EP0561390A1 - Buildingblock for electroinstallation - Google Patents

Abstract

In a cuboidal building block (6) for erecting a masonry structure (1), the intention being to provide load and data lines in the masonry structure (1), the arrangement is such that the building block (6) has at least one prefabricated groove (9) for receiving the load and data lines. <IMAGE>

Description

The invention relates to a cuboid block for the construction of masonry according to the preamble of claim 1.

Due to the human striving for more convenience in the private sector and the increase in productivity in the business sector, more and more electrical and electronic devices are being used that serve this purpose. On the one hand, these devices must be connected to a voltage source in stationary operation, but on the other hand must also frequently be connected to one another for the purpose of data exchange. For this purpose, connecting lines are usually provided, which are laid in closed rooms in the masonry that forms the room.

If such a room is to be newly built or is to be equipped with such lines at a later date, channel-like recesses in the form of slots must be provided in the masonry, in which the lines can be laid. For this, the masonry with suitable tools, For example, a milling machine to be held by hand or, in the simplest case, worked with a hammer and chisel to make suitable slots. These slits then often run horizontally along the side walls, so that, for example, because the current building regulations prohibit the horizontal slitting of masonry with a cross section width of only 115 mm, applicable building regulations are violated.

The subsequent production of suitable slots, for example with the milling cutter mentioned, also leads to considerable dust and noise pollution for the operating personnel. For this reason, the use of this milling cutter is often omitted and the slot is made with a hammer and chisel. It is in the nature of things that a slot made in this way with a hammer and chisel does not run in a straight line, moreover, because of the undefined slot, a large amount of building rubble accrues and this ultimately leads to an avoidable environmental impact. In addition, vibrations of the still new, unset masonry are unavoidable when making the slot with hammer and chisel, so that this has a negative impact on the building structure.

Both the milling of the slots and their manufacture with a hammer and chisel, since the latter in particular takes place in an undefined manner, leads to the destruction of the pores of the brick building blocks which are generally used in construction. As a consequence, this leads to a negative influence on the thermal conductance of the brick blocks, since heat-conducting nests are created by destroying the pores. Since the striking or milling of the slots is also time-consuming and labor-intensive, often only a single slot is made, in which the load and data lines are then laid together, with the result that interference occurs in particular with the data lines.

The invention is therefore based on the object of eliminating the disadvantages, to create a brick for the construction of masonry, which on the one hand prevents mutual interference of the load and data lines to be laid and on the other hand allows a locally defined laying of these lines.

To achieve this object, the invention has the features specified in claim 1. Advantageous refinements of this are described in the further claims.

The invention is essentially based on the idea of providing a groove suitable for later accommodation of the load and data lines during the manufacture of the building blocks, so that the later milling or slitting of the walls, which would otherwise be necessary in construction, is eliminated.

For this purpose, the module created according to the invention has at least one prefabricated groove for receiving the load and data lines, the groove being advantageously provided on an outside of the module.

In an expedient embodiment, the groove is provided on an outer rare surface of the module, and to a large extent parallel to the longitudinal axis of the module. The groove can of course be arranged at any height on the side surface of the block.

It is therefore necessary to create the groove in the masonry necessary for the later inclusion of the load and data lines by simply bricking a row of the building block created according to the invention at the desired distance from the floor. By lining up the building blocks in the direction of the longitudinal axis of the masonry, a channel-like groove is created in which, for example, the load lines are to be received. It is therefore possible to comply exactly with the prescribed cable routing height. This is also due to this Defined later on during construction where the individual lines run.

Finally, it is also possible to produce two grooves which run separately from one another and lie one above the other in that only two rows of the module according to the invention are walled one above the other. This makes it possible to lay the load line in the lower groove, for example, and to provide the data line in the upper groove, spatially separated from the load line. Interference with the data line by the load line is therefore excluded.

