EP0882850B1 - Brick, particularly formwork brick or building block - Google Patents

Abstract

The brick has a number of acoustic damping channels (15) in the outer wall (1). The channels (15) run from at least one side of the outer wall (1) inwards, parallel to a long side of the brick. The channels (15) can run from the under side of the outer wall (1) at least vertically upwards and/or from the upper side vertically downwards, in at least two rows.

Description

The invention relates to a stone, in particular formwork or block stone with two longitudinal walls, one Form outer wall and an inner wall, which by at least a transverse wall that is at least one Part of the stone height extends, connected to each other are, the outer wall made of an insulating material is manufactured and by means of positive connection devices with the at least one transverse wall is connected, the inner wall and the at least a transverse wall made of concrete or a concrete-like Material exist, and wherein the outer wall to the Has inner wall directed cross members, which the at least partially enclose at least one transverse wall.

A generic formwork block is for example known from EP 0 751 266. The one in the above Formwork block disclosed has two Longitudinal walls that have an outer wall and an inner wall form. Both longitudinal walls are through two transverse walls connected at right angles to each other. Related to the side faces (face of the outer and the Inner wall), the transverse walls are each slightly behind set inside.

The inner wall and those connected to the inner wall Cross walls are made in one piece from concrete or a concrete-like one Material made while the outer wall made of polystyrene, i.e. an insulating material, is made. The outer wall is in one piece with Cross parts made, which from above over the cross walls of the stone can be put on and thus the Cross walls on all sides, apart from the bottom of the stone shown, isolate.

Further known formwork blocks are in DE-OS 43 18 578 and DE 295 10 640. These formwork blocks also consist of two transverse walls and two longitudinal walls, an outer wall and an inner wall form. The cavity lying between the walls is used for concrete filling. With the previously known Formwork blocks is also an insulation insert provided for thermal insulation.

A disadvantage of known formwork blocks, in particular according to EP O 751 266 is that at certain frequencies Resonances occur that affect the sound insulation affect. That means certain noises or Vibrations outside of the house are evident in the Hear interior.

The present invention is therefore the object based on a stone, especially a formwork or To create a block that is better Sound insulation ensures without the thermal insulation too influence.

This object is achieved in that a large number of sound insulation channels in the outer wall are provided, extending from at least one side the outer wall inwards parallel to the stone long side extend.

In a completely surprising way, the inventor found that with the provision of a variety of Sound insulation ducts in the outer wall provide very good noise insulation is achieved by the resonances that have previously occurred at certain frequencies, be prevented. The thermal insulation is through the However, soundproofing ducts are not reduced.

In a non-obvious development of the invention can also be provided that the outer wall at least in the area of the at least one transverse wall with a variety of at least approximately horizontal extending steam diffusion channels is provided, the from the transverse wall to the outside of the outer wall extend.

Through the vapor diffusion channels, the vapor diffusion clearly improved. The steam that so far between the concrete transverse walls and the outer wall made of an insulating material has formed, can now easily the vapor diffusion channels escape to the outside. The Thermal insulation of the formwork blocks is through the vapor diffusion channels but not restricted.

Advantageous further developments and refinements of Invention are described in the further subclaims.

An embodiment of the invention is based on the Drawing described in principle.

Fig. 1

Eine Draufsicht auf einen erfindungsgemäßen Stein;

Fig. 2

eine Ansicht des Steines der Fig. 1 in Richtung des Pfeiles II;

Fig. 3

einen Schnitt entlang der Linie III-III der Fig. 2;

Fig. 4

einen Schnitt durch den erfindungsgemäßen Stein nach der Fig. 1 entlang der Linie IV-IV der Fig. 3;

Fig. 5

einen Schnitt entlang der Linie V-V der Fig. 3.

It shows:

Fig. 1

A top view of a stone according to the invention;

Fig. 2

a view of the stone of Figure 1 in the direction of arrow II.

Fig. 3

a section along the line III-III of Fig. 2;

Fig. 4

a section through the stone according to the invention of Figure 1 along the line IV-IV of Fig. 3.

Fig. 5

a section along the line VV of Fig. 3rd

As can be seen in FIGS. 1 and 2, the one shown Stone, which is designed as formwork stone, two longitudinal walls, an outer wall 1 and an inner wall 2 form on. The outer wall 1 is with the inner wall 2 through two transverse walls 3 at right angles to each other connected.

The outer wall 1 is made of an insulating material, preferably made of polystyrene. The inner wall 2 and the transverse walls 3 are made of concrete or a concrete-like material.

