DE19801123A1 - Simply-laid foundation structure providing thermal insulation and load bearing capacity - Google Patents

Abstract

A novel base section (1) for a foundation structure, has a generally flat, box-shaped outline and comprises a light concrete material. It has a horizontal underside, two vertical outer sidewalls (3, 4), a top wall (5) running parallel to the underside, a sloping surface (6), and two end walls (7). One sidewall (3) is wider than the other (2). The top surface extends from the top edge of this sidewall (3), over about two thirds the width of the underside. The top and side (4) walls are connected by the sloping surface, which acts as a run-off wall. Also claimed is a foundation. It includes a horizontal, insulating slab base. Rows of base sections as described are laid and filled with intervening cast light concrete, forming a continuous, load-bearing highly-insulating layer. Preferably the hardened light concrete has a bulk density of 200-800 kg/m<3> with a compressive strength of 30-120 t/m<2>. It contains polystyrene granules. The sloping surface is inclined at 20-50 deg with respect to the underside, and there are two parallel grooves (8a, 8b) in the top surface, running along its length, equally spaced about the top centreline. These form rectangular recesses a third to a fifth the height of the base section. One groove is next to the side wall (3) and is spaced about one groove width from it. A second groove (8b) lies adjacent to the common edge formed by the top and sloping surfaces, being about one groove width from it. The grooves have equal width, about one sixth the entire width of the top surface. In one end wall of the section, there are vertical grooves, in the other, corresponding vertical tongues. The tongues and grooves have corresponding dovetail sections.

Description

The invention relates to a foundation structure and a base element for use therein.

It is known for the foundation of a building slab or to use strip foundations. Plate foundations used to pass through the foundation area in poor soil a rigid foundation plate made of reinforced concrete, the quasi eats on the ground and settles unevenly zelner building prevented to enlarge significantly.

Strip foundations are placed under all load-bearing walls of the building first created foundation strips.

To create these foundation strips, the floor on which the building is to be built, first edited so that it is absolutely flat. In the case of basement buildings, this is the case Bottom of the excavation pit and for buildings with no basement ground level. Then in the areas in where the foundation strips are to be created, strip-shaped Excavations or trenches created. In these excavations reinforcements are inserted in a known and customary manner and then the excavations are filled with concrete, whereby Formwork can be provided above the floor, so that the hardened foundation strips about 20 cm above the ground survive. In the areas delimited by the foundation strips  is now usually a rolling, d. i.e., a layer of Gravel or crushed stone, which, after it has compacted with the top edge of the foundation strip. Possibly. can apply a film to the compacted roller coating as moisture protection, especially when there is waterlogging. On the through the Foundation strips as well as the flat surface formed by the curling can now be poured on a base plate in a known manner. After the floor slab hardens, the walls of the building bricked up. Another option is the walls to build directly on the foundation strip and into that of the Wall bounded areas on the floor Pour on the roll. That way, initially created a basement that extends from the outside walls Foundation strips up to the top edge of the floor or Construction pit a so-called perimeter insulation. This perimeter insulation consists for example of foam glass or polymer foams and has the task of masonry, especially in the case of waterlogging to protect existing water.

The base of the foundation must lie so low that it freezes and thawing the bottom layer immediately below does not move. According to DIN 1054, one is considered frost-free Depth of at least 80 cm; in particularly frost-prone areas it can be 1.50 m and more.

With such strip foundations it is disadvantageous that in Thermal bridges often arise over the area of the foundation strip the heat from the building flows into the floor.

In basements in particular, arise in the lower outer edges and corner areas cold zones by tiling away heat, which is why internal insulation is often used in these areas for example, styrofoam can be attached.

GB 2 018 854 A is a strip foundation for stone walls known, in which trapezoidal blocks on a rolling in Area of the walls to be created. This trape  cedar blocks have a wide area in the area of the curling Contact surface, which tapers towards the top, so that above a narrower platform for the support of the bricks is trained. The weight forces acting through the walls are thus distributed over a larger area on the floor. This Trapezoidal blocks should also be easy to read sen.

