HUT77731A - Building stone - Google Patents

Abstract

The brick has an integrated insulating mass (6) as the connecting brick. The building brick can have an insulating layer or plate on one side. It has dovetailed or inclined grooves in which the insulating layer or plate is anchored by tongues complementary with the grooves. The insulating mass or plate is made from mineral foamed clay and the brick is made from natural or artificial stone. The insulating plate can be flat along the edge for butt connection of the insulating plate between adjoining connecting bricks.

Description

BACKGROUND OF THE INVENTION The present invention relates to a masonry stone which forms a masonry stone formed from integrated insulating material. The insulating material is preferably arranged on one side of the masonry stone (4) in the form of an insulating layer (6) or an insulating sheet. THE

At least one side of the IC masonry stone is provided with grooves (2) in which the insulating layer (6) or insulating sheet is fixed to the insulating layer or insulating sheet by joints (14, 16, 181) complementary to the grooves. The insulating layer (6) or insulating sheet is provided with grooves (= 23) and opposite sides of the insulating layer (6, 6 ') or grooves (= 23) between the adjacent masonry tiles (2, 2') adjacent composite masonry units (designed for overlapping joints at the joint portion).

4 /, afcw (Fig. 5).

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DISCLOSURE

COPIES

61 443 / DB

S.B.G. & K.

International Patent Office

H-1062 Budapest, Anürássy út 113. Phone: 34-24-950, Fax: 34-24-323 //

Masonry stone and process for its production

SCHMIDT, Volker,

STEENHEUER, Clemens,

ISERNHAGEN, DE SCHÖPPINGEN, DE

Date of filing: 1995th 10th 20th PRIORITY: 1994. 10th 22. (P 44 37 885.8-25) DE 1994. 11th 25. (G 94 932.3) DE

FIELD OF THE INVENTION The present invention relates to masonry stone and a process for its production. It is known that the masonry is provided with insulating layers on the outside and / or on the inside for a subsequent separate session.

It is an object of the present invention to provide a masonry stone with which the masonry and masonry insulation can be made in one session and / or the masonry stone and the insulator are made of the same material.

It is a further object of the present invention to provide a suitable process for making such masonry units.

According to the present invention, this object is achieved with respect to the masonry stone by providing the masonry stone with a composite insulating compound.

In a preferred embodiment of the invention, the masonry stone is formed as a masonry stone with at least one side insulating layer or insulating plate.

Preferably, the masonry stone is provided with grooves on at least one side in which the insulating layer or insulating sheet is secured by joints in the insulating layer or insulating sheet which complement the grooves.

The grooves are preferably dovetail grooves, T-grooves or oblique grooves.

Preferably, the insulating material, the insulating layer, or the insulating board consists of mineral foam.

Preferably, the foam material is a foam material.

The masonry stone is preferably natural stone or artificial stone.

The masonry stone is preferably clay brick.

The masonry stone is preferably perforated brick or stoneware brick.

The perimeter channels of the perforated brick are preferably constructed as Thornyos with open T-bridges extending into the outer surface.

The holes are preferably molded with foam material.

Preferably, the insulating layer or insulating sheet on the edge side has a planar surface for mutually adhering the insulating layers or insulating sheets between adjacent composite masonry units.

Preferably, the insulating layer or insulating sheet on the flank side is formed with grooves and joints for grouting joints between the insulating layers or insulating sheets between adjacent composite masonry units.

Preferably, the insulating layer or insulating board has a stepped recess along one of the opposing sides and a projection complementary to the stepped recess on the opposite side to overlap the insulating layers or insulating panels between adjacent composite masonry units.

Preferably, one of the opposing side edges of the insulating layer or insulating sheet protrudes a distance from the edge of the masonry stone and is positioned backward to the size of the projection to effect overlapping of the opposite side edges.

The task with respect to the method of making masonry stone is solved by the following steps:

a) making a masonry block,

b) working the grooves in the roughest part,

c) applying a flowable, raw mineral foam insulating layer to the side of the masonry unit with grooves,

d) drying the composite blank obtained in the previous step from the masonry block and the foam insulation layer,

e) incinerating the dried composite blank,

f) optionally planing and calibrating the foam insulating layer.

Preferably, the insulating layer is applied to a blank which has already been dried and / or burned, and then dried and / or burned together with a previously dried and / or burned blank.

At least when the foam material is applied and the composite blank is dried, the form applied to the masonry blank is used.

The present invention provides a composite masonry stone consisting of a conventional masonry stone and an insulating layer, whereby the usual additional and costly insulation of masonry can be omitted. The thickness of the insulating layer can be selected arbitrarily according to the particular application. The composite masonry stone can be masonry as well as a normal masonry stone and / or combined with a slurry mortar or the like and provided with an integrated insulating layer of plaster or facade brick.

The groove joint creates an insoluble bond between the masonry stone and the insulating layer. It is particularly advantageous to use foam as an insulating layer on the composite masonry and on the other hand masonry bricks. Thus, the complex masonry stone can be made as a whole in one session. The material of the masonry stone and the insulating material may be the same, for example clay.

