NO168193B - FORSKALING STEN - Google Patents

Abstract

A formwork stone has an outer wall (1), an inner wall. (2), an intermediate cavity (5) for filling concrete, two end walls (3,4) provided with recesses (6), and an insulating insert (10). The insulating insert (10) extends over the inside (12) of the outer wall (1), the inside of the end walls (3,4) and in the recesses (6).

Description

The invention relates to a formwork block with an outer wall, an inner wall, a cavity lying between them for filling with concrete, two end walls which are provided with recesses with at least an approximate tunnel shape, and with an insulation insert that extends over the inside of the outer wall.

In order to save costs, formwork stones are used more and more when building houses, especially for basements. However, it is also possible to build up an entire house with formwork stone. Formwork stone has the advantage that it can also be used by non-professionals. Usually, only the first stone layer is set in mortar, while the rest of the wall is built up dry, in the same way as you build with building blocks. To make this possible, the formwork stones are relatively precise, that is to say they are milled and provided with tongue and groove. After the formwork stones have been laid together at the desired height, their cavities are filled with concrete. In this way, you achieve a very stable wall that is easy to build up.

However, such formwork stones only have a relatively poor thermal insulation capacity. It has therefore been proposed to use paving stones that are fitted with insulating inserts. The walls in the cavity of the formwork stone are then completely covered with insulation. This provides relatively good thermal insulation, but there is a disadvantage that heat cannot be stored in the wall. In this connection, the filled concrete will be a good heat reservoir during utilization of the tiled stove effect, but because the concrete will also be surrounded on the inside by styrofoam, the concrete cannot be used for this purpose. A disadvantage is also that the moisture condensation conditions or the removal of moisture through the stone is poor. In the case of a finished house, you will therefore have to reckon with so-called building humidity over a relatively long period of time, and there is even a danger that panels placed on the wall could come loose. The concrete filled in the cavity, which is surrounded on all sides by insulating inlays, is naturally very moist, and this moisture will only be able to penetrate very slowly.. Even later, however, the room climate will become worse as a result of such a stone, because in the room steam pressure, which is always present, is poorly dissipated through such a wall.

From DE-OS 26 44 897, a formwork part with an insulating layer on the inside of the outer wall is known. There are also tunnel-shaped recesses, which provide good lateral connection when the cavities are filled with concrete. With this known formwork stone, however, it is a disadvantage that cold bridges will occur in the area near the end sides, or between two formwork stones lying next to each other, as a result of the direct transition between the stone parts that collide with each other. In addition, the insulation layer is foamed directly into the stone, and this is relatively complicated and expensive. From DE-PS 26 15 608, an insulation insert is known on both longitudinal sides of a formwork stone, but it concerns a so-called mantle stone, i.e. a different type of stone. There are no tunnel-like recesses. The insulating effect of this known stone is also relatively poor, because there are cold bridges between stone parts that collide with each other and direct stone transitions.

The present invention therefore aims to provide a formwork stone of the type mentioned at the outset, which stone is easy to use and also has good heat and sound insulation properties, without moisture problems.

According to the invention, this is achieved by the insulating insert also extending over the inside of the end wall and along the recesses, the end edges of the tunnel-shaped recess being surrounded by an extension of the insulating insert.

According to the invention, the insulation inserts are arranged so that good heat and sound insulation is achieved, while also ensuring sufficient moisture transport through the formwork stone. Thus, for example, there will be no insulation inlay between the inner wall of the formwork stone and the cavity, which will later be filled with concrete. This means that the tiled stove effect can be utilized, because the heat of the interior can be stored in the concrete. At the same time, however, insulation inserts placed on both end walls and on the inside of the outer wall ensure that the heat cannot be transported out. The recesses mean that the concrete filling in lined up formwork stones will have a mutual connection, which provides a stable connection. Moisture can escape transversely through the formwork stone via the parts of the end walls that are not broken by the recesses.

The tunnel shape, in connection with the lining of the end edges with insulating inserts, will provide a further improvement in the insulating effect.