From US 3,673,750 are curbs for a building foundation known, these curbs at the same time as Schalungsele elements for an insulating layer to be cast under a floor plate te and serve as formwork elements for the floor slab. This Curbs also serve as foundation blocks for the External walls of a building to be built. These curbs are supposed to consist of an insulating concrete. With such a Foundation construction and with such curbs is disadvantageous, that the curbs on the one hand have a supporting function for the Exercise external walls and have an insulating effect should. With a sufficient load-bearing capacity to support the walls curbs, it is not possible to insulate them strongly to be trained, since highly insulating lightweight concrete blocks are only minor Can have load capacities. With such a funda It is therefore not possible to build an optimal thermal insulation to achieve a high load-bearing capacity.

The object of the invention is to create a foundation structure, which is thermally well insulated with a high load capacity.

Another job is to build a foundation that can be created easily and quickly.

In addition, a task is a base element for one to create such a foundation, with which a tragä foundation quickly laid with high thermal insulation and can be created.  

The task is carried out with a foundation structure according to claim 1 solved. Advantageous further developments are in the subclaims featured.

The invention provides, first of all, a curling, that is to say one Leveling fill made of gravel or crushed stone in an excavation pit a basement building or in a shallow pit bring to. This rolling must then be compacted so that it meets the static requirements. On the rollie If necessary, a sealing film can be applied. On this Rol lation or the sealing film are the bases of the invention elements placed loosely in the area of planned walls. This Soc In the simplest case, kel elements are elongated, box-shaped and in cross section essentially rectangular shaped bodies or Blocks. This results in foundation base strips, which are made of individual base elements are constructed. The base elements consist of a lightweight concrete, preferably a styrofoam lightweight concrete. These elements are easy to install, whereby a correction during the laying is possible at any time. The Elements will be arranged where future exterior walls, as well as where partition walls, especially load-bearing partitions walls should be created. In addition, it is possible these base elements also within the outer contours of the building of the foundation or foundation regularly, d. H. in a grid pattern to arrange.

The base elements face in the upward-facing wall at least one longitudinal groove. In the longitudinal grooves of the outer cone Pedestal elements forming the building are upright inserted corner-shaped strip elements, which preferably with a slight pressure in the grooves and over the base elements protrude upwards. The stripe-shaped elements can, for example, up to the top edge of a planned funda with a foundation arranged in a building pit for a building with a basement but also over the top of the Extend the excavation pit and serve as perimeter insulation.  

The areas within the outer contour of the building or Foundations and are limited by the base elements, with a lightweight concrete up to the upper edge of the base elements filled up. The lightweight concrete preferably has the same mate rial properties in terms of density, strength and heat transfer behavior like the concrete from which the base elements are made are made.

The base elements function for this at the construction site filling concrete (also called in-situ concrete) as formwork. As The result is an insulating layer on top of the roller made of lightweight concrete.

Formed from the base elements and the hardened in-situ concrete The insulating plate or layer serves as a base for a concrete base plate to be applied to this. This will after pouring the concrete into the grooves of the outer Soc kelelemente inserted formwork elements limited. The concrete the bottom plate can be in the free grooves of the inside of the Au The outer contour of the base elements flow, causing the hardened bracketing effect. With multiple grooves The concrete can also be inserted into the free grooves of the base element outer elements tile. This base plate can be used in the usual way Wise a building, especially a prefabricated house or block of wood be set up house.

The base plate delimiting and in the outer base elements inserted formwork elements are preferably made of one insulating rigid foam material, which is so firm and is stiff that it withstands the poured concrete and remain on the base plate after the base plate has hardened be liable. These insulating formwork elements fulfill the radio tion of a thermal insulation laterally to the outside if it is as Perimeter insulation on a basement foundation up to the upper canal te of the construction pit are extended.  

In addition, it is possible to use the insulating plate or Iso lierschicht known carrier plates for the heating coils of underfloor heating.

With such a foundation structure, it is advantageous that the Base elements very quickly and easily like a strip fundamentals can be laid and, after a desired Contour was reached and they were connected to each other Gaps filled with insulating lightweight concrete will. This results in terms of heat transfer tes a homogeneous, insulating layer as a base for a base plate to be applied thereon, the base plate also Can contain heating coils for underfloor heating.

