NO791791L - BINDER FOR BRICK. - Google Patents

Abstract

Binder for bricks.

Description

The present invention relates to a binding agent for bonding

of bricks, especially porous bricks with holes, on the resting and/or end joints.

The most widely used agent for filling joints between bricks is mortar, a mixture of binding agent, water and additives such as slag, sand, pumice stone etc. Building plaster with and without lime addition, building lime with and without cement addition or cement are generally used as a binding agent. The mortar must have a predetermined firmness/as the loads in the resting joints are partly considerable. At the same time, it must also be elastic in order to equalize expansion and shrinkage movements in the rough-stone connection. This requirement applies above all to end joints.

For a series of bricks, especially stones with holes, the rule applies that the compressive strength of a joint is higher than for the individual stone. However, in the case of stone with large holes, such as porous stone with large holes, there is a risk that the steps will break between the holes in the resting surface area as a result of the shear forces.

This affects the compressive strength of the stone itself as well as the brick bond.

The disadvantage of using mortar is that professionals are needed for the construction of walls.

In connection with aerated concrete blocks, it is already known to grind these on the resting surfaces and connect them to each other using adhesives. A further connection can be made by filling in core concrete in vertical core concrete holes. However, such a connection is e.g. not immediately usable for masonry with higher holes. The unevenness, which cannot be completely eliminated by sanding, works against effective bonding. In contrast to the use of mortar, however, the bonding of bricks has the advantage that unskilled or trained labor can also be used for the construction of walls.

The invention is based on the task of finding a bonding agent for bonding bricks, especially porous bricks with holes, which enables unskilled or trained labor to work with the bricks.

The binder must have such a high strength that, in the case of stone with high holes, damage to the steps connecting the holes is avoided by shear forces.

According to the invention, this task is solved by a band of a hardenable binder and an additive which secures the band's shape.

Instead of the usual additives, the invention comes with a material that secures the band shape so that a band-shaped continuous binder is created, which can be placed on the connected resting surfaces or inserted into the end joints.

According to a preferred embodiment of the invention, the additive is a band of fibrous material. It can be kept ready in long lengths on a storage drum or similar and cut to the desired lengths on the construction site. The binder is applied either before application or after application

of the band of fibrous material, as it e.g. ironed with the binder substance. This essentially depends on the type of fiber tape and binder, and in the latter case especially on its curing time. After curing, the fiber tape together with the binder must form a support with predetermined compressive strength and elasticity before sufficient wall strength is achieved and the formation of cracks is prevented. It is clear that such a "mortar tape" has a sufficient water tightness and is also not attacked through a more or less aggressive atmosphere.

decrease or change adversely in its properties.

The mortar or joint tapes according to the invention can be a suitable fabric or a further design of the invention a tangle, spin or needle felt, which is given the necessary firmness and elasticity by adding a suitable binder. When such a band has a sufficient thickness, significant unevenness on the resting and end surfaces of the bricks can easily be smoothed out. The work with such mortar bands and bricks does not require any trained labour, but can therefore be carried out without further ado by untrained or trained people.

In order to absorb the forces that appear in the composition of the bricks, a further embodiment of the invention provides that the band's strength in the plane is greater than across it, which e.g. can be achieved by tightening the band in the longitudinal direction. A great firmness in the plane of the band prevents that, in the case of bricks with high holes, the areas between the holes are severely strained and damaged by shearing forces.

The tissue or the felt is made from fibers that do not rot, e.g. of glass, asbestos, metal or synthetic fibers such as polyamide or polyester fibres.

As a binder, in principle, ordinary hydraulic binders such as mortar come into consideration, to which additives can possibly be added to accelerate hardening. According to one embodiment of the invention, the binder is a normal temperature-hardening duroplastic resin or a cold-hardening duroplastic resin with a corresponding dosage of the hardener. Suitable resins are e.g. polyesters, epoxies, isocyanate resins, the suitable hardeners are known; examples include peroxides, tertiary amines, metal oxides.

When the binder is applied after laying the fiber tape, hardener and accelerator are mixed into the resin immediately before application. However, if the tape is to be soaked with resin before laying, it is particularly preferable to use a resin in which a hardener and possibly an accelerator have been incorporated microcapsule, i.e. in the form of small particles, which are incorporated into a protective polymer film, so that they do not can perform its function and premature hardening is avoided. The microencapsulation technique with film-forming polymers is known and used in various areas. Hardener and accelerator can be encapsulated separately or together. One such soaked joint tape can be stored for a long time, so that the soaking can take place immediately after the tape production and the soaked web is stored and shipped. The hardening reaction is only triggered immediately before or during work with the joint tape by crushing the capsules. As the microcapsules are destroyed by mechanical stress, especially pressure, the soaked tape can e.g. before laying out, it is passed over a spiked or disc roller, which with a large local surface pressure causes the capsules to burst, so that the hardener and possibly the accelerator are freed and the reaction can take place. You can also run a comb-shaped kicker or a roller over the already laid path under light pressure or use another suitable technique.

In the case of a band intended for the rest joints, if desired, a separate crushing of the capsules can be completely omitted, as the pressure of the masonry is sufficient to destroy. the capsules.

When the binder is a normal hydraulic binder such as mortar, according to another preferred embodiment of the invention, the additive to the binder that secures the strip shape can be a hydrophilic polymer, e.g. a polyvinylpyrrolidone. The polymer is used in an amount from approx. 0.5 to 8% by weight calculated on the weight of the finished binder. It is incorporated with a small amount of one or another known wetting agent for mortar mixtures. To improve the building's physical properties

.short fibers are added.

