DE3730679C2 - - Google Patents

Description

The invention relates to a cuboid component for he put up by walls with two on opposite sides arranged connecting surfaces, one of the connecting surfaces with at least one groove and the other connecting surface with at least one to cooperate with the groove of another Component specific spring is provided, as well as with at least a first, the two connecting surfaces together end and open cavity at both ends, the middle longitudinal axis intersects the central longitudinal axes of tongue and groove.  

From the magazine "The Builder" dated April 6, 1962, page 693 components are known that are related to their neighboring elements on all contact or connection surfaces through grooves and Springs are toothed. Point to a vertical wall these elements have continuous cavities in the middle that run perpendicular to their horizontal connecting surfaces. You can accommodate supply lines. When building one Wall, these cavities can also be filled with concrete or the like to be a solid link for the transfer of forces to manufacture.

The grooves and tongues of these components serve primarily to center the elements. You can, related on a vertical wall, in the transverse direction and depending on the shape only very limited forces are transmitted in the longitudinal direction since they have very little shape. The stop of the Wall or the elements against each other is made of a fabric conclusive connection achieved using adhesive or mortar. This has in addition to the resulting costs, due to additional material and additional working time, including that Disadvantage that a wall created in this way with a hardened joint not simply dismantled and reassembled can. As a rule, when dismantling such Wall damaged or destroyed the individual components, see above that they cannot be used again. Therefore suitable such components are not for walls or walls that only should be created for a short period of time.

The object of the invention is to provide a component of the ge called to create the forces in a wall network Longitudinal direction and z. B. Tipping moments to be expected during earthquakes Transfer safely in the transverse direction even without mortar or glue a simple laying of supply lines gene allowed. The above object is achieved in that the  Cavity at one end of one across the bottom of the groove or surround and protrude from the outer surface of the spring projecting extension its other end with an inner fitting to the extension Cross-sectional expansion is provided and that tongue and groove in Spread the area of the extension and the cross-sectional expansion tert and with such a narrow tolerance and with such a height as, for example one third of the total height of the component are formed, that arranged in the composite components by a lower Do not let the force directed towards the wall be levered out.

The proposed solution enables supply lines behaves in cavities with respect to the width of the spring large diameter can be easily installed and that the components both in large forces without mortar Can record lengthways and crossways. In particular This prevents parts or a complete row of components according to the invention within a wall network, of the large, due to earthquakes or the like forces are pushed out of the wall network.

In a preferred embodiment there is one according to the invention Pressboard component. This material is light and cheap to manufacture. Components made from it can above all for walls or buildings that are used for only one should be created in one place for a short time. By the poss the components only form-fitting with sufficient Stability can be connected quickly and easily for example, construction huts, show booths or the like be put. Leave through the cavities already provided supply lines in a simple way relocate such buildings. The component can also be made of  be made of any other material, for example from Alumina. Finally, the components according to the invention in model size for models of buildings to be constructed turns or can also be used for game purposes.

Further advantageous refinements and a preferred off management form are explained with reference to the drawing. It shows

Fig. 1 is a perspective view of a device OF INVENTION to the invention,

Fig. 2 is a plan view of a device according to Fig. 1,

Fig. 3 shows a longitudinal section through a component ge Mäss Fig. 1,

Fig. 4 is a plan view of a recess provided with a device according to Fig. 1,

Fig. 5 is a reduced representation of a top view of a T-shaped component,

Fig. 6 is a reduced representation of a plan view of an L-shaped component,

Fig. 7 is a reduced representation of a top view of a cross-shaped component,

Fig. 8 is a reduced representation of a plan view of an arc-shaped component,

Fig. 9 is a reduced view of a plan view of an S-shaped component.

A cuboid component 10 shown in FIGS. 1-3 has the dimensions of a standardized component. However, it can also deviate from these dimensions depending on the intended use. For example, it is conceivable that a component 10 is designed wider for a load-bearing wall or as an intermediate element is only half the size of a standardized building block.

In Fig. 1, the component 10 is shown so that its upper and lower connecting surfaces 12, 14 are parallel to the horizontal. In the middle, it is provided with a vertically extending groove 16 extending from the upper connecting surface 12 . The lower connecting surface 14 has a shape and dimension with the groove 16 corresponding, also ver tical spring 18 . Groove 16 and tongue 18 extend over the entire length of element 10 . They can also run outside the central longitudinal axis of the component 10 . Furthermore, it is possible, depending on the width of the element 10, to provide several grooves 16 and tongues 18 per connecting surface 12, 14 . These can also be combined with one another in the case of a connecting surface 12, 14 . Finally, it is possible that they do not extend in a straight line over the component 10 .