In addition, with such a foundation structure of Advantage that this is due to its massive, yet light Structure does not vibrate and thereby the order of a massive Screed layer made possible. It is also an advantage that in the foundation structure according to the invention by the insulated formwork elements put an excellent heat Insulation is achieved to the outside, so that the building is facing down and is insulated on the outside outside. The one in underfloor heating The heat produced does not flow through the outside or through the bottom of the bottom plate.

The invention is illustrated below with reference to the drawing explained. Show it:

Figure 1 shows a cross section through an inventive base element.

Fig. 2 is a plan view of an inventive base member;

Figure 3 shows a cross section through an inventive Funda ment.

4 shows a cross section through a further embodiment of a foundation according to the invention for the use of a floor heating.

Figure 5 is a plan view of an inventive corner base element.

Fig. 6 is a plan view of a T-connec tion base element;

Fig. 7 is a plan view of an intersection base element according to the invention;

Fig. 8 shows a cross section through an inventive Funda element with widened frost bar.

9 shows a further embodiment of a base member according to the invention with a widened strip profile element in a perspective view from above; FIG.

FIG. 10 shows a base element according to FIG. 9 with a further embodiment of a strip profile element in a perspective view from above;

Fig. 11 shows an inventive strip profile element in a perspective view.

A base element 1 according to the invention is a flat box-shaped element with a horizontal bottom wall 2 , a right angled, to this vertical wide side wall 3 and a vertical narrow side wall 4 opposite this parallel.

The wide side wall 3 facing away from the bottom wall 2 has a height or width which is about 2.5 times the width of the narrow side wall. 4 Opposite the bottom wall 2 , with the wide side wall 3 enclosing a right angle, a top wall 5 of the base element 1 . The top wall 5 extends from the side wall 3 in approximately two thirds of the width of the bottom wall 2 . The deck wall 5 and the narrow side wall 4 are connected to one another by a running wall 6 which, for example, is oriented at 30 ° to 50 ° to the bottom wall 2 .

On the end faces, the base element has vertical end walls 7 which enclose a right angle with the bottom wall.

A base element 1 according to the invention has, for example, a width of 60 cm, a length of 100 cm and a height of 25 cm ( FIG. 2).

The top wall 5 has from its transverse center approximately equally spaced two parallel to the longitudinal extension of the base element 1 grooves 8 a, 8 b ( Fig. 2). The grooves 8 a, 8 b are rectangular recesses or recesses which are introduced into the base element 1 by about a third to a fifth of the height thereof. A groove 8 a is arranged adjacent to the wide side wall 3 and spaced from it approximately by the width of the groove 8 a. A second groove 8 b is arranged adjacent to the common edge 9 of the ceiling wall 5 and the drain wall 6 and is spaced therefrom approximately by the width of the groove 8 b. The grooves 8 a, 8 b are preferably of the same width and have a width which corresponds approximately to one sixth of the total width of the ceiling wall 5 .

Such a base element 1 according to the invention consists of a lightweight concrete. Lightweight concretes are concretes that contain a mineral binder, generally cement, and as an aggregate - in contrast to normal concrete - contain an aggregate with a low bulk density. Such a lightweight concrete contains as lightweight aggregate, for example on foamed or expanded polystyrene, but other organic or inorganic, in particular mineral lightweight aggregates can also be used. It is essential for the lightweight aggregate that it has a low thermal conductivity without, however, weakening the compressive strength of the lightweight concrete too much.

A base element 1 according to the invention has a length of 1 m, for example a volume of 0.08 to 0.12 m ³ , the density of the base element being between 200 and 800 kg / m ³ , preferably 400 kg / m ³ . The bulk density of the base element depends on the static requirements, since a light base element has a lower compressive strength than a heavy base element. The compressive strengths of such base elements according to the invention are between 30 and 120 t / m ² , in particular between 50 and 90 t / m ² .

The base elements are preferably of dimensions and of their weight and adjusted so that they can still be laid manually by two people.