A predetermined amount of a mixture of dry ready-made mortar, hydrophilic polymer, approx. 0.5 to 4% by weight, and wetting agent is pressed corresponding to the length and width of the stones to be built up. Preferably, a fiber felt is pressed with, whereby the static firmness of the binder is further increased. A further increase in firmness is achieved when small fibers are mixed in with it. The individual elements in the mortar electrical tapes can be stacked on top of each other or next to each other by means of a folding mechanism. A binding medium of dry mortar, approx. 4 - 8% by weight hydrophilic polymer and preferably a fiber chip is so elastic that it can be rolled up on a storage drum without risk of breaking or tearing. Short fibers can also be introduced in such binder tapes.

Particularly advantageous is the application of the invention to bricks which are towed on the resting rafts, especially bricks with high holes. Below this, you can work with a relatively thin band, as no large differences in the height of the resting joints have to be equalised. For end joints where no significant loads occur, the tape can be thicker and also elastic. The material composition of a joint tape for the end joints can also be simpler, as a pressure load is missing. Theoretically, grinding the fronts of such stones would also be possible, but this would still mean that a lot of mass would have to be ground away. With the help of a relatively thick and elastic joint tape, larger unevenness can be compensated and other stresses can also be smoothed out, which especially occur in the end joints and lead to cracks.

The invention is now illustrated by preferred embodiments through the attached figures which show: Fig. 1 perspective part of a brick's composition according to

the invention,

Fig. 2 a part of a brick composition according to the invention seen from the front, in which the joint tape is laid in a particularly simple way.

Porous bricks 10 with high holes are arranged in a continuous composition. The brick 10 with high holes is of the usual type and consists of e.g. of brick material made porous with polystyrene balls. The stones' 10 dimensions are also standardized.

In the resting joints 11 there is arranged a strip 12 of a suitable felt with predetermined firmness which can first be soaked with a binding agent, e.g. a cold-hardened duroplastic. The soaking can take place before the laying on the resting rafts, as the tape is ironed with the binder. After hardening, the band 12 forms a desired binding, sufficiently pressure-resistant and elastic "putty" between the stones 10. i

Short sections of a band consisting of a simpler felt or textile weave are inserted between the end joints 13, as they are hardly exposed to compressive forces. They can also be thicker than the band 12. This is particularly the case when the resting rafts of the stones 10 are towed and the band 12 is designed correspondingly thin. The bands 14 are mixed with the same binding agent as the bands 12 or with another suitable binding agent to achieve a "putting together" of the stones 10 in the desired manner.

A simpler laying of the tape is now shown in fig. 2. Here a tape already soaked with binders is used. From the storage drum, a length of tape 15 is rolled off onto the foundation on which the wall is to be erected, laid out and separated from the storage drum. Then the brick layers are set, whereby further bands 15' are rolled off from the warehouse, running' and laid in such a way with the application of the porous bricks with high lids that each brick 10 is enveloped by the band 15' from three sides (two end joints and one resting joint). As can be seen from fig. 2, in the case of a wall erected in this way, in the lower layer every second brick lies directly on the base band 15, while the next brick lies on the second band 15' which is laid out when the wall is set. Or put another way, every other brick is inserted when erecting the wall into the just unrolled band 15', while with each subsequent brick the band 15' is pulled over its upward facing surface. In the ready-built wall, however, each brick with high holes is surrounded on all four sides by bands of 15 or 15'.

In this embodiment of the invention, a tape is preferably taken that is soaked with thermoset resin, which contains hardener and microencapsulated accelerator. As the end joint is not under pressure, the tape is subjected to a mechanical treatment before laying, e.g. over a disc roller, so that the microcapsule bursts when the tape is laid out.

When the invention was described in connection with porous bricks with high holes, it is of course not limited to this. Thus, the invention can advantageously find application!

especially for other stones with high holes and similar bricks in,

Claims (15)

1. Binder for joining bricks, especially porous bricks with holes, on the rest and/or end joints, characterized by a band (12, 14, 15) of. a hardenable binder and an additive that secures the tape shape. 2. Binder according to claim 1, characterized in that the additive is a tangle, spin or needle felt. 3. Binder according to claim 1 or 2, characterized in that the additive consists of glass, asbestos, metal or synthetic fibres. 4. Binding agent according to one of claims 1 to 3, characterized in that the binding agent is a normal hydraulic mortar binding agent. 5. Binder according to one of claims 1 to 3, characterized in that the binder is a at normal temperature or by a corresponding dosage of the hardener and possibly the accelerator cold-hardening duroplastic resin. 6. Binder according to claim 5, characterized in that the hardener and the accelerator are mixed microencapsulated in the resin. 7. Binder according to one of claims 5 and 6, characterized in that the thermosetting resin is a polyester, epoxy or polyurethane resin. 8. Binder according to claims 1 and 4, characterized in that the additive is a hydrophilic polymer that has been pressed into ribbon form with the binder and a common mortar wetting agent. • 9. Binder according to claim 3, characterized in that the hydrophilic polymer is polyvinylpyrrolidone. 10. Binder according to claim 8 or 9, characterized in that the hydrophilic polymer is present in an amount of approx. 0.5 - 8% by weight calculated on the binder. 11. Binder according to one of claims 8 and 9, characterized in that, in addition to the hydrophilic polymer, it has an additive according to claim 2 and/or 3. 12. Binder according to one of claims 8 to 11, characterized in that it contains the hydrophilic polymer in an amount of 4 - 8% by weight. 13. Binder according to one of claims 1 to 12, characterized in that the firmness of the tape (12, 14, 15) in one plane is greater than across it. 14. Binder according to one of claims 1 to 13, characterized by its use on the resting surfaces of dragged stones, especially bricks (10) with high holes. 15. Binder according to one of claims 1 to 5 and 8 to 13, characterized in that the band (14) for the end joints (13) is thicker than the band (12) for the resting joints (11).