The outer wall 1 faces the inner wall 2 Cross parts 4, which the two transverse walls 3 each enclose on the side and on the top. The connection the outer wall 1 or the transverse parts 4 with the Transverse walls 3 are made via positive connection devices 5, which in the present embodiment are dovetail-shaped. The Connection devices 5 can of course also have another suitable geometric shape.

Point in their connection area with the inner wall 2 the transverse walls 3 beveled towards the top of the stone or rounded transition areas 6. How 2 and 4 can be seen in that the transverse walls 3 only in the transition areas 6 to open spaces are sufficient to the top of the stone 7. These open spaces 7 serve for later concrete backfilling horizontally in Stone longitudinal direction.

Through the outer wall 1, the inner wall 2 and the two Transverse walls 3, a cavity 8 is created, which also is intended for later concrete backfilling. in the The area of the cavity 8 is located on the inner wall 2 facing side of the outer wall 1 dovetail-shaped projection 9. Through this dovetail-shaped projection 9 is after the Filling concrete a firm connection between the Outer wall 1 with the inner wall 2 and the transverse walls 3 created.

As can be seen from Fig. 1, are located on the End faces of the outer walls 1 connecting devices in the form of recesses 10 and complementary thereto Projections 11. The recesses 10 and the projections 11 are designed such that the projection 11 one Stones in the recess 10 of an adjacent Stones engages and thus a positive Connection of the two formwork blocks is created. As a result, the formwork blocks can be built using the modular system be attached side by side, leaving the free spaces between the formwork blocks next to each other also after creating a wall from formwork blocks be filled with concrete.

As can be seen in Fig. 1 and 2, are on the top and Undersides of tongues 12 or grooves 13 are provided. With With the help of these springs 12 and the grooves 13 can be stack the stones exactly on top of each other. On the outside the outer wall 1 are dovetail-shaped Recesses or vertical grooves 14 are provided a better connection between the outer wall 1 and a basic plaster, not shown, after creation surrender to a wall.

In the outer wall 1 there are a large number of Sound insulation ducts 15. Extend as shown in Fig. 4 the sound insulation channels from the bottom the outer wall 1 approximately vertically upwards and from the top of the outer wall 1 approximately vertically below. The sound insulation channels 15 each extend by a small amount from the top or bottom from beyond the horizontal center of the stone.

As a result, the sound insulation channels 15 overlap Area of the horizontal center of the stone. This overlap can be, for example, 2 to 3 cm. The advantage this overlap is to avoid one massive core in the middle of the stone and thus a reduction sound insulation (see e.g. Fig. 5).

The sound insulation channels 15 are each with holes a diameter of 5 to 20 mm, preferably 10 to 15 mm. The sound insulation channels 15 taper from the top or bottom towards the horizontal stone center. It was found that thereby achieving even better sound insulation becomes.

As can be seen from Figs. 1 and 3, the sound insulation channels 15 arranged in the outer wall 1 that two rows of sound insulation channels 15 from the Top of the outer wall 1 down and two rows of sound insulation channels 15 from the bottom of the outer wall 1 extend upwards. The side by side Rows of sound insulation channels 15 are offset to each other. This ensures that at any Cut perpendicular to the stone longitudinal plane at least one of the sound insulation channels is cut.

By moving the rows next to each other the sound insulation channels 15 become the resonance frequencies heavily subdued. Through the staggered Sound insulation channels 15, it is also possible that the sound insulation channels 15 over the horizontal Extend the middle of the stone without contact with the extending from the opposite side Sound insulation channels 15 takes place. Because of the overlap the sound insulation channels in the area of the horizontal Stone center ensures that no in the middle stable horizontal solid stripe is created. The Number of soundproofing ducts 15 and their arrangement in two rows, from the top and bottom has been brought in regarding production turned out to be particularly advantageous. Of course are also others within the scope of the invention Designs and arrangements for the sound insulation ducts 15 possible.

3 and 4, are located in the Outer wall 1 in the area of the two transverse walls 3 horizontally running vapor diffusion channels 16. These vapor diffusion channels 16 extend from the transverse wall 3 from to the outside of the outer wall 1. Through this Vapor diffusion channels 16 will be excellent Vapor diffusion achieved.

Steam or moisture, which is the case with the previously known Formwork blocks at the points of contact between has formed the outer wall 1 and the transverse wall 3, can easily through the vapor diffusion channels 16 escape. The vapor diffusion can be optimal from the inside to the outside via the transverse wall 3 and the vapor diffusion channels 16 take place. This prevents e.g. when the house dries up due to the high moisture content Points of contact of the transverse wall 3 with the outer wall 1 can form. Even after the house has dried out is a moisture accumulation or the like, e.g. thereby can arise that the house is little ventilated is significantly reduced.

