulosic ether and other agents capable of imparting particular properties, in particular water. polyvinyl alcohol (cf. US Br. 3,030,258 of 28.5 1958, on behalf of TILE COUNCIL OF AMERICA).

 

Claims (1)

CLAIMS 1 - Mortar composition containing a hydraulic cement and an organic polymer having a water retention capacity, said water retention capacity being greater than 10% by weight, characterized in that one adds to this composition an agent capable of reduce the water absorption capacity of the mortar. 2 - Composition according to claim 1 characterized in that the modifying agent of the water absorption power is chosen from the group of substances comprising silicone oils, silicone emulsions, glycol esters, esters. of polyglycols, phosphoric acid esters, carbonic acid esters and mixtures of these substances. 3 - Composition according to claim 1, characterized in that the reducing agent of the water absorption capacity is tri-n-butyl phosphate. 4 - Composition according to claim 1, characterized in that the agent for reducing the water absorption capacity is present in an amount less than approximately 0.5% by weight, relative to the weight of the dry composition. 5 - Mortar composition for dry laying, which can be mixed with about 11 to 40% of its weight of @ au to produce a mortar applicable with a trowel, characterized in that the viscosity of the phase water is greater than 500 centipoise, said composition comprising a hydraulic cement, sand and / or limestone and a water soluble cellulose ether and a small effective amount of an agent capable of reducing the absorption capacity water from the mortar. 6 - Composition according to claim 5, characterized in that the cellulose ether is selected from the group of substances comprising methylcel- EMI15.1 lulont, nydro9ty <thyleellulose, metiqrltyrdrorpropylcellulose, oarboxy- "¯¯lo.1lu1OH, ethyltqrdroarethylcellulose, methylcarboxy- mdtbcoci e ollulose and osthylhydrcotyethyleellulose. 7 - Process for preparing a mortar for laying seo from the composition of claim 5, characterized in that there is added approximately EMI15.2 11 to z - by weight of MU 8't m oe that one -lange mechanically the composition, which results in fear prcdeire wfe .... plastic capable of being applied using a trowel. 8 - Installation process of tiles using a plastic basket EMI15.3 planned4 * according to .., ... 4SoatICID 1, c-aru * 18 'in that 18 support is 1'8v8tu <Desc / Clms Page number 16> EMI16.1 of a * COUOBO twink of mmo Dlmti4w and had 01 that we p8o loo O & l'l'8 & \ IX an od. 1'UI1C "1 to the mrtier oouobe which resulted. 9 - Process according to claim es oaraot4l'i- in 00 that the espuea between the O & 1'l'8 & Wt * ce% rup118 of a rtüre Jo1DtoIIMDt. 10 - Ion method of claim 9, oaractérisé in that the support used is a constituent of the floor to be coated and in that the oarr u is a glass tile. 11 - Mortar composition for seo laying by means of a trowel comprising a hydraulic cement, an organic polymer capable of retaining water, an inert solid chosen from sand and limestone, a capacity reducing agent of water absorption, said mortar having an aqueous phase viscosity of greater than 500 centipoise at 20 ° C. and a water absorption capacity, in the hardened state, of up to 26% by weight. . 12 - Dry composition according to claim 5, characterized in that it contains 18.7 to 89.7% by weight of Portland cement, 10 to 75% by weight of sand EMI16.2 or limestone, 0.2 to 6% of a water soluble cellulose ether and 0.01 to 1.0% of a reducing agent in water absorption capacity. 13 - Installation for tiling comprising a horizontal support, a thin layer of mortar on said support, comprising a hydraulic cement, a polymer capable of retaining water as well as a reducing agent of the water absorption capacity, and a number of vitreous ceramic tiles, laid with a certain spacing in the layer of mortar. 14 - Installation according to claim 13, characterized in that the mortar layer comprises an inert aggregate consisting of sand or limestone.