It is particularly advantageous to use perforated bricks, since their surface-side channels only need to be provided with one longitudinal recess, for example for a T-bridge to form a T-groove. This should be done when producing the blank.

The production of composite masonry stone is not a problem in the case of masonry bricks, since the raw material of the foam material is to be applied to the brick blank with grooves only with the desired thickness, with or without shape. The foam material enters the grooves and additionally binds to the brick blank. The brick blank and the applied foam are then dried and co-fired together. Subsequently, the insulation layer can be further ground and calibrated if necessary. With suitable material selection, the masonry stone and the insulating layer can be dried and fired together, for example, if both the masonry stone and the insulating layer are clay.

In a preferred embodiment of the invention, using a high-hole clay brick, the brick is cast with foam clay as an insulating material and dried and co-dried with the foam clay.

The insulating layer may be formed at the side edges for grooved or overlapping joints to provide better insulation effect than the joint portion of the masonry stone.

The thickness of the joint between the masonry stone and the insulating material can be different, thus ensuring an optimal combination of noise protection and heat protection. Our invention by way of example! Embodiments of the invention will be described in more detail by means of the drawings, of which

Figure 1 is a first embodiment of a composite masonry stone consisting of a masonry stone and an insulating layer,

Fig. 2 is a second embodiment of a composite masonry stone consisting of a masonry stone and an insulating layer,

Figure 3 shows a third embodiment of a composite masonry stone consisting of a masonry stone and an insulating layer,

Fig. 4 is a view showing Figures 1-3; FIG. 1 is a design of the side edges of the insulating layer of the composite masonry stone of FIG

Figure 5 is a view corresponding to Figure 1-3. another embodiment of the side edges of the insulating layer of the composite masonry stone of FIG

Fig. 6 is a view of Figs. FIG. 1A is a further embodiment of the side edges of the composite masonry insulating layer of FIG

Figure 7 is another embodiment of composite masonry stone with insulating material.

1-6. The same parts of the masonry units of FIG.

1-3. Fig. 4a shows a composite masonry stone 2 consisting of a masonry stone 4, for example a masonry brick and an integrated insulating layer 6 on one side thereof. Such an insulating layer 6 can also be formed on the opposite side.

The masonry stone is preferably a perforated brick. Such a perforated brick 7 is depicted in dashed line in FIG.

The masonry 4 has grooves 8, dovetail grooves 8 (Fig. 1), 10 T-grooves (Fig. 2) or oblique grooves 12 (Fig. 3), in which inserts 14, 16 and 18 are arranged on the insulating layer 6 applied to the masonry stone 4. . 1-3. In the case of the composite masonry stone 2 shown in Figs.

At the joints 20 between adjacent masonry units 4, 4 ', the side edges of the insulating layer may be formed for a tongue or overlap arrangement, as shown in Figs. 3B.

Falazókőnél 4 of Figure 4, the side edges in the insulating layer 6 are opposite a groove 22 and a tongue 24 formed to complement 26 tongue and groove joint between adjacent two ^one and two adjacent composite falazókő 6 and 6 'insulating layer. The 24 eaves here are composite _ ··· ·· ·· ·

..............

• * · ♦ ·· ··

- Ί designed as a protrusion from the edge of the masonry stone.

Two versions of the overlapping arrangement for the insulating layer are shown in Figures 5 and 6.

In the embodiment of Figure 5, one of the opposing sides of the insulating layer 6, 6 'has a stepped recess 28 on one side and a complementary stepped projection 30 on the opposite side to form the overlapping arrangement 32 shown in Figure 5.

In the embodiment of Figure 6, one of the opposite edges of the insulating layer, the edge 34 protrudes 36 mm from the edge of the composite masonry stone or masonry stone, and the opposite edge 38 is offset by the size of the projection 36 40 overlapping layouts are created for masonry stones adjacent to the insulating layer.

A suitable mortar or suitable adhesive may be introduced into the joints of the groove joint 26 or the overlapping arrangement 32 and 40.

In the following, a preferred method of producing composite masonry stone 2 consisting of an insulating layer 6 and masonry stone 4 is described.

First, a masonry blank is produced in a conventional manner, preferably a masonry brick, with grooves on the side to be provided with an insulating layer. These grooves can be, for example, dovetail grooves, T-grooves or simple oblique grooves. When making perforated brick blocks, the edge channels only need to be provided with recesses flowing into the surface to form T-grooves.

Thereafter, an insulating layer of flowing raw mineral foam material, preferably foam mass, is applied to the side of the masonry unit with grooves. Optionally, the application is carried out in a mold where there is a risk of the foam being applied to the side of the masonry unit.

Then, the composite raw material obtained from the masonry raw material and the foam material and the foam insulating layer is dried and then burned in the usual manner in the manufacture of the masonry brick. Of course, the foam mass can also be applied to the already dried and fired brick. Then the brick is now dried or burned again with the insulating layer.