The vapor diffusion channels extend from the Transverse wall 3 from to the outside of the outer wall 1. On the outside of the outer wall 1 are the vapor diffusion channels 16 later e.g. by a not shown Basic plaster after finishing a wall with closed the formwork blocks. The base coat, with which the vapor diffusion channels 16 are closed, However, does not reduce vapor diffusion because it is open to diffusion.

The vapor diffusion channels 16 are linearly side by side in two arranged rows. Every row can, for example, from nine vapor diffusion channels 16 consist. This means that they are located in a formwork block with two transverse walls 3 thirty-six vapor diffusion channels.

As can be seen from FIG. 4, the vapor diffusion channels extend 16 about the height of the transverse wall 3. The Vapor diffusion channels 16 have a diameter of 2 to 10 mm, preferably 3 to 5 mm. Through this Dimensioning of the vapor diffusion channels 16 becomes one ensures optimal vapor diffusion without a noticeable heat loss occurs. In addition, through the selected diameter the stability of the styrofoam not weakened in any way.

The vapor diffusion channels 16 partially intersect with the sound insulation ducts 15. This ensures that the moisture that transports inside out should already be inside the formwork module due to the vapor diffusion channels intersect with the sound insulation channels. This ensures an even better vapor diffusion.

Claims (13)

1. Masonry, especially formwork or blocks, with two longitudinal walls which form an outer wall (1) and an inner wall (2), which are connected together by at least one transverse wall (3), which extends over at least a part of the height of the masonry, the outer wall (1) being manufactured from an insulating material and connected to the at least one transverse wall (3) by means of positive-locking connection devices (5), the inner wall (2) and the at least one transverse wall (3) consisting of concrete or a concrete-type material and the outer wall (1) having transverse components (4) pointing towards the inner wall (2) which at least partially surround the at least one transverse wall (3)
   characterised in that a large number of sound insulation channels (15), which extend, parallel to the longitudinal side of the masonry, from at least one side of the outer wall (1) towards the inside, are provided in the outer wall (1).
2. Masonry according to claim 1,
      characterised in that the sound insulation channels (15) extend at least approximately vertically upwards from the bottom of the outer wall (1) and/or from the top of the outer wall (1), at least approximately vertically downwards.
3. Masonry according to claim 1 or 2,
      characterised in that at least two rows of sound insulation channels (15) are provided, lying parallel to each other.
4. Masonry according to claim 1, 2 or 3,
   characterised in that sound insulation channels (15) from adjacent rows are arranged offset in respect of each other.
5. Masonry according to claim 4,
   characterised in that the offsetting of the rows and the size of the sound insulation channels (15) is selected in such a way that if a cut is made at an arbitrary point vertical to the longitudinal plane of the masonry, at least one of the sound insulation channels is cut through.
6. Masonry according to one of claims 1 to 5,
   characterised in that two rows respectively of sound insulation channels (15) extend downwards from the top of the outer wall (1) and at least two rows of sound insulation channels (15) extend upwards from the bottom of the outer wall (1).
7. Masonry according to claim 6,
   characterised in that the sound insulation channels (15) starting from the top and the bottom of the outer wall (1) are arranged offset in respect of each other in such a way that the sound insulation channels (15) extend from the top or bottom respectively across the horizontal centre of the masonry.
8. Masonry according to one of claims 1 to 7,
   characterised in that that the sound insulation channels (15) take the form of bores with a diameter from 5 to 20 mm respectively, preferably 10 to 15 mm.
9. Masonry according to one of claims 1 to 8,
   characterised in that the sound insulation channels or bores (15) narrow from outside to inside.
10. Masonry according to one of claims 1 to 9,
    characterised in that the outer wall (1) is provided with a large number of vapour diffusion channels (16) running at least approximately horizontally at least in the area of the at least one transverse wall (3), the said channels extending from the transverse wall (3) to the outside of the outer wall (1).
11. Masonry according to claim 10,
    characterised in that at least two adjacent rows of vapour diffusion channels (16) extend at least approximately above the height of the transverse wall (3).
12. Masonry according to claim 10 or 11,
    characterised in that the vapour diffusion channels take the form of bores (16) with a diameter of 2 to 10 mm respectively, preferably 3 to 5 mm.
13. Masonry according to one of the claims 1 to 12,
    characterised in that at least a part of the vapour diffusion channels or bores (16) intersect with the sound insulation channels (15).

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