DE2440467A1 - Cavity masonry block with continuous insulation layer - has zigzag continuous layer i block between air chambers - Google Patents

Abstract

The hollow masonry block incorporates a heat or sound insulating material layer which passes from one edge of the block to another. This block is used to provide a continuous insulation layer in a wall. The insulating layer thickness eliminates only one row of air cavities within the building block. The ends of this insulating layer project from the brick edge and form keying features. The insulating layer (2) is parallel to the flat wall and it runs in a zig zag pattern. The zig zag pattern runs between a pattern of insulating air chambers within the hollow brick.

Description

Description of the Invention H o h 1 b 1 o c k s t .e 1. n m i t i s The invention relates to a hollow block with parallel to the wall, from one face to the other and from a bearing surface to the other continuous intermediate layer made of heat and / or sound insulating material, those with corresponding intermediate layers of subsequent, staggered in the association stones of the same type create a closed insulating layer that runs through the entire wall surface form.

Such stones have the purpose of a complete insulation against To cause heat loss and / or sound over the entire wall built from them and the sound and thermal insulation of the masonry built with it usual Significantly improve construction methods.

It is known to have an insulating layer parallel to the wall in a hollow block from the material, with the two separated by the insulating layer Stone parts are monolithically connected by the webs penetrating the insulating layer and furthermore, these webs are opposite to those parallel to the insulating layer extending rows of air chambers dividing transverse webs are arranged offset to the heat conduction path leading through the connecting webs penetrating the insulating layer to make it as long as possible. (DBP 1,708,765.) It has been shown to be desirable that the insulation layer is as thick in its extension perpendicular to the wall surface as is possible. However, on the one hand this has limits due to the static requirements Resilience, on the other hand, must have enough space for parallel to the insulating layer Rows of air chambers remain. It is advisable to have at least two rows next to each other to provide air chambers in order to arrange their transverse webs offset from one another, so that as long a heat conduction path as possible over this cross webs and the longitudinal walls the air chambers is created. From a certain width of the insulating layer on however, it is no longer possible to accommodate more than one row of insulating chambers in the stone.

The object of the invention is therefore to provide an embodiment of the hollow block to find where the insulating layer can be wider in its transverse dimension, without relying on more than a series of air chambers to have to do without. Furthermore, care must be taken that the insulating layers in association with similar Stones have closed joints to actually have a closed one over To get the entire wall extending insulating surface.

This object of the invention is achieved in the preamble of the claim 1 specified hollow block design by the characterized in the claims Training solved.

An embodiment of the invention is shown in the drawing and is described in more detail below. 1 shows a horizontal section by a hollow block according to the invention in plane I - I in Fig. 2 Fig. 2 two similar hollow blocks according to the invention resting on one another in a continuous Vertical section, with the upper stone in plane II - II in Fig. 1 and the lower Stone in plane IIa-IIa in Fig. 1 is cut.

The hollow block shown has a horizontal section in Zigzag line guided isolation chamber (1), from storage area to storage area goes through and in a completely filling insulating layer (2) made of foamed Plastic, such as polystyrene or polyurethane, is introduced, with cavities or crevices between the body of this insulating layer and the insulating chamber walls are avoided in order to exclude the formation of condensation or disruptive air convection. Seven kinks in the insulating layer are provided over the length of the stone, so that when moving stones of the same type in association by half a stone length each time the insulating layers and their walls with the stones adjoining the top and bottom always come to cover. The inner walls of the insulating chamber are in their height extension (1) vertical. The insulating layer (2) is penetrated by connecting webs (3, 4), the two stone halves (4, 12) separated by the insulating layer (2) monolithically associate. The cross-section is as small as possible for static reasons is held in order to limit the heat flow passing through them. In the bigger one the stone part (4) facing the inner wall side are two rows parallel to the wall provided by air chambers (5, and 6). While the air chambers (5) essentially are rectangular, the air chambers (6) have walls directed towards the insulating chamber (7), which run parallel to the kinked inner wall of the insulating chamber (1). The insulating chambers (6) are separated by intermediate webs (8) and on the front side by the walls (9) limited. The intermediate webs (8) and the walls (9) lead into the corners (10, 11) reentering in the direction of the air chambers (6) of the after the insulating chamber (1) facing walls (7) to the heat conduction over the webs (8) and to extend the end walls (9) as much as possible. By doing smaller stone part (12) facing the wall side are in the indentations (13) the insulating chamber (1) more Air chambers (14, 15) are provided. The insulating chambers (6) adjoining the front wall (9) and the front side outer isolation chambers. (15) in the smaller stone part (12) are in front of the approach put the. Connecting webs (3 and 4) on the walls of the insulating chamber (1.) and thus prevent direct heat transfer via the connecting webs (3).

