DE10146062A1 - Foundation construction for structures with load-bearing insulation - Google Patents

Abstract

The invention relates to a structure for foundations in structures with load-absorbing insulation and is used in single and multi-storey residential, corporate and industrial buildings. DOLLAR A The technical problem, while ensuring the requirements for stability, heat, sound, health and fire protection as well as the usability of the built structures and while maintaining the natural basis of life a simple, inexpensive, construction time-shortening, insensitive to weather influences, for everyone Creating a seasonally feasible and fully functional foundation structure for buildings is achieved in that in the manufacture of a foundation structure for structures with load-absorbing insulation, an insulating material that contains all load-bearing components and parts of the floor structure arranged between the load-bearing components, including the entire structure carries and which consists of a heat-insulating, environmentally compatible, louse absorbing, distributing and ablating, closed-cell, pourable and compressible and / or plate-shaped, light material on the foundations for the insulation of buildings, sensible areas, lines and points of the structure are arranged horizontally on the ground (Figure 1).

Description

The invention relates to a structure for foundations in structures with load-bearing Insulation and is used in single and multi-storey residential, corporate and industrial construction.

The for the transfer of the building loads to stable floor layers and for Ensuring an even setting serving foundation already requires in the Building planning in-depth studies of the building ground and the Groundwater conditions. In addition to the resilience of the soil types and their depth, the required soil coverage of the foundation base for the type of foundation (flat or Deep foundation) and the choice of the foundation body (e.g. against frost elevations) are decisive.

So far, the foundations of the foundations of outer walls and pillars or in Free standing foundations of more than 800 mm, based on the later final Terrain height usual. The open position of the foundations is therefore when the construction is carried out special attention and requires in the cold season, especially at frost-variable soils additional effort, so that at certain temperatures (below 10 ° C) even with internal walls and pillars in closed rooms Earth coverage of more than 800 mm is required.

The foundation dimensioning should be matched to an even foundation load be, with the possibility of mutually influencing neighboring Foundation body due to the pressure distribution in the soil must be observed, so that often Building-sized foundation slabs are used for load transfer to larger areas become.

Compared to the strip foundations for a linear load transfer and the Individual foundations for punctiform load entry are the foundation plates, the consist mainly of concrete and both on site (formwork, fresh concrete) and industrially manufactured prefabricated parts are manufactured, very material and labor intensive. Connected to the expenses and services already required during planning as well as the necessary in terms of weather, environmental and moisture protection Measures, also in connection with the materials of the emerging components, is for the Establishment required a significant portion of the cost of the entire structure.

So z. For example, in US 5 657 597 A1, a floor construction method for a building described in which a plurality of foundation blocks at predetermined locations that the Define the floor plan, be positioned. A variety of foundation beams, which have notches at regular intervals, are over the foundation blocks curious; excited. Floor beams are inserted into the notches between the foundation beams appropriate. This method is both in the manufacture of the construction parts as well the creation of the construction for the respective building is very complex and does not offer also the function of the thermal insulation.

An earthquake, fire and wind resistant prefabricated foundation plate, consisting of one A variety of structural members that are cast from concrete are disclosed in US 5,862,639 A1 described. The structural members are together to form a structure in one Structural level connected, with a rigid, malleable between the structural members Substance is introduced. The structural members consist of page, end and Center foundation members and have connecting flanges on their sides. Between the structural members and in spaces delimited by the structural members Styrofoam plates arranged. The disadvantages mentioned in US Pat. No. 5,657,597 A1 also apply here to.

Around one of the solid until the forties of the twentieth century Construction with their conventional heavy, solid stone houses and heavy Equivalent impact sound insulation for wooden floors for the subsequent lighter ones Ensuring constructions with their solid concrete floors is described in US 6 250 043 A1 proposed a method for laying floor coverings on concrete substrates, in which a quickly applied thin layer of a mixture that is also glass fibers or contains polyurethane foam, is used. However, this solution is specific to that Problem of impact sound insulation aimed and brings no progress in terms of traditional means and ways of making foundations.