Furthermore, the insulation insert on the inside of the end walls can advantageously have a reduced thickness in the direction towards the inner wall. This design is particularly practical and does not reduce the thermal insulation. At the same time, however, more space is provided for the concrete filling, so that the finished wall has a higher static load capacity.

A particularly advantageous further development is that the two end walls are additionally provided with a transverse slot running parallel to the outside of the end walls.

The end wall parts used for moisture transport thereby have better thermal insulation properties. In addition, the transverse slits reduce the density of the concrete, which also provides better insulation.

Generally, one will choose a slot width and a slot length as large as possible. A prerequisite is that the end wall maintains sufficient stability.

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A similarly very advantageous embodiment of the invention is characterized by the fact that the two end sides at their upper sides facing away from the recesses have a respective insulation groove running parallel to the end side in which an extension of the insulation insert is located.

In this way, it is achieved that when the formwork stones are laid in mortar, the mortar will not come into direct contact with the concrete or the end wall in the formwork stone. The insulating insert in the insulating groove prevents direct contact. This measure results in a further improvement of the formwork stone's thermal insulation ability.

If the formwork stone is made of aerated concrete and possibly also the concrete filling is lightweight concrete, then the insulation properties are further improved.

The insulation insert can be made uniform and can be pushed into place after the stone itself has been produced. In order to facilitate assembly, especially when the end edges of the recess and the insulation groove are to be provided with an insulation insert, the insulation insert is usually designed in two parts, with the separation joint in the form of a step joint being laid approximately along the longitudinal center line of the stone to thereby avoid breaks in the insulation.

A further very advantageous design of the formwork stone consists in providing the outer wall and possibly also the inner wall with at least one stiffening rib on the inner side. The stiffening rib can be made throughout in the vertical direction and can be located in the area of the middle plane of the stone.

Of course, it is also possible within the framework of the stone

to have several side-by-side bracing ribs; This will depend on the length and type of stone. The same also applies to the course of the stiffening ribs.

With the help of such stiffening ribs, the formwork stone becomes significantly more stable against compressive and bending stresses. This applies, for example, to the construction of the wall, while the inner space in the formwork stones is still open. The stiffening ribs will reduce the risk of breakage. However, the stiffening ribs will also bring benefits when filling the formwork stones with concrete. During the concrete filling, high compressive stresses will occur which are taken up by the stiffening ribs.

Even after the building has been erected, the stiffening ribs on the outer walls will bring benefits. If such a wall is exposed to strong sun, for example it may be a south-facing wall, then the outer wall will heat up quite strongly as a result of the insulation placed on the inside. The stiffening ribs here significantly reduce the risk of plaster cracks.

The invention shall be explained in more detail with reference to the drawings where: Fig.1 shows a half-section through a formwork stone, Fig.2 shows an end view of the formwork stone,

fig.3 shows a perspective view of the formwork stone, fig.4 shows several laid out formwork stones, and fig.5 shows a ground plan of a formwork stone with stiffening ribs.

The formwork stone has an outer wall 1, an inner wall 2 and end walls 3 and 4. These walls surround a cavity 5 where, after laying the formwork stones, it is filled with concrete. The cavities 5 are connected to each other through tunnel-shaped recesses 6 in the end walls 3 and 4.

In the end walls 3 and 4 there are grooves 7 and springs 8 which enable a joint-free assembly of the formwork stones. In the two end walls 3 and 4, transverse slits 9 are also arranged. These can be continuous in the vertical direction. Of course, they can also be closed to the outside of the formwork stone. In order for the cross-section 9 to have the greatest possible length, they are, as shown, offset in relation to each other relative to the stone's longitudinal axis. This is necessary because of the located notches 7 and springs 9.

An insulating insert 10 is two-part. In the separation joint, the insulation is stepped 11, roughly in the middle of the length of the stone.