The insulating layer itself does not have a greater transverse extent than before well-known wall-parallel insulating layers, but is due to their respective inclination to the wall surface the heat conduction path penetrating perpendicularly to the wall surface is considerable extended. An insulating layer with a thermal conduction path that corresponds to this extended heat conduction path Thickness could be in a hollow block of the same transverse dimension in the usual wall-parallel arrangement cannot be accommodated without relinquishing a number of air chambers (5 or 6). There would then be the advantage of the offset arrangement of the intermediate webs the rows of air chambers (5 and 6) are lost, and a direct heat flow from the The result would be the interior wall of the stone to the insulating layer (2).

The arrangement according to the invention also results from the enlargement the load-bearing surfaces of the stone due to the inclined position of the insulating chamber walls increased static »stability without reducing the number of air chambers or the heat-conducting stone parts would be shortened and without the transverse dimensions the chamber walls would have to be enlarged. From the static conditions therefore corresponds to the stone according to the invention with such a an insulating layer that is less than half the transverse dimension than it is possible according to the arrangement according to the invention.

To ensure a secure joint seal of the insulating layer of the invention To achieve hollow blocks in the association, the insulating layers are both in each case front and bearing side connected like a tongue and groove. There is one for each Bearing and one end face of the insulating layer with one the entire length of the edge continuous edge-parallel projection (16) with a triangular cross-section with inside provided lying base, the other end and bearing surface of the insulating layer with a corresponding groove (17) with a triangular cross-section.

The cross section of the projection (16) preferably has a more obtuse one Angle (18) as the angle (19) of the cross section of the groove (17).

- patent claims -

Claims (7)

Patent claims i Hollow block with wall-parallel running, of one end face to the other and from one bearing surface to the other continuous Intermediate layer made of heat and / or sound-absorbing insulating material, with the appropriate Intermediate layers of adjoining stones of the same type staggered in a bond thereby forming a closed insulating layer extending through the entire wall characterized in that the insulating chamber (1) filled with the insulating layer (2) is formed zigzag in the direction parallel to the wall. 2. hollow block according to claim 1, d a d u r c h ge k e n n z e i c h n e t that the stone parts (4, 12) connecting the insulating chamber (1), the insulating layer (2) penetrating connecting webs (3) between the two Stone parts (4, 12) provided air chambers (6, 14, 15) are arranged. 3. hollow block according to claim 1, 2, characterized in that the inner walls (7) of the row of the insulating chamber (1) adjacent air chambers (6) with the zigzag line of the adjoining inner wall of the insulating chamber (1) runs parallel and that the air chambers (6) separating the intermediate webs (8) and the walls (9) delimiting the insulating chamber (6) at the end in the direction corners (10, 11) reentering away from the air chambers (6) to the insulating chamber (1) lead to the facing inner wall (7) of the air chambers (6). 4. hollow block according to claims 1, 2, 3, characterized in that that the zigzag line of the insulating chamber (1) over the length of the stone at equal intervals has seven kinks. 5. hollow block according to claim 1, 2, 3, 4, characterized in that that it has two parallel rows of air chambers (5, 6) on one side of the stone, wherein the air chambers' 6) of a row separating transverse webs (8) to the Air chambers (5) of the other row separating transverse webs (8) offset from one another are. 6. hollow block according to claim 1, 2, 3, 4, 5, characterized in that that the air chambers (14, 15) on a stone side (12) in the re-entrant corners the insulating chamber (1) are arranged. 7. hollow block according to claim 1, 2, 3, 4, 5, 6, a a d u r c h g e it is not noted that one end face and one bearing side of the insulating layer (2) have edge-parallel projections (16) with a triangular cross-section and the other end and bearing side of the insulating layer (2-) corresponding grooves (17), wherein the edge angle of the projections (16) is more obtuse than that of the grooves (17).