DE-OS 198 39 849 A1 describes a simplified method for creating in the ground horizontal parts of the building presented by changing the construction methods Drastically reduce manufacturing costs and the functionality of the building parts as a whole should improve and apply to all floor conditions at no additional cost can. For this purpose, a large-scale floor slab with the building to be erected should be appropriate shape and size in a shape-matched, by cutting out and removing the Form formed in the upper layer of earth. To external walls and base plate in To protect the base area from frost, they receive an earth fill. Although in the Unless explicitly mentioned, it can be assumed that the base plate, since it is poured into the earth form, is also made of concrete, which means that the known disadvantages such as construction time, required frost protection during the construction phase, Material costs etc. arise and no thermal insulation is achieved without further notice.

On the use of a leveling layer on the ground just as little as on the usual one Floor plate made of concrete is also not omitted in DE-GM 298 10 406 U1, although here as flameproof thermal insulation is provided. So that is this solution also has the aforementioned disadvantages.

Finally, a foundation structure is described in DE-OS 198 01 123 A1, in which one horizontal insulating layer or plate is formed from base elements made of lightweight concrete, preferably lightweight polystyrene, and between which formwork elements an insulating rigid foam material, e.g. B. also made of foam glass, which are not be removed and thus remain as insulation. Is used in this solution a roll of gravel or gravel as a leveling layer and a concrete floor slab, so that the known disadvantages such as long construction time, required frost protection during the construction phase, material costs etc. arise.

Therefore, the object of the invention is to ensure the requirements the stability, the heat, sound, health and fire protection as well as the Usability of the built structures and preserving the natural Livelihood a simple, inexpensive, construction time-shortening, against Insensitive to weather influences, realizable in every season and full to create functional, thermally insulated foundation structures for buildings.

This object is achieved in that in the manufacture of a Foundation structure for buildings with load-bearing insulation an insulation material, which all load-bearing components and parts of the, with full-surface training also the entire, between the load-bearing components arranged floor carries and from a heat-insulating, environmentally compatible, load-absorbing, distributing and removing, closed-cell, pourable and compactable and / or plate-shaped, light Material exists, in the area of foundations for the insulation of buildings Areas, lines and / or points of the structure directly on the ground horizontally is arranged.

Both industrially prefabricated plate-shaped components are suitable for this Hard foam and / or foam glass in connection with pourable compressible materials as well as this alone with the required properties.

A particularly inexpensive material for the production of the foundation has been made from recycled Glass-made foam glass in the form of grit or crushed stone, which the required parameters such as thermal insulation, drainage and capillary refraction, Water repellency, since it is not hygroscopic, closed-cell structure (to keep even in damp Condition to ensure thermal insulation), environmental compatibility, frost protection, high Resilience and low mass and is inexpensive to process. The usual Construction measures are limited to the most necessary or are completely eliminated. B. less Excavation, saving water drainage, no need for special layers, none additional insulation materials. In addition, due to the low load due to the minimized layer thickness and the low dead weight while at the same time fulfilling the required insulation values in this way the load on most floors can be improved, with an even improvement for damp soils is because there is a load distribution due to the enormous frictional resistance of the individual Foam glass grains, which are well connected by the compression, are formed.

Another significant advantage of the foundation structure according to the invention is that that the advantages of drywall work here, which in particular a season-independent construction and thus also the prerequisite for creates continuous employment in the construction industry.

An advantageous embodiment consists in anchoring the load-bearing components the insulation material directly in the ground. This ensures the stability of the emerging components increased and against lateral forces such. B. Wind loads (lifting forces and thrust forces) stabilized.

To counter the emerging structural components that limit the building from the outside Anchoring possible shear forces safely, it is also advantageous to a circumferential Arrange ring anchors in the lower area of these components. This ring anchor can be used massive reinforced concrete walls and walls from rising masonry in Door threshold height and in the case of lightweight walls made of wood or similar in the area of trained spacers arranged between the wall and insulation become.

