ES1281112U - Insulating block (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

An insulating block made of foam material, having a set of projections (3) on its lower surface (1), and having a corresponding set of grooves (4) on its opposite upper surface (2), characterized in that Drainage channels (5) are provided on the upper surface (2) of the block, whereby a drainage channel (5) extends through the bottom (6) of each slot (4) and an outlet from each channel drain (5) is located on the edge of the upper surface (2) of the block. (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Insulating block

The utility model refers to an insulating block of foamy material for use as an element for the construction of insulation systems for walls and ceilings of buildings.

Polish patent application P. 283124 discloses a formwork block having two side walls with protrusions and grooves at the ends. They are connected by means of transverse walls in such a way that one of them is arranged in a place where the side walls have grooves. In this way, two chambers are formed within the block: one closed and one open. In their upper parts, the transverse walls have at least one gap formed as close as possible to the upper edge of the side walls to place the horizontal reinforcement. The construction of the walls of the blocks described in the present application consists in inserting, in each layer, the tabs of one block into the grooves of another block.

Furthermore, the Polish utility model PL59898Y1 discloses a building block in the form of a single horizontal layer, similar to a wall, comprising three square holes offset from each other by a constant modulus that constitutes one third of the length of these blocks. The openings are arranged in such a way that in each of the successive horizontal layers of the wall they coincide vertically with each other, forming columnar openings, used to receive vertical reinforcements and to be filled with concrete.

Furthermore, the Polish patent specification PL167039B1 discloses a modular wall element made of gypsum materials for the dry construction of all exterior walls, said element containing at half width a central cylindrical hole between the front walls and two semi-cylindrical openings that extend into the side walls. The side walls are provided with a semi-cylindrical groove and a semi-cylindrical projection, arranged vertically and symmetrically in stripes and placed alternately with each other. Around the central cylindrical hole and the semi-cylindrical holes in the upper part of the element are a projection and semi-projections in the form of two truncated pyramids with rounded side edges, and in the lower part of the element there is a recess and two semi-recesses with dimensions corresponding to the of the overhang and the two semi-overhangs.

Polish patent PL172426B1 discloses a set of masonry blocks, some of them being provided with concave grooved recesses in their front walls, while others with convex walls that can be connected to these grooved recesses. In addition, in a central partition of the complete modular block there is a slot or a hole for introducing a connector designed to connect adjacent blocks.

The technologies and processes of the current state of the art for the construction of insulating layers of walls made of blocks include methods of joining elements "by contact" without the use of mortar, as well as the joining of blocks and bricks by means of a mortar of cement-lime, sealing mass, or by forming a shell, so-called formwork: metal, wood or made of concrete blocks, plaster or other materials that constitute the permanent formwork in place and then concrete is poured into them or they are filled with reinforced concrete or foamed plaster.

However, no solution has been disclosed for a connection system of insulating elements, including in particular blocks made of foamed materials for the construction of insulation systems for walls and ceilings of buildings, that in an easy and effective way allows avoid the accumulation of rainwater or condensation water in the cavities of the upper surfaces of the blocks. During the assembly of the insulating layer in case of rain, it often happens that, despite the use of shields, rain and / or condensation water accumulates in the cavities of the upper surface of the blocks, including the grooves that form part of the block connection system. The presence of water is totally undesirable, both due to the possibility of freezing at negative temperatures (which would cause leaks in the projection-groove connections between the blocks) and due to the possibility of the growth of microorganisms (in particular fungi) in a humid environment. In addition, in order for the dimensions of the insulation system to continue to comply with the given design of the construction, all joints of the hollow blocks must be assembled "by contact", that is, without leaving gaps. In case of accumulation of water in the grooves of the upper surface of the blocks, due to the low compressibility of the water, the lower surfaces of the next layer of blocks mounted from above cannot fully adhere to the upper surfaces of the already mounted blocks . In practice, the differences resulting from the sum of the thicknesses of the water layers in each successive layer of blocks even reached up to 20 cm. For these reasons, it had been desirable to provide an effective, but easily implementable, dewatering system from the cavities in the upper surfaces of the insulating blocks, which has been achieved in the utility model block.

Accordingly, the utility model refers to an insulating block made of foam material, which has a set of projections on its lower surface, and which has a corresponding set of grooves on its opposite upper surface. The block according to the utility model is characterized by the drainage channels provided on the upper surface of the block, whereby a drainage channel extends through the bottom of each slot and an outlet from each drainage channel is located in the edge of the upper surface of the block.

In a preferred embodiment of the insulating block according to the utility model, the drainage channels are arranged parallel to each other.

In another preferred embodiment of the insulating block according to the utility model, the drainage channels extend horizontally and the bottoms of the drainage channels are coplanar with the bottoms of the grooves.

In another preferred embodiment of the insulating block according to the utility model, the bottoms of the drainage channels are inclined with respect to the plane defined by the upper surface of the block.

In a particularly preferred embodiment of the insulating block according to the utility model, the bottoms of all the drainage channels have the same inclination in the same direction. In a particularly preferred embodiment of the insulating block according to the utility model, the inclination of the bottoms of the drainage channels in relation to the plane defined by the upper surface of the block is 0.5% to 5%, preferably 1, 5 %.

In another preferred embodiment of the insulating block according to the utility model, in a top view each groove has the outline of a regular polygon or a circle, preferably a rectangle, and in particular a square.