In an embodiment of the block according to the invention, this can also be achieved in that the groove is provided in the region of the cutting edge of the upper and / or lower mortar surface and one or both longitudinal outer side surfaces of the block. The module thus has the advantage that the groove lies in the region of one of the corner regions running in the direction of the longitudinal axis of the module. This groove can therefore be provided, for example, only in the area of a cut edge or in any combination on up to four cut edges.

This is advantageous if load and data lines are to be laid on both sides of the masonry. Advantageously, a defined groove is generated by the configuration of the module according to the invention, which already specifies the later course of the lines to be installed and, moreover, makes it possible to eliminate the dirty work otherwise required on the construction site for producing the slots. As a result, there is far less dirt accumulation and considerable environmental relief, since the amount of building rubble is significantly reduced. Ultimately, this also leads to a reduction in the cost of laying the cable, since the time required for hammering or milling the groove is eliminated.

In a further development of the invention, it is provided that the groove is arranged on an outer face of the module. The groove can run largely parallel to the transverse axis of the building block or also largely perpendicular to this axis. In the latter case, it is advantageous if the groove is arranged in the region of the cut edge between the end face outer surface and a longitudinal side outer surface of the module. However, it can also be arranged largely at right angles to the transverse axis of the building block at any distance from the cutting edge between the outer face of the end face and a long side outer face of the building block. This arrangement of the groove in the region of the cut edge between the end face outer surface and a longitudinal side outer surface of the module is then advantageous when it is necessary to arrange the load and data line in a vertical manner in the masonry, for example in front of a door to be provided.

In an embodiment of the invention, it is finally also possible to provide a groove combination on the module such that one groove runs parallel to the longitudinal axis of the module and a second at a right angle parallel to an outer face of the module. In any case, the groove has a depth suitable for receiving the load and data lines.

The design of the module according to the invention also ensures that the vibrations acting on the new masonry from the known hitting of the slots are avoided. The building structure is no longer weakened by the elimination of the known milling or hammering. The thermal insulation of the masonry remains fully intact because the pore pattern is not destroyed by the known hitting of the grooves. Due to the spatial separation of load and data lines, there is no mutual interference between the lines. The for receiving the load and data lines in the masonry necessary groove is automatically created by simply bricking the stones in the manufacture of the wall.

Ultimately, it is also advantageous that in the case of bypassing a large window area extending to the floor area of the room, the groove in the masonry is simply produced by bricking blocks according to the invention with a vertically extending groove to the side of the window area, and Such modules are used above the window area, the groove of which runs in the longitudinal direction of the module.

Fig. 1

perspektivisch und schematisch einen Teil eines Mauerwerks einer Innenwand mit dem erfindungsgemäßen Baustein;

Fig. 2

im Querschnitt ein Anordnungsbeispiel des Bausteins in einer ersten Ausführungsform sowie

Fig. 3

in einer zweiten Ausführungsform;

Fig. 4

eine Darstellung ähnlich Fig. 1;

Fig. 5

ein Anordnungsbeispiel des Bausteins nach Fig. 4 in einer dritten Ausführungsform sowie

Fig. 6

in einer vierten Ausführungsform ;

Fig. 7

ein weiteres Anordnungsbeispiel des Bausteins;

Fig. 8

eine abgewandelte Ausführungsform des Bausteins;

Fig. 9

vergrößert im Detail eine andere Ausführungsform der Bausteinnut;

Fig. 10

eine weitere abgewandelte Ausführungsform der Bausteinnut in Form einer Durchgangsbohrung und

Fig. 11

eine gegenüber Fig. 10 abgewandelte Ausführungsform des Bausteins.