When using massive, large, up-and-coming components, load distribution plates can be between Insulating material and load-bearing or non-load-bearing components can be arranged to the To allow pressure distribution on the insulation material.

When using wooden components, spacers, e.g. B. L- or U-shaped Precast concrete parts, the surfaces facing the outside of which are protected against splash water and the are arranged between the wooden components and the insulation material, protecting the Wooden components against splashing water and rising damp.

In order to prevent the penetration of frost into the foundation structure, the insulating material with a protrusion over all outer edges of the building, which the frost protection ensuring dimension, arranged.

The already low costs for the foundation structure according to the invention can further reduced both in terms of material costs and labor if the insulation material consists of layers or areas that differ are heavily compressed. Areas with emerging components can meet the requirements are compressed accordingly more strongly than areas that are only considered the floor structure Take up surface load and in which pourable insulation material with less compression and / or low-density plate-shaped insulation elements that meet the requirements are arranged.

Another way of reducing costs while ensuring functionality is that the insulating material only in areas with emerging load-bearing components and is arranged on the outer edge of the building, while the remaining areas of the Foundation of inferior materials (e.g. gravel, grit or crushed stone) are formed.

The invention is described below in several exemplary embodiments, which are shown in FIGS Drawings are shown, described in more detail.

Here show:

Fig. 1 shows a cross section of the foundation structure with an aspiring outer wall component and an impact soundproofed floor structure.

Fig. 2 shows a cross section of the foundation structure with an emerging steel column and industrial floor.

Fig. 3 shows a cross section of the foundation structure with an aspiring outer wall component made of wood, splash-proof spacer and an impact soundproofed floor structure.

Fig. 4 shows a cross section of the foundation structure with an emerging particularly thermally insulated outer wall component with a wooden frame, splash-proof spacer, circumferential ring anchor and a thermally insulated floor structure.

As can be seen from FIG. 1, after removal of the topsoil 1 and the soil 2 there is approximately 35 cm deep, the floor plan dimensions of the building to be erected plus the protrusion 3, which provides frost protection, of at least 50 cm corresponding flat construction pit 4 with a roof planum 5 a 35 cm thick foam glass layer 8 arranged on the load-bearing floor 6 and a drainage 7 running around the edge in accordance with the course of the emerging outer wall components and their linear load transfer into the subsurface. This layer is compressed in a ratio of 1: 1.6. The remaining areas of the construction pit 4 are filled up to the level of the foam glass layer 8 compressed in the ratio 1: 1.6 with a foam glass layer 9 which is compressed in the ratio 1: 1.3. A foil cover serving as a vapor barrier 10 closes off the foam glass layers at the top. The emerging heat-insulated outer wall component 11, which is provided with a facing layer, stands on the vapor barrier 10 above the foam glass layer 8 . To improve the stability, a mortar compensation layer 12 is arranged between the base of the outer wall component 11 and the vapor barrier 10 . The floor 13 , consisting of an impact sound-absorbing layer 14 made of pourable insulating material and an overlying screed compensation layer 15 , is arranged between the aspiring components on the vapor barrier 10 above the foam glass layer. The foam glass layer 8 is provided with a broken edge 16 in the peripheral area in front of the outer wall components 11 . In the space thus formed between the outer film cover 17 over the outer edge of the foam glass layer 8 and the facing layer of the outer wall components 11 , an apron 18 made of gravel is arranged, which is delimited on the outer edge by lawn shelves 19 .

