AT400458B - PERFORATED BRICK - Google Patents

Description

AT 400 458 B

The invention relates to a perforated brick with continuous walls running along its circumference and between the walls arranged channels that run vertically in the installed position of the brick, of which several are arranged between the walls in both main directions of the base or top surface. 5 Such perforated bricks are mostly used for walls in which a high degree of thermal insulation and at the same time a high degree of sound insulation is achieved with little effort, or a formwork line through the wall should be largely avoided. These two requirements, e.g. When building houses, but also when building industrial halls and offices, they are mutually exclusive and require mutually exclusive measures. So it is very important to achieve a substantial reduction in the heat flow through a wall that the bricks contain as much air as possible. On the other hand, it is essential for the wall to be largely prevented that the brick used has a mass which is as large as possible in order to largely reduce vibrations of the brick which are caused by the impinging sound waves.

In the case of the previously known perforated bricks of the type mentioned at the beginning, in which the thickness of all T5 walls is essentially the same, there is usually good thermal insulation, but this is associated with the disadvantage of a rather inadequate prevention of the passage of sound.

A brick for better insulation was known for example from DE-PS 860 709, but the thickness of the wall, which is free of breakthroughs, is rather greater in the area of the long sides of the brick than in the area of the two narrow sides of the brick. 20 This has the disadvantage that the brick does not prevent the formwork line.

From DE-PS 820 801 an artificial stone has become known, the two halves of which are made of different materials, and which has two channels surrounded by a wall.

The disadvantage of this artificial stone is the complex production due to the use of different materials, and a low level of sound insulation resulting from the two large-volume channels 25.

AT-PS 381 532 describes a hollow block that does not have any continuous side walls. Has chambers with an arcuate cross section for better thermal insulation.

This hollow block is also disadvantageous in that, due to the design, it does not guarantee sound insulation. 30 The aim of the invention is to propose a perforated brick of the type mentioned, in which both the heat and the formwork are largely reduced.

According to the invention this is achieved in that at least one essentially plate-shaped zone extending parallel to the walls provided for receiving the plaster layers over the entire cross-section of the brick with a substantially greater density and / or a significantly lower density than the other areas of the brick Perforated portion is provided, the thickness of this plate-shaped zone being considerably greater than the thickness of the walls extending perpendicular to this.

In this way, a relatively large proportion of the mass of the brick is concentrated in the area of this zone. As a result, the passage of sound through such a brick is significantly reduced. Its thermal conductivity is only slightly influenced by this measure and is essentially determined by the thickness of the webs and transverse ribs, which can be arranged in a conventional manner, and by the proportion of voids in the brick.

A wall erected from the bricks according to the invention has a substantially higher bending stiffness than a wall erected from the conventional high-bricks, which have walls with only a relatively small thickness and a continuous area between them with a relatively uniform, high proportion of holes. This means that when sound waves hit the zone, which has a much higher density due to the smaller number of holes, the structural response of the wall to the Schailan excitation is significantly lower than that of a wall made of conventional perforated bricks, which results in significantly improved sound insulation. So in the sense of a substantial reduction of the formwork line by the brick, it is advantageous if the zone having the higher density is at least twice, preferably three to four times the thickness of the walls and, or or eight to ten times the thickness of the channels from each other separating webs.

In this way, there is an extensive concentration of the mass of the brick in this zone, 55 which can also be arranged in the areas directly exposed to the sound, thereby ensuring appropriate sound insulation. In addition, due to the very uneven distribution of the masses of the brick, the occurrence of resonance phenomena is largely avoided, as a result of which relatively uniform sound insulation properties 2 are obtained over the relevant frequency range

AT 400 458 B.

The brick can enclose a relatively large volume of air and thus largely reduce the flow of heat.

In this regard, it can further be provided in a brick according to the invention with channels which are separated from one another by transverse ribs passing from side wall to side wall and webs connecting them to one another, that several openings are arranged in the zone which has a greater density or a smaller hole portion are, the cross-sectional area of each of these, preferably circular openings is significantly smaller than the cross-sectional area of each channel.

According to a further feature of the invention, it can be provided that the zone with a higher density is arranged between the walls provided for receiving the plaster layers.

Such an arrangement facilitates the subsequent installation of lines in a wall made from such bricks, since only the relatively thin walls and the even thinner webs of the brick have to be pried open, which requires only little effort.

In the case of an eccentric arrangement of the zone having a higher density, the bricks can be laid when bricking up a wall in such a way that these zones of the bricks lying in superimposed shares are offset from one another, which results in a further improvement in sound insulation. For different applications and under certain conditions, however, it is more favorable if the zone with a higher density is arranged in the middle between the walls provided for receiving the cleaning slabs.

This measure gives the advantage that the load-bearing capacity of a wall made from such bricks is greater, since in such a case the denser sections of the bricks will surely lie one on top of the other, but the advantage of the possibility of subsequently removing such a brick Wall remains intact. - ·

Basically, it is also possible. to arrange a zone with a higher density directly on one or both of the walls intended to hold the plaster layers or to integrate them into this wall (s) by having a correspondingly greater thickness than the other walls of the brick. Even with such a design, there is a significant improvement in the sound insulation properties compared to the conventional perforated bricks. In the case of an arrangement of zones with an increased density or a reduced proportion of holes on both walls provided for the admission of plaster layers, the brick is particularly stiff and thus a particularly extensive sound insulation.

The invention will now be explained in more detail with reference to the drawing. It shows:

1 shows a first embodiment of a brick according to the invention in plan view,

Fig. 2 to 4 further embodiments of bricks according to the invention in plan view.