As can be seen in particular from fig.10, an insulating insert 10 is arranged on the inside 12 of the outer wall 1 and on the inside of the two end walls 3 and 4. At the same time, the insulating insert with an approximately semicircular part 13 enters the recesses 6 and covers their end edges 14. In fig.2, the stone is shown so that one sees the tunnel-shaped recess 6. Of course, one can also imagine an inverted design of the formwork stone, that is to say that the two recesses are located in the upper end wall areas.

In both end walls 3 and 4, in those facing away from the recesses, resp. undersides arranged a respective insulating groove 16 which runs parallel to the end side. An insulation insert part 17 has been inserted here.

When the two-part insulation insert 10 is to be inserted, this takes place from the stone sides where the recesses 6 are open, as the insulation insert halves are pushed in from below, respectively. from above, whereby the side parts 13 and 17 are placed respectively pushed in over the end edges 14 or into the insulation groove 16.

As can be seen from fig.l, the insulation insert has a decreasing thickness in the direction of the inner wall 2 in the area of the two end walls 3 and 4.

In fig.4, several laid formwork stones are shown on a smaller scale. You can also see there how a cornerstone 18 is designed. Such a cornerstone has a closed end wall, i.e. an end wall without recess 6, while the inner wall 2 is instead provided with a recess 6. In addition, an insulation insert has been laid on the outer end side.

If you do not want to use a special corner stone 18, you can optionally also use an ordinary formwork stone as a corner stone. It is then only required to cover the recess 6 in the end side with a special insulation plate (shown with dashed lines) and then either at the factory or on the construction site provide a recess 6 in the inner wall 2.

Fig.5 shows a ground plan of formwork stone with stiffening ribs. As can be seen, a vertical, continuous stiffening rib 19 is arranged on the inner side of the outer wall 1 and the inner wall 2, approximately in the middle plane of the stone. The insulation insert 10, which also lies on the inside of the outer wall 1, is designed so that it follows the shape of the stiffening rib, so that

an even thickness of the insulation insert is ensured.

The shape of the stiffening rib can be arbitrary. Usually, the stiffening rib is designed so that its side flanks slope towards the outer wall or inner wall.

Claims (8)

1. Formwork stone with an outer wall (1), an inner wall (2), a cavity lying between them for filling with concrete, two end walls (3,4) which are provided with recesses (6) with at least an approximate tunnel shape, and with an insulation insert ( 10) which extends over the inside (12) of the outer wall (1), characterized in that the insulation insert (10) also extends over the inside of the end wall (3,4) and along the recesses (6), the end edges (14) of the tunnel-shaped recess ( 6) is surrounded by an extension (13) of the insulating insert (10). 2. Formwork stone according to claim 1, characterized in that the thickness of the insulating insert (10) along the inside of the end walls (3,4) decreases in the direction towards the inner wall (2). 3. Formwork stone according to claims 1-2, characterized in that the two end walls (3,4) are each provided with a transverse slot (9) running parallel to the outer side of the end wall. 4. Formwork stone according to claim 3, characterized in that the width of the transverse slot (9) is between 1/3 and 1/8, preferably 1/6 of the thickness of an end wall (3,4). 5. Formwork stone according to claim 3 or 4, characterized in that the two end walls (3,4) are provided with diagonally opposite notches (7) and springs (8), and in that the two transverse slots (9) are shifted in relation to each other transversely of the stone's longitudinal axis, so that in the area near the springs (8) they are extended in the direction towards the outer wall or the inner wall. 6. The formwork stone according to one of the claims 1-5, characterized in that the two end walls (3,4) at their upper and lower sides facing away from the recesses (6) have a respective insulation groove (16) running parallel to the end side, in which an extension (17) of the insulation insert (10) is located. 7. Formwork stone according to claim 6, characterized in that the insulating groove (16) with the insulating insert extends over a significant part of the width and at least approximately over the width of the stone's recess (6). 8. Formwork stone according to one of claims 1-7, characterized in that the outer wall (1) and/or the inner wall (2) is provided on the inside with at least one stiffening rib (19).