DE102006044915B4 - Method for creating a foundation of a building - Google Patents

Abstract

Method of constructing a building with the following steps: - after removing non-loadable soil, make a viable subgrade, - mark the outside of a plate foundation and transfer the mark to the subgrade, - thereafter vertical slot-shaped trenches become to a predetermined depth milled or dug along the marking, the outer edges of the plate foundation are marked again, - heat insulation plates are set in the slot-shaped trench - the concrete slab is cast using the supernatant of the heat-insulating plates as edge formwork, with U-shaped clamps are placed on the lower edge of the thermal insulation panels , whose web has a skewer on the side opposite the thighs, set the thermal insulation plates with the spit in the slot-shaped trench and set up with their upper edge to the desired height above the ground.

Description

The invention relates to a method for creating a foundation of a building according to claim 1.

To prevent damage to buildings caused by frost, building foundations must be protected against frost heaves. A frost bump is the deformation of a building caused by ice lenses in the soil underneath.

Various methods are known in the prior art to avoid the risk of freezing. One method is to run the building foundation below the freezing penetration depth. In the case of buildings whose foundations reach below the freezing depth of the earth, no special design methods are required for frost heaves. Here, concrete strip foundations are created, which run around the building in the outer area of a plate foundation and thus increase the foundation depth of the founding of the plate. This measure is the most common one used to prevent frost heave. Strip foundations made of concrete are costly and time-consuming due to the required earthworks and the building material in the production. Concrete strip foundations without integrated vertical insulation are a thermal bridge in the base of the building.

Another possibility is to remove frost-sensitive soil under a plate foundation to below the freezing penetration depth and to replace it with frost-resistant material before constructing the foundation. The frost-resistant material is also kept free of water by a drainage, so that frost can not form below the plate foundation when frozen. However, soil replacement is also costly and time consuming. He also requires a permanent functioning drainage. The drainage leads to follow-up costs, since a permanent function can only be guaranteed by maintenance at fixed intervals. In addition, drainage is not allowed in all construction areas.

A third way to avoid frost heave is to create heat-insulating measures, as in DE 29 915 206 U1 disclosed. On the outside of the building, a vertical edge insulation is provided for strip foundations. When using a vertical edge insulation, the strip foundations are lowered to a certain depth depending on a frost index. At the corners, a greater depth is required than along the remaining walls. Deeper foundations at corners are avoided by soil insulation at the corners. Soil insulation is a horizontally installed insulation around the building. It can also be used if the foundation depth is limited. The building user must be informed about the presence and location of the soil insulation and its purpose. It must also be ensured that the soil insulation is adequately protected against excessive moisture caused by roof overhangs, proper placement of gutters, etc., and that it is constructed on a drainage layer. A major difficulty in soil containment is the location of this insulation in the exterior of the building. If frost protection requires soil containment, measures must be taken to ensure that it is not damaged or removed during installation or after completion of the building. In the case of soil insulation, there is also a restriction with regard to outdoor facilities around the building.

Out DE 20 2004 011 902 U1 is a founding of a building known by means of a reinforced steel concrete slab, which is created on a planum, outside the periphery of the concrete slab a vertical heat-insulating layer is introduced into the soil, which extends beyond the concrete slab also down into the ground. Below the concrete slab is a pressure-resistant, heat-insulating horizontal layer, which rests on a sandy or gravel surface.

Out DE 299 10 010 U1 For foundation purposes, a so-called shield plate layer is led obliquely into the ground, which also partly meets the frost protection requirement. Below the bottom plate, an additional drainage is provided, which consists of a pressure-resistant hard foam layer.

The invention has for its object to provide an easy to implement method for creating a foundation of a building, which ensures a more efficient protection of sheet foundations against frost heaves.

This object is solved by the features of patent claim 1.

The method for creating a foundation according to the invention provides the following method steps:
After removal of unsustainable soil a viable planum is created
the outsides of a plate foundation are marked and the marking is transferred to the planum,
thereafter vertical slot-shaped trenches are milled or dug at a predetermined depth along the marking,
the outside edges of the plate foundation are marked again,
Thermal insulation panels are set in the slot-shaped trenches,
the concrete slab is cast using the supernatant of the heat-insulating slabs as edge formwork,
U-shaped clamps are attached to the rear edge of the thermal insulation panels, the bridge on the opposite side of the legs has a spit, the thermal insulation panels are set with the spit in the slot-shaped trench and set up with its upper edge to the desired height above the ground.

According to one embodiment of the invention, the heat-insulating plates are foam boards. According to a further embodiment of the invention, a pressure-resistant heat-insulating layer is placed on the subgrade below the bottom plate.