There is a close tolerance between the width of the tongue 18 and the width of the groove 16 . In this way, on the one hand, a safe and positive interlocking connection between two components is produced and, on the other hand, a component from another component cannot be levered out by a force acting vertically on one of its longitudinal sides 26, 28 . In a preferred embodiment, the width of the groove 16 or the tongue 18 is approximately one third of the total width of the construction element 10 . If several grooves or tongues 18 are arranged parallel to one another on a connecting surface 14, 16 , the width of the groove 16 or tongues 18 can of course be reduced or the width of the element 10 can be increased. For example, this is conceivable for load-bearing walls.

In a preferred embodiment, the depth of the groove 16 is approximately one third of the total height of the construction element 10 according to the invention. In this way, a particularly good, high-force connection between two superimposed components is achieved. Of course, the groove depth can be smaller or larger. It is also possible for a component with several grooves to have different depths.

In a preferred embodiment, the height of the spring 18 is somewhat less than the depth of the groove 16 . This creates two stacked construction elements between the groove bottom and tongue 18, a gap in which additional glue or mortar to further increase the strength of a wall made of these elements can be filled. With a positive connection between two superimposed elements, the height of the spring 18 can of course be equal to the depth of the groove 16 . It is also conceivable that the spring 18 is greater than the depth of the groove 16 , so that between two superimposed components, the gap between their lower or obe ren connecting surfaces is formed. Mortar or adhesive can also be inserted here or insulating material can be placed between them. The gap between the connecting surfaces of two components can also be used on one or both sides for inserting or attaching other types of components, for example plates.

Of course, a combination of the above Types of use of the gap between the two connections surfaces of two components possible.  

Groove 16 and tongue 18 have a rectangular cross section, but which can also have any other conceivable shape. In the bottom of the groove, the component 10 is provided with two first, continuous cavities 20 , the central longitudinal axes of which cut the central longitudinal axes of the groove 16 and tongue 18 . These first cavities 20 each have an extension 22 at their ends facing the spring 18 . At their other ends they each have an extension 24 protruding from the plane of the groove base, which can be inserted into the cavity extension of a further component. It can be designed so that it centers two components only against each other or in such a way that it seals the resulting te by two Bauelemen extending cavity from the environment. The latter can be done, for example, by a tight fit or by additional sealing means. The height of the extension 24 can be both the same and slightly less than the depth of the extension 22 . However, it is also possible that it is somewhat higher than the depth of the extension 22 . This creates a gap between the tongue and groove as well as between the upper and lower connec tion surface of two superimposed components. This column can be used in a variety of ways, as already described above.

The shape of the cross-sectional area of the first cavity 20 can be of any type, preferably it is circular. Of course, the first cavity 20 can also have differently combined cross-sectional areas, insofar as only the extension 24 of a component can be inserted into the extension 22 of another element. The first two cavities 20 of a component 10 are arranged in relation to each other so that they are aligned in a grid-shaped wall composite with the first cavities of other components arranged above and below the respective component 10 . This creates a multitude of continuous cavities in a wall, which can be used in different ways. For example, it is conceivable that supply lines not shown in them run or suitable, not shown, clamping means are provided to additionally brace the entire wall in the direction of the central longitudinal axes of the first cavities. However, any other type of use is also conceivable. The intermeshing of the extension 24 of a component 10 in the expansion of a further element prevents this material from penetrating into the first cavities 20 when the base of the groove is poured out with an adhesive or mortar and can block them. At the same time, the two nested components are centered against each other.

Of course, it is also possible that the extension 24 on the spring 18 facing end of the first cavity 20 and the extension 22 are located at the opposite end. In addition, only one or more than two ste cavities 20 per component 10 can be provided. It is possible that individual first cavities 20 have no connection to the first cavity of other components, or al le first cavities have such a connection. Such a blindly ending first cavity 20 can be used, for example, for filling in mortar or adhesive into the groove base of components connected in the longitudinal direction. Components with only a first cavity 20 can be used, for example, between two door supports or windows.