The invention is explained in more detail below with reference to the drawing. This shows in

Fig. 1

perspective and schematic of part of a masonry of an inner wall with the building block according to the invention;

Fig. 2

in cross section an arrangement example of the module in a first embodiment and

Fig. 3

in a second embodiment;

Fig. 4

a representation similar to FIG. 1;

Fig. 5

an arrangement example of the block of FIG. 4 in a third embodiment as well

Fig. 6

in a fourth embodiment;

Fig. 7

another arrangement example of the block;

Fig. 8

a modified embodiment of the block;

Fig. 9

enlarged in detail another embodiment of the block groove;

Fig. 10

a further modified embodiment of the block groove in the form of a through hole and

Fig. 11

an alternative to Fig. 10 modified embodiment of the block.

As can be seen from Fig. 1, the masonry 1 shown has a wall thickness of ex. 115 mm from a large number of blocks 2 arranged side by side or one above the other. These have butt joint teeth 4 arranged on their end faces 3. This toothing 4 engages in each case with butt joint toothing 4 of the adjacent module 2. The masonry 1 is produced in that mortar is applied to the upper mortar surface 5 of each brick row and the next brick row is arranged thereon.

As can be seen from FIG. 1, this next row of building blocks in the exemplary embodiment shown consists of building blocks 6, each of which has a groove 9 arranged in the region of the cutting edge of one side surface 7 of the building block 6 and its upper or lower mortar surface 8. This groove 9 accordingly extends in the longitudinal direction of the masonry and is formed in that an upper row of masonry formed from blocks 6 is arranged on the lower row of brickwork formed from building blocks 2.

On this upper row of masonry formed from building blocks 6, mortar is then applied to the mortar surface 8 and the next row of building blocks 2 is arranged thereon. The groove 9 then has a depth suitable for receiving load and data lines, so that these lines can be laid in the groove 9.

This takes place in an advantageous manner, as can be seen from FIGS. 2 and 3, in spatially separate grooves 9, such that mutual interference between the lines is avoided.

As can be seen from FIG. 2, the lower groove 9 in the exemplary embodiment shown has a clear height which corresponds to twice the clear height of an individual groove 9. This is achieved in that the lower block 6 with its mortar surface 8 opposite the groove 9 is arranged on the schematically represented reinforced concrete ceiling 10. Then a second building block 6 is arranged in mirror image of the first building block 6 on its mortar surface 8. This arrangement is advantageous if a load line with a large cross-section is to be laid in the lower groove 9.

The arrangement shown in FIG. 3 differs from the arrangement according to FIG. 2 in that the block 6 has a groove 9 in the area of the two cut edges of its one side surface 7 and the upper and lower mortar surface 8.

The masonry 1 shown in FIG. 4 consists, similar to the masonry according to FIG. 1, of a lower row of building blocks 2, a row of building blocks 6 arranged thereon and a row of building blocks 2 again arranged thereon, etc. As shown in FIG. 4 in connection with 6 shows, the building blocks 6 each have grooves 9 arranged in the area of the cut edges of the two side surfaces 7 with the upper and lower mortar surfaces 8. This arrangement is advantageous, for example, when load and data lines are to be separated and provided on both sides of the masonry.

An arrangement similar to this is shown in FIG. 5, the second or third row of masonry respectively consisting of building blocks 6 which are in the region of the cut edges have 8 grooves 9 between the left and right side surface 7 and the respective lower mortar surface.

The arrangement shown in Fig. 7 shows a further arrangement example with two grooves 9 in blocks 6 with 365 mm wall thickness, these grooves 9 being achieved in that two blocks 6 are arranged one on top of the other, each only only in the area of the cut edge between the longitudinal side outer surface 7 and the lower mortar surface 8 have a groove 9.

In the modified embodiment shown in FIG. 8, the groove 11 of each module 6 is designed in such a way that it has an acute-angled cross-section tapering into the module interior. For this purpose, the bottom 12 of the groove 11 is inclined inwards, i.e. sinking, flowing. This provides the essential advantage that no additional or separate brackets are required for the lines to be received in the groove 11.

In the modified embodiment according to FIG. 9, the module 6 has such a groove 13, which likewise has a cross section that tapers into the interior of the module. Here, however, the walls of the groove 13 are curved in the manner shown. This also has the advantage that the desired lines 14 can be received in the groove 13 without additional brackets for the lines 14 being required.