In another preferred embodiment, the insulating block according to the utility model is a cube or a block composed of several cuboids connected by means of side walls.

Due to the presence of drainage channels, the insulating blocks according to the utility model allow the water to drain from the grooves. In the case of horizontally extending channels having the bottoms coplanar with the bottoms of the grooves, the water drainage is forced when the projections of another block mounted from the top are inserted into the grooves. Under pressure, the water escapes to the outside through the channels drainage. On the other hand, in the case of channels with sloping bottoms with respect to the plane defined by the upper surface of the block, water drainage from the grooves occurs as a result of gravity, and any residual water is removed as a result of the above described assembly of another block fixed from the top.

Thanks to a wide interlocking system formed by the protrusion-groove joints on the upper and lower surfaces of the blocks, the insulating blocks according to the utility model allow to construct the insulation of walls and ceilings of buildings, with a significant reduction, or including the complete elimination, of the height differences of the assembled system resulting from the accumulated water in the depressions of the upper surfaces of the successive layers of blocks. The insulating blocks according to the utility model are assembled in such a way that the outlets of the drainage channels are directed towards the outside of the block and, for aesthetic reasons, are directed towards the interior of the building under construction. In this way, rain or condensation water can be easily and efficiently drained from the upper surfaces of the insulation blocks before or at the latest during the assembly of the insulation systems.

The object of the utility model is shown in the drawing, in which fig. 1 shows a block according to the utility model in a perspective view, fig. 2 shows a simplified perspective view of the upper part of a block according to the utility model, fig.

3a shows a perspective view of a fragment of the upper part of a block according to the utility model, fig. 3b shows a cross section in a vertical plane through a fragment of the upper part of the block of fig. 3a, fig. 4a shows a perspective view of a fragment of the lower part of a block according to the utility model, fig. 4b shows a cross section in a vertical plane through a fragment of the lower part of the block of fig. 4a, fig. 5a shows a top view of the block according to the utility model, figs. 5b, 5c, 5d and 5e show cross sections of the block of fig. 5a along planes A-A, B-B, C-C and D-D, respectively, while fig. 6 shows another preferred variant of the block according to the utility model in a perspective view.

The insulating block according to the utility model has a set of projections 3 on its lower surface 1 (see figures 1, 4a, 4b and 5d), and on its opposite upper surface 2 it has a corresponding set of grooves 4 (see figures 1, 2, 3a, 3b, 5a and 5b). On the upper surface 2 of the block there are drainage channels 5, whereby a drainage channel 5 extends through a bottom 6 of each slot 4 and an outlet of each drainage channel 5 is located on the edge of the upper surface 2 of the block. As shown in figs. 2, 3a and 5a the drainage channels 5 are arranged parallel. The arrows in fig. 2 indicate the direction of water drainage through the drainage channels.

Figures 5a, 5b and 5c show a variant of the block according to the utility model, in which the drainage channels 5 extend horizontally and the bottoms 7 of the drainage channels 5 are coplanar with the bottoms 6 of the grooves 4. Figures 2, 3a and 3b in turn show another variant of the block according to the utility model, in which the bottoms 7 of the drainage channels 5 are inclined with respect to the plane defined by the upper surface 2 of the block. The bottoms 7 of all the drainage channels 5 in the utility model variant shown in figs. 2, 3a and 3b have the same inclination in the same direction.

Preferably, the inclination of the bottoms 7 of the drainage channels 5 with respect to the plane defined by the upper surface 2 of the block is 0.5% to 5%, preferably 1.5%. In a preferred variant of the utility model illustrated in figs. 1, 2 and 3a each slot 4 in top view has the outline of a square. In a preferred variant of the utility model shown in fig. 1 the insulation block is shaped like a cuboid. In another preferred variant of the utility model shown in fig. 6 the insulation block is formed as a block composed of several cuboids connected by means of side walls to an L-shape in top view. Furthermore, the block according to the utility model can be combined with separate elements, as shown in fig. 6.

Claims (8)

1. An insulating block made of foam material, having a set of projections (3) on its lower surface (1), and having a corresponding set of grooves (4) on its opposite upper surface (2), characterized in that Drainage channels (5) are provided on the upper surface (2) of the block, whereby a drainage channel (5) extends through the bottom (6) of each slot (4) and an outlet from each channel drain (5) is located on the edge of the upper surface (2) of the block. The insulating block according to claim 1, characterized in that the drainage channels (5) are arranged parallel to each other. The insulating block according to claims 1 or 2, characterized in that the drainage channels (5) extend horizontally and the bottoms (7) of the drainage channels (5) are coplanar with the bottoms (6) of the grooves ( 4). The insulating block according to claims 1 or 2, characterized in that the bottoms (7) of the drainage channels (5) are inclined with respect to the plane defined by the upper surface (2) of the block. The insulating block according to claim 4, characterized in that the bottoms (7) of all the drainage channels (5) have the same inclination in the same direction. The insulating block according to claims 4 or 5, characterized in that the inclination of the bottoms (7) of the drainage channels (5) with respect to the plane defined by the upper surface (2) of the block is 0.5% 5%, preferably 1.5%. The insulating block according to one of claims 1-6, characterized in that each groove (4) in top view has the contour of a regular polygon or a circle, preferably a rectangle, and in particular a square. The insulating block according to one of claims 1-7, characterized in that it is a cuboid or a block composed of several cuboids joined by means of side walls.