In the area of the first cavities 20 , the groove 16 and the tongue 18 are widened. This ensures that two nested components are securely hooked in both directions of a horizontal plane, since the extension of the spring 18 engages in the expansion of the groove 16 . If the transverse dimension of the cavity 20 is smaller than the transverse dimension of the groove extension, a channel is formed between the groove wall and the cavity 20 , along which adhesive or mortar can flow. The entire groove base can thus be filled in without mortar or adhesive being able to get into the cavities 20 . This is also possible with nested components. The shape of the expansion of the groove 16 and tongue 18 is independent of the shape of the cavity 20th The extension on each side of the groove 16 and tongue 18 is preferably arcuate.

The component 10 is provided on one of its longitudinal sides 26, 28 with continuous one or more second cavities 30 running parallel to the first cavities 20 . In a preferred embodiment, these cavities 30 have a circular cross section, but can also have any other cross section. The cavities 30 can be provided on both long sides 26, 28 . They are used for ventilation or insulation by air, but can also be used to bring an adhesive or mortar onto the connecting surfaces of two superimposed components.

On the other longitudinal side 28, the device is provided with overlapping and extending over the entire height insulating inserts 32 provided. Like the second cavities 30, these can be arranged on both longitudinal sides 26, 28 . However, a combination of second cavities 30 and the insulating material inserts 32 is conceivable with correspondingly wide components or reduced groove widths.

The long sides 26, 28 of the component 10 are shown in the drawing figures as flat, smooth surfaces. As with any other component, they can be plastered or clad with other means. It is also possible that they are provided with ornaments or the like so that they can be used as gemstones.

It is also possible to see one or both of the longitudinal sides 26, 28 with an upwardly open recess 50 for receiving support beams or the like ( FIG. 4).

Parallel to the central longitudinal axis of the groove 16 or tongue 18 , the component 10 sits one or more in the longitudinal sides 26, 28 and open at both ends, third cavities 38 , which preferably have a circular cross section. These third cavities 38 can also be used for air insulation. However, supply lines (not shown) should preferably be laid in them. The supply lines can be branched independently of the lines in the first cavities 20 or from these. For this purpose, it is necessary that a recess, not shown, for example in the form of a control box, is provided at one point in the wall assembly. The recess is made at the location of the first cavity 20 that holds the supply line provided for branching ent. The recess is so deep into the component that its base plane, which runs parallel to the respective longitudinal side 26, 28 , intersects the first cavity 20 . The supply line can then be removed and pushed through the third cavity or cavities 38 to the point where it is to be coupled to a connection located outside the wall. This makes it possible for supply lines to be laid in a simple manner in walls which have already been erected. Above all, no major chiselling work has to be carried out, because they are only necessary at the points where the supply line is transferred from the first cavities 20 into the third cavities 38 and where they are to be led out of the wall.

The third cavities 38 can also serve to brace a wall parallel to the central longitudinal axes of the groove 16 or tongue 18 by means of suitable clamping means, not shown.

There is a possibility that the second and third cavities 30, 38 are arranged so that their central longitudinal axes intersect. In these cases, the second cavities 30 cannot be used to apply mortar or adhesive to the connecting surfaces of two components placed on one another.

On its two end faces 34, 36 , the component 10 has two vertically extending, centrally arranged recesses 40 . Their central longitudinal axes intersect the central longitudinal axes of groove 16 or tongue 18 . Thus, 40 mortar or adhesive can be filled in with cohesively connected components through the recess 40 if these are already arranged next to one another in one layer. It is possible that one as well as both end faces 34, 36 have such a depression 40 . The depression 40 can also be designed as a groove. An elevation 42 designed as a spring engages in this groove on the face of one of its components. A device 10 may thus on one end side 34, 36 designed as a groove Vertie Fung 40 and have on the other designed as a spring boss 42nd As a result, the components are interlocked with one another on all sides. The height of the tongue should be slightly less than the depth of the groove, so that a gap is used to fill in the mortar or adhesive. The tongue and groove preferably have a rectangular cross section, but can also have any other. It is possible to provide a further recess 44 in the middle 42 of the elevation. This increases the gap that is created between two components on the end faces.

In Figs. 5 to 9 further Bauelemen invention are shown te. They differ from the element 4 described in the drawing figures only by their shape, so that the description can be limited to their intended use.

In Fig. 5 a T-shaped component 100 is shown, which is used in the cases where the walls abut each other at an angle of 90 °. His legs 102 are the same length, but can also have different lengths.