As shown in Fig. 2, the foundation structure for a workshop also consists of a floor plan of approx. 35 cm deep after removal of the topsoil 1 and soil 2, the floor plan dimensions of the building to be erected plus the overhang 3 ensuring frost protection of at least 50 cm Corresponding shallow excavation pit 4 according to the course of the emerging outer supports 20 and their punctiform load transfer into the subsurface 35 cm thick foam glass layer 8 . This layer is also compressed in a ratio of 1: 1.6. The remaining areas of the construction pit 4 are filled up to the level of the layer compressed in the ratio 1: 1.6 with a foam glass layer 9 , which is compressed in a ratio of 1: 1.3 or 1: 1.6 according to the respective stress. A foil cover serving as a vapor barrier 10 closes off the foam glass layers at the top. The aspiring outer support 20 stands in a support foot 21 , which is arranged on a steel load distribution plate 22 , on the vapor barrier 10 above the foam glass layer 8 . To improve the stability, a mortar leveling 12 is arranged under the load distribution plate 22 between the vapor barrier 10 and the foam glass layer 8 . Furthermore, the load distribution plate 22 for securing against laterally acting forces such. B. wind loads by several ground anchors 23 firmly connected to the load-bearing floor 6 . The industrial floor, consisting of a concrete layer 24 , is arranged between the emerging supports 20 on the vapor barrier 10 above the foam glass layers. The foam glass layer 8 is provided with a broken edge 16 in the peripheral area in front of the outer supports 20 . In the space thus formed between the soil 2 , the outer film cover 17 of the outer edge of the foam glass layer 8 and the column feet 21 or the concrete layer 24 of the industrial floor, an apron 18 made of washing gravel is arranged.

When using aspiring exterior wall components made of wood 25 , the construction pit 4 is designed as in the previous examples. However, in this case according to FIG. 3, a 20 cm thick, 1: 1.6 compressed, continuous foam glass layer 26 is arranged on the roof plan 5 of the excavation pit 4 , on the corresponding to the course of the emerging exterior wall components made of wood 25 and their linear load transfer into the subsurface L-shaped prefabricated concrete parts 27 , the vertical leg of which serves as a support for the wooden components, all around according to the floor plan of the building, on a mortar leveling 12 applied to this foam glass layer 26 in the support area. The emerging outer wall components made of wood 25 are anchored through the L-shaped prefabricated concrete parts 27 and the foam glass layer 26 by means of ground anchors 23 in the load-bearing floor 6 . The space formed within the L-shaped prefabricated concrete parts 27 is filled up to its upper edge with a second foam glass layer 28 compressed in a ratio of 1: 1.3. A film cover, as a vapor barrier 10, covers both the surface of this foam glass layer 28 and the upper edges of the L-shaped prefabricated concrete parts 27 lying in the same plane. The floor, consisting of an impact sound-absorbing layer 14 made of pourable insulating material and an overlying screed compensation layer 15 and on a floor covering 29 laid out thereon, is arranged between the emerging wooden components 25 on the vapor barrier 10 above the foam glass layer 28 . In the peripheral area in front of the L-shaped prefabricated concrete parts 27 there is also an outer foam glass layer 30 compressed in a ratio of 1: 1.3 with an outward slope and an outer foil cover 17 . This film cover is clamped towards the building under a profiled sheet 31 attached to the outside of the L-shaped prefabricated concrete parts 27 . In the space formed between the soil 2 , the outer foil cover 17 of the outer edge of the outer foam glass layer 30 and the emerging leg of the L-shaped prefabricated concrete part 27 , an apron 18 made of washing gravel is arranged.