After firing, the foam insulating layer is further planed and calibrated if necessary.

To improve the insulating effect of the insulating layer at the joint portion of the masonry stone, the opposing sides of the insulating layer may be provided with an overlapping arrangement or groove joint as shown in FIGS. with reference to FIG. Suitable grooves and gutters, as well as recesses and projections, are preferably formed in a suitable form when applying the mineral foam mass, which remains as a lost form on the composite blank or is removed after the drying process.

Figure 7 shows a masonry stone 4 formed of high-hole brick, preferably high-hole clay, whose holes 7a are filled with foam 6a. Pouring with foam clay can be done on the clay brick blank, then the brick and foam clay are dried and co-fired. Pouring with foam clay can be done on already dried or burned bricks. In this case, the drying is optimal ···! · ........

• · · · · · _ · · · ··································· · · · · · · · · · ·

- 9 foam clay bricks go through the and firing process once more. For a combination of noise protection and thermal protection, the thickness of the joint between the masonry stone and the insulating material may vary.

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Claims (19)

DATA SHEET REQUIREMENTS A masonry stone, formed as a masonry unit made of integrated thermal insulating material, characterized in that at least one side of the masonry stone (4) is provided with an insulating layer (6) or an insulating board (6). Masonry stone according to Claim 1, characterized in that the masonry stone (4) is provided with grooves (8, 10, 12) on at least one side, in which the insulating layer (6) or insulating sheet is joined to the grooves in the insulating layer or insulating sheet. 14, 16, 18). 3. Masonry stone according to one of claims 1 to 3, characterized in that the grooves are dovetail grooves (8), T-grooves (10) or oblique grooves (12). 4. A masonry stone according to any one of claims 1 to 3, characterized in that the insulating material, the insulating layer (6) or the insulating plate is made of a mineral foam material, which is preferably a foam-like material. 5. A masonry stone according to any one of claims 1 to 4, characterized in that the masonry stone is natural stone or artificial stone. The masonry stone according to claim 5, characterized in that the masonry stone is a clay brick. Masonry stone according to claim 5 or 6, characterized in that the masonry stone is a hole brick or a stone sponge. Masonry stone according to claim 7, characterized in that the perforated channels of the perforated brick are formed as T-grooves with open T-bridges extending into the outer surface. * ·· " - 11 Masonry stone according to claim 8, characterized in that the holes are filled with foam material. 10. A masonry stone according to any one of claims 1 to 6, characterized in that the insulating layer (6) or the insulating plate is formed on the edge side with a planar surface for joining the insulating layers (6, 6 ') or insulating plates between adjacent composite masonry stones (2, 2'). 11. A masonry stone according to any one of claims 1 to 4, characterized in that the insulating layer (6) or insulating plate is suitable for grooving (26) the insulating layers (6, 6 ') or insulating plates between adjacent composite masonry stones (2, 2') with grooves (22) and provided with flaps (24). 12. A masonry stone according to any one of claims 1 to 6, characterized in that the insulating layer (6) or insulating plate has a stepped recess (28) along one of the opposite sides and a projection (30) adjacent to the stepped recess on the opposite side. (2, 2 ') for overlapping joints (6, 6') or insulating sheets. 13. A masonry stone according to any one of claims 1 to 4, characterized in that one of the opposite side edges (34) of the insulating layer (6) or insulating plate protrudes a distance (38) from the edge of the masonry stone and the projection (38) ) is placed rearward. 14. A process for producing masonry stone from integrated heat-insulating mass, characterized in that during construction: • ··· * «• * ·« β ·· - Perform the following 12 steps: a) making a block of masonry stone, b) working the grooves in the roughest part, c) applying a flowable, raw mineral foam insulating layer to the side of the masonry unit with grooves, d) drying the composite blank obtained in the previous step from the masonry block and the foam insulation layer, e) incinerating the dried composite blank, f) optionally planing and calibrating the foam insulating layer. Method according to claim 14, characterized in that the insulating layer is applied to a blank which has already been dried and / or burned, and then dried and / or burned together with a previously dried and / or burned blank. Method according to claim 14 or 15, characterized in that at least the foam material is applied and the composite blank is dried, using a sample applied to the masonry blank. The process according to claim 14, 15 or 16, characterized in that the masonry unit consists of clay and the foam material is foam clay. 18. A 14-17. A method according to any one of claims 1 to 3, characterized in that the opposite sides of the insulating layer are provided with a groove and a gutter or a recess for interconnecting the insulating layers of adjacent masonry units with a groove or overlapping. - 13 ··· · THE · • · · 19. A method according to any one of claims 1 to 4, characterized in that the holes of a perforated brick or perforated brick are poured with foam mass and the molded perforated brick or perforated brick is dried and / or burned. The authorized agent ι niipy hénesné is a member of the S.B.G · & K / International Patent Office