The production of such a thermal frost apron made of thermal insulation panels provides a significant time savings of up to 35% compared to the conventional strip foundations. Moreover, it can be used in any construction area and is completely maintenance-free.

The heat-insulating layer is, as mentioned, preferably made of foam boards, which are set against each other without cold spots. This is done according to an embodiment of the invention in that the plates are connected laterally via a tongue and groove connection.

An embodiment of the method according to the invention will be explained in more detail with reference to drawings.

1 shows a section in the foundation area of a building with a thermal apron.

2 shows in perspective a thermal insulation board for the thermal apron after 1 ,

3 indicates a foot for the thermal insulation mat 2 ,

In 1 is an outer wall 2 and an inner wall 4 to recognize a building not shown and the hint of a window or a patio door 6 with glazing, which of a frame 8th is surrounded. 10 denotes an elastic joint, 12 also an elastic joint in connection with clinker boards 14 as a transition to a terrace 11 , The building parts, to which also a screed 13 heard, with underlying insulating layer 15 , rely on a concrete slab 28 from. Below the concrete slab 28 There is a horizontal heat-insulating layer 30 from load-bearing thermal insulation panels. You can also see a parapet 17 On top of a thermal insulation of the frame 8th supported and mortared on the concrete slab 28 lies.

At the edge of the concrete slab 28 is a so-called thermal frost apron 34 arranged as a heat-insulating layer. The vertical heat-insulating layer extends to a depth of z. B. 80 cm and closes immediately to the edge of the concrete slab 28 and extends slightly above the upper edge of the concrete slab 28 out. It is understood that such a heat-insulating layer around the entire concrete slab 28 extends around.

Below the terrace 11 and on the outside of the heat-insulating layer 34 is a gravel bed 38 and below a gravel bed arranged with a drainage 37 , Sunk in the gravel bed 38 is a drainage channel 16 ,

The thermo-frost apron 34 is composed of individual thermal insulation panels, one of which is in 2 is shown by way of example. It is with the reference number 40 Mistake. The thermal insulation board consists z. B. from a hard foam of sufficient thickness and height and is at the edges with a spring 42 or a groove 44 provided so that individual plates can be effectively connected to each other. At the bottom of the plate 40 are feet 46 appropriate. In 3 is a foot 46 shown.

The foot 46 consists of a U-shaped bracket 48 , at the footbridge at the bottom of a longer spit 50 is appropriate. The clip 48 gets stuck on the plate 40 postponed. However, it is also a connection conceivable such that the legs of the profile 48 are provided with holes to the profile by means of pins, screws or the like on the plate 40 to fix.

When creating the in 1 The founding procedure is as follows:
First, after removal of unsustainable soil, a viable planum is made. The outsides of the plate foundation are marked and the marker is transferred to the planum. Thereafter, a slot-shaped trench with a depth of at least 80 cm is made with the aid of a suitable milling machine or an excavator. Here, the mark is used for orientation. Then the outer edges of the plate foundation are marked. Thereafter, thermal insulation panels, such as the plate 40 set in the trench so that its upper edge is set approximately at the height of the upper edge of the concrete slab still to be produced. The height adjustment can be done with the help of the feet 46 respectively. After that, the concrete slab 28 poured, with the upper part of the frost apron 34 serves as edge formwork. Before pouring the concrete slab 28 becomes a sealing layer on the heat-insulating layer 30 hung up, z. B. an EPDM web.

On the concrete slab a bituminous roof waterproofing membrane is laid.

Claims (5)

Method for creating a building with the following steps: - after removal of unsustainable soil a viable planum is created, - the outer sides of a plate foundation are marked and the marking is transferred to the planum, - then vertical slot-shaped trenches are milled or dug to a specified depth along the marking, the outer edges of the plate foundation are marked again, - Thermal insulation panels are set in the slot-shaped trench - The concrete slab is poured using the supernatant of the insulating panels as edge formwork, with U-shaped clamps are attached to the lower edge of the thermal insulation panels, the bridge on the opposite side of the legs has a spit, the thermal insulation panels with the spit in the slot-shaped trench set and set with their upper edge to the desired height above the planum. The method of claim 1, wherein the heat-insulating plates are connected together via a tongue and groove connection. The method of claim 1 or 2, wherein a horizontal thermal barrier coating of heat-insulating pressure-resistant plates is made under the concrete slab. A method according to claim 3, wherein a seal is incorporated between the heat-insulating layer and the concrete slab. Method according to Claim 4, in which EPDM sheets bonded to one another are installed as a seal.

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