One possibility of absorbing increased shear forces in the foundation area in the case of particularly thermally insulated buildings is shown in FIG. 4. The structure of the load-absorbing, pressure-absorbing and distributing, insulating foam glass layers corresponds to the structure already described in FIG. 3. Instead of the L-shaped prefabricated concrete parts 27 , however, U-shaped prefabricated concrete parts 32 corresponding to the course of the emerging heat-insulating outer wall components with wooden frames 33 and their linear load transfer into the subsurface all round in accordance with the building plan, on one in the bearing area on the compacted in the ratio 1: 1.6 Layer of foam glass layer 26 applied mortar leveling 12 , set up. A circumferential ring anchor 34 made of reinforced concrete is arranged inside the U-shaped precast concrete parts 32 . In addition, the U-shaped prefabricated concrete parts 32 are anchored through the foam glass layer 26 by means of ground anchors 23 in the load-bearing floor 6 . The space formed within the U-shaped prefabricated concrete parts 32 is filled up to its upper edge with a second foam glass layer 28 compressed in a ratio of 1: 1.3. For particularly high demands on thermal insulation, insulating panels 35 with wooden frames are arranged on the foam barrier 10 forming the 1: 1.3 compressed foam glass layer 28 and the U-shaped precast concrete elements 32 , on which a floor structure made of chipboard 36 and Dry screed 37 is located. The emerging heat-insulated outer wall components with a wooden frame 33 are arranged above the U-shaped prefabricated concrete parts 32 on the load-transmitting outer edges of the insulating panels 35 with a wooden frame. In front of the load-bearing frame of the insulation panels 35 with wooden frames, protective panels 38 are fastened from splash water. The outer film cover 17 is clamped toward the building under a profile plate 31 fastened to the supporting frame of the insulation panels 35 . Here, too, an apron 18 made of washing gravel is arranged in the space formed between the soil 2 , the outer film cover 17, the outer edge of the outer foam glass layer 30 and the outer emerging leg of the U-shaped prefabricated concrete part 32 . List of reference numbers used 1 topsoil
2 soil
3 supernatant
4 construction pit
5 roof planum
6 load-bearing floor
7 drainage
8 foam glass layer
9 foam glass layer
10 vapor barrier
11 outer wall component
12 Mortar leveling
13 floor
14 sound-absorbing layer
15 Screed leveling layer
16 broken edge
17 outer foil cover
18 apron
19 lawn board
20 outer support
21 column base
22 load distribution plate
23 ground anchors
24 concrete layer
25 exterior wall components made of wood
26 continuous foam glass layer
27 L-shaped precast concrete parts
28 foam glass layer
29 flooring
30 outer foam glass layer
31 profiled sheet
32 U-shaped precast concrete parts
33 heat-insulating external wall components with wooden frames
34 ring anchors
35 insulation boards
36 chipboards
37 dry screed
38 aperture

Claims (8)

1. Foundation structure for buildings with load-absorbing insulation, characterized in that an insulating material, which carries all load-bearing components and parts of the, with full-surface training also the entire, arranged between the load-bearing components floor ( 13 ) and that from a heat-insulating, environmentally compatible, load-bearing , -distributing and ablating, closed-cell, pourable and compressible and / or plate-shaped, light material, on which in the founding area for the insulation of buildings meaningful areas, lines and / or points of the structure are arranged horizontally directly on the ground. 2. Foundation structure according to claim 1, characterized in that supporting components by the insulation material is anchored directly in the ground. 3. Foundation structure according to one of claims 1 or 2, characterized in that a circumferential ring anchor ( 34 ) is arranged in the lower region of the up-and-coming, building-defining structural components. 4. Foundation structure according to claim 1 or 2, characterized in that load distribution plates ( 22 ) are arranged between the insulating material and load-bearing or non-load-bearing components. 5. Foundation structure according to claim 1 to 3, characterized in that when using wooden components spacers ( 27 , 32 ), the surfaces facing the outside of which are protected against splashing water, are arranged between the wooden components and the insulating material. 6. Foundation structure according to one of claims 1 to 5, characterized in that the insulating material is arranged with a protrusion ( 3 ) over all outer edges of the building, which has a dimension that ensures frost protection. 7. Foundation structure according to one of claims 1 to 6, characterized in that the Insulation material consists of layers or areas that have different densities exhibit. 8. Foundation structure according to one of claims 1 to 6, characterized in that the Insulation material only in areas with emerging load-bearing components and on the Outside edge of the structure is arranged while the remaining areas of the foundation are made of inferior materials.