In the further modified embodiment according to FIG. 10, the design is finally made such that the groove provided in each module 6 is designed as a longitudinal through bore 15. As shown, this is designed to be closed in the longitudinal direction and thus has only two open ends with which it, Seen in the longitudinal direction of the wall, adjacent to the adjacent building blocks 6. The advantage of this training is above all that lines 14 can also be retrofitted. In addition, the respective surface of the block 6 is completely closed, so that - in contrast to the previously described embodiments - no subsequent closing of the block surface is required.

As can finally be seen from the further modified embodiment according to FIG. 11, two through holes 15 are provided in each of the building blocks shown there, which run at a distance from one another in the longitudinal direction of the building block 6 in the interior of the building block - and at a relatively short distance from the outer surface of the building block.

Claims (21)

Rectangular block for the construction of masonry, installation load and data lines must be provided in the masonry (1),
characterized,
that the module (6) has at least one prefabricated groove (9) for receiving the load and data lines. Module according to claim 1, characterized in that the groove (9) is provided on an outside of the module. Module according to claim 1 or 2, characterized in that the groove (9) is provided on a longitudinal outer side surface (7) of the module (6). Module according to one of claims 1 to 3, characterized in that the groove (9) runs largely parallel to the longitudinal axis of the module. Building block according to one of claims 1 to 4, characterized in that the groove (9) is provided at any height of the longitudinal outer side surface (7) of the building block (6). Building block according to one of claims 1 to 5, characterized in that the groove (9) is provided in the region of the cutting edge of the upper and / or lower mortar surface (8) and one or both longitudinal outer side surfaces (7) of the building block (6). Building block according to one of claims 1 to 6, characterized in that the groove (9) in the region of the cutting edge of the upper and / or lower mortar surface (8) and a longitudinal outer side surface (7) of the building block (6) and the upper or lower cutting edge between the other longitudinal side outer surface (7) and the lower or upper mortar surface (8) of the block (6) is provided. Module according to claim 1 or 2, characterized in that the groove (9) is provided on an end face outer surface (3) of the module (6). Module according to claim 8, characterized in that the groove (9) runs largely parallel to the transverse axis of the module. Building block according to claim 8 or 9, characterized in that the groove (9) is provided at any height of the outer face of the stoning side (3) of the building block (6). Building block according to one of claims 8 to 10, characterized in that the groove (9) is provided in the region of the cut edge between the outer face surface (3) and the upper and / or lower mortar surface (8) of the building block (6). Module according to claim 1 or 2 and 8, characterized in that the groove (9) is provided largely at right angles to the transverse axis of the module. Building block according to claim 12, characterized in that the groove (9) is provided at any distance from the cutting edge between the end face outer surface (3) and a longitudinal side outer face (7) of the block (6). Building block according to claim 12 or 13, characterized in that the groove (9) is provided in the region of the cutting edge between the end face outer surface (3) and a longitudinal side outer face (7) of the block (6). Building block according to one of claims 1 to 14, characterized in that a combination is provided between a groove (9) arranged on an outer face (3) and an outer face (7) of the building block (6). Module according to one of claims 1 to 15, characterized in that the groove (9) has a depth suitable for receiving the load and data lines. Module according to one of claims 1 to 16, characterized in that the groove (11, 13) of each module (6) has a cross section tapering into the module interior. Building block according to claim 17, characterized in that the groove (11) has an acute-angled cross section. Building block according to one of claims 1 to 18, characterized in that the bottom (12) of the groove (11, 13) is inclined obliquely inwards, i.e. descending, runs. Module according to one of claims 1 to 19, characterized in that the groove is designed as a longitudinal through bore (15) in the module (6). Building block according to claim 20, characterized in that the through hole (15) is closed in the longitudinal direction and is only open at its two ends.

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