The tile according to the invention according to FIG. 1 has a continuous, closed wall, which enclose an area provided with channels 4 continuous in the vertical direction. Furthermore, zones 2, 2 'are provided which extend from side wall 3 to side wall 3' and over the entire height of the brick and which have an increased density or a smaller proportion of holes than the area of the brick enclosed by the wall. These zones 2, 2 'simultaneously form the load-bearing walls 2, 2' provided for the application of plaster layers on their outer surfaces 1, 1 '. These essentially plate-shaped zones 2, 2 'have a considerably greater thickness than the other walls 3, 3'.

The separation of the individual channels 4 from one another is provided by the transverse ribs 5, which extend essentially parallel to the zones 2, 2 ′ with a reduced proportion of holes, and the webs 6 connecting them to one another in sections. The mutually adjacent cross ribs 5 connecting webs 6 are arranged offset from one another.

Because of the much greater thickness of the zones 2, 2 'compared to the other walls, transverse ribs and webs, they are excited to vibrate much less easily when the sound waves hit than the other sections of the brick. This results in a significantly improved sound insulation.

The relatively large channels 4 which penetrate the brick vertically make the flow of heat through the brick difficult. In order to further reduce this, a number of the channels 4 close to the edge can be designed to be open to the edge at least up to half the height of the brick, a part of these open-toe edges can be designed to be open to the edge in the upper half and others in the lower half of the tile. In this case, such channels alternately alternate with one another. 3rd

Claims (2)

AT 400 458 B Furthermore, in the zones 2, 2 ', which have a greater thickness than the side walls 3, 3' and the transverse ribs 5 and webs 6, openings 7 are arranged which penetrate the brick vertically, but whose cross-sectional areas are considerably smaller than those of the channels 4 . These breakthroughs also contribute to reducing the heat flow through the brick, but without significantly reducing the masses of these zones, so that these breakthroughs do not result in a deterioration in the sound insulation values of the brick. In order to achieve a high degree of sound insulation, the zones 2, 2 'have approximately three to four times the thickness of the walls 3, 3' and, or or eight to ten times the thickness of the transverse ribs 5, 5 '. In the embodiment according to FIG. 2, the brick also has an area with vertical channels 4 enclosed by a dense wall 3, 3 ', 8, 8'. The side walls 3, 3 'have the same thickness as the end walls 8, 8', the outer sides 1, 1 'of which are provided for receiving the plaster layers. In this embodiment, the zone 2, which has an increased density compared to the area of the brick penetrated by channels 4 or a reduced proportion of holes, is arranged eccentrically and parallel to the surfaces 1, 1 'receiving the plaster layers and extends, as in the embodiment according to FIG Fig. 1, from side wall to side wall and over the entire height of the brick. In this embodiment too, zone 2 is penetrated by openings 7 which have only a very small cross-sectional area. In the embodiment according to FIG. 2, in the case of bricks which have already been bricked up, the end regions thereof can be easily pried open due to the small thickness of the walls 8, 8 'in order to be able to subsequently lay lines. The embodiment according to FIG. 3 differs from that according to FIG. 2 in that the zone 2, which has a higher density or a smaller proportion of holes, is arranged centrally between the surfaces 1, 1 'receiving the plaster layers. In this embodiment it is ensured in a simple manner that the denser zones 2 of the bricks lying one above the other in the wall structure come to lie on top of one another, whereby the load-bearing capacity of the bricks can be used to the maximum. In this embodiment, there is also the advantage that a subsequent opening of the wall, e.g. in order to be able to subsequently lay lines easily and with little effort, since only the relatively thin walls 8, 8 'have to be broken through. The latter is just as easily possible in the embodiment according to FIG. 4. This differs from that according to FIGS. 2 or 3 only in that instead of the transverse ribs and webs, which essentially separate rectangular channels from one another, essentially circular cross-sectional areas have vertical channels 9, 10, 11, which are arranged asymmetrically distributed and have different cross-sections. Also in the embodiment according to FIG. 3, zone 2, which has a much smaller proportion of holes, has openings 7 'which, compared to channels 9, 10, 11, have a substantially smaller cross-sectional area than these. The asymmetrical distribution of the channels 9, 10, 11 in connection with zone 2, which has an increased density or a reduced number of holes and extends over the entire cross-sectional area of the brick, results in particularly good sound insulation. 1. Hollow hole brick with along its circumference, continuous walls and arranged between these walls, in the installed position of the brick vertically continuous channels, of which several are arranged between the walls in both main directions of the base or top surface, characterized in that at least one parallel to the walls of the narrow sides provided for receiving the plaster layers, over the entire cross-section of the brick extending parallel to these walls, essentially plate-shaped zone (2, 2 ') with a substantially greater density and / or compared to the other areas of the brick a much smaller proportion of holes is provided, the thickness of this plate-shaped zone being considerably greater than the thickness of the walls running perpendicular to it. 2. Perforated brick according to claim 1, characterized in that the higher density zone at least twice, preferably three to four times the thickness of the walls 2, 2 ', 3, 3') and, or or eight to ten times the thickness the webs (5. 6) separating the channels (4) from one another. 4 AT 400 458 B perforated brick according to claim 1 or 2, with channels which are separated from one another by transverse ribs running from side wall to side wall and webs connecting them to one another, characterized in that in the zone (2 , 2 ') a plurality of openings (7) running parallel to the channels are arranged, the cross-sectional area of each of these, preferably circular, openings (7) being considerably smaller than the cross-sectional area of each channel (4). Perforated brick according to one of claims 1 to 3, characterized in that the zone (2) having a higher density is arranged between the walls (8, 8 ') provided for receiving the plaster layers. Perforated brick according to one of claims 1 to 4, characterized in that the zone (2) having a higher density is arranged centrally between the walls (8, 8 ') provided for receiving the plaster layers. Including 4 sheets of drawings 5