A component 200 for corners is shown in FIG. 6. In plan view, it has the shape of the letter L with legs 202 of different lengths. Depending on the intended use, one or the other leg 202 may be longer. However, it is also possible for both legs 202 to have the same length. The third cavities 38 are bent at right angles at the apex of the L '. For better execution of supply lines, they can also be rounded. The third cavities 38 in the long longitudinal sides 26, 28 of the legs 202 are open on both sides in both longitudinal directions. As a result, bracing means and / or supply lines can be carried out in a simple manner through an entire wall. But it is also possible that they have no openings in the region of the apex of the L '.

A cross-shaped component 300 is shown in FIG. 7. It is primarily used when four walls meet at an angle of 90 °. Its legs 302 are of the same length, but can also have different lengths. As with the L-shaped component 200 , the third cavities 38 can have rounded corners in the respective longitudinal sides 26, 28 .

An arcuate component 400 is shown in FIG. 8. By using these components 400 , chimneys, towers and the like can be built. However, they can also be used for excavating and lining up tunnel structures. In the latter case, the connecting surfaces 14, 16 run vertically. The first cavities 20 can then serve to accommodate suitable tensioning means, not shown.

In Fig. 9, an S-shaped component 500 is finally shown ge. It is used for the grid-shaped connection of two Bo-shaped components 400 , which are strung together in an S-shape.

Finally, it should be pointed out that the cavities 20 of the components 10 can also be used for pouring concrete. For example, it is possible to end the wall in front of the corner at a corner. In every second row, a single component 10 jumps out from the end face of the respective wall. Using formwork boards, 20 concrete can then be poured through the first cavities along the entire height of the two walls. After the concrete has hardened, a secure and solid material connection is created.

Claims (13)

1. Rectangular component for creating walls, with connecting surfaces arranged on opposite sides, one of the connecting surfaces having at least one groove and the other connecting surface being provided with at least one spring to cooperate with the groove of another component, and with at least one he Most, the two connecting surfaces connect the cavity, which is open at both ends, the central longitudinal axis of which intersects the central longitudinal axes of the tongue and groove, characterized in that the cavity ( 20 ) has at one end of one of the above the bottom of the groove ( 16 ) or surround the outer surface of the tongue ( 18 ) in front of the standing extension ( 24 ) and at its other end is provided with an internal cross-sectional extension ( 22 ) matching the extension ( 24 ) and that groove ( 16 ) and tongue ( 18 ) in the area of the extension ( 24 ) and the cross-sectional extension ( 22 ) widened and with such close tolerance and with solc forth height, such as about a third of the total height of the component ( 10 ), are formed such that components arranged in the composite ( 10 ) cannot be levered out by a force directed perpendicular to the wall. 2. Component according to claim 1, characterized by two first cavities ( 20 ), each in alignment with the first wall cavity ( 20 ) of a staggered, further component ( 10 ). 3. Component according to one of claims 1 or 2, characterized in that the width of the groove ( 16 ) or tongue ( 18 ) is approximately one third of the total width of the component ( 10 ). 4. Component according to one of the preceding claims, characterized in that outside the groove ( 16 ) parallel to the first cavity ( 20 ) duri fende, second cavities ( 30 ) are arranged. 5. Component according to one of the preceding claims, characterized in that paral lel to the central longitudinal axis of the groove ( 16 ) or tongue ( 18 ) at the ends open, third cavities ( 38 ) over the entire length of the component ( 10 ) extend. 6. The component according to claim 1 to 5, characterized in that the first, second and third cavities ( 20, 30, 38 ) have a circular cross-section. 7. Component according to one of the preceding claims, characterized in that its end faces ( 34, 36 ) are provided on the one hand with a groove ( 40 ) and on the other hand with a suitable spring ( 42 ). 8. Component according to one of the preceding claims, characterized in that one of the connecting surfaces ( 12, 14 ) is provided at the edge with a recess ( 50 ). 9. Component according to one of claims 1 to 8, there  characterized in that it is in Top view has a substantially T-shaped shape. 10. Component according to one of claims 1 to 8, there characterized in that it is in Top view has a substantially L-shaped shape. 11. The component according to one of claims 1 to 8, there characterized in that it is in Top view of a substantially cruciform shape sits. 12. Component according to one of claims 1 to 8, there characterized in that it is in Top view of a substantially circular arc shape owns. 13. Component according to one of claims 1 to 8, there characterized in that it is in Top view has a substantially S-shaped shape.