A suitable material for manufacturing is, for example a polystyrene lightweight concrete according to the German utility model 91 15 774.9.

The base elements are frost-resistant.

A foundation structure according to the invention or a foundation structure according to the invention ( FIG. 3) is arranged in a shallow trough-shaped construction pit 10 which is introduced into the grown soil 11 . The construction pit 10 is filled up to a third or up to half with a fill 12 or roller 12 made of gravel, crushed stone and the like. In the edge areas of the construction pit 10 , which are not covered by the building to be built, drainage pipes 13 known per se can be laid. With this leveling layer 12 not only a leveling, ie the setting of an equal height level of the top of the curling 12 is achieved, but also the capillaryity of the floor is interrupted. This means that moisture in the floor is not transported through the curling to the underside of the building due to the lack of capillaries. The curling 12 must be compressed.

If the foundation is expected to be loaded from the Soil rising water, especially pressurized water or at Buildings in floodplains are based on the rolling of the entire area, preferably up to the edge of the excavation pit Sealing film applied.

On the curling 12 , the base elements 1 are placed loosely on impact and, if they have been placed, can still be aligned. The base elements 1 are laid according to the course of the planned walls and thus form strip-shaped fun base. In the area of the outer walls 14 of a building to be constructed, the base elements 1 with the drain walls 6 are laid facing the exterior of the building. In the area of the inner walls 15 , the orientation of the drain walls 6 can optionally take place. In the corner areas of the contour, miter-cut base elements 1 can be brought together, but it is also possible to use prefabricated corner elements ( FIG. 5). In addition, crossing elements can be used at crossing points ( Fig. 7) and at branching points, for example, T-shaped branching elements ( Fig. 6). When the base elements 1 are completely installed and aligned, strip profile elements 19 are inserted into the outer grooves 8 b of the outer base forming the outer base elements, with which the individual base elements are connected to one another. The strip profile elements 19 are upright rectangular profiles, which preferably rest with pressure in the grooves 8 b and extend upward beyond the top wall 5 of the base elements 1 .

The base elements 1 can also be provided in the region of their end walls 7 with grooves and tongues, for example with grooves and tongues in the form of a dovetail. This allows the individual base elements 1 to be plugged together in a suitable manner, thereby preventing displacement of the base elements after alignment. Another way to avoid displacement is to clamp the base elements together.

The spaces 17 between the base elements 1 are filled with a lightweight concrete 16 . Light-weight concrete is a concrete that is processed at the installation site, in this case between the base elements 1 is poured. The lightweight concrete is poured up to the height of the ceiling wall 5 between the base elements 1 , and after pouring in, if necessary, is wiped to this height. The lightweight concrete preferably has the same or a similar composition with the same or similar strength properties and raw materials as the concrete material of the base elements 1 . However, the resulting compressive strength does not have to be the same as the compressive strength of the base elements, for example 30 to 60 t / m ² . The bulk density of such a lightweight concrete 16 is between 200 and 400 kg / m ² in the hardened state. The lightweight concrete is, for example, a concrete as described in DE-G-91 15 774.9.

The base elements 1 act as formwork elements for the lightweight concrete 16 .

The base elements 1 and the hardened lightweight concrete 16 result in an insulating layer or plate 18 , which rests on the roller 12 .

The edge regions of the layer or plate 18 have a bevel due to the outward-facing drain walls 6 of the outer base elements 1 . In the, the drain walls 6 neigh disclosed grooves 8 b of the outer contour of the plate 18 delimiting base elements 1 , the narrow, elongated, cross-sectionally rectangular strip elements or formwork profile elements 19 are inserted, which connect the base elements with each other.

The strip or formwork profile elements 19 have a width which corresponds approximately to that of the groove 8 b. The strip elements 19 are inserted into the grooves 8 b in a butt joint and with slight pressure. The height of the strips or formwork profile element 19 is chosen so that the upper edge 20 corresponds at least to the upper height level of the planned foundation or a base plate still to be poured on. It is, for example, 5 to 6 times the width of the strip element 19 and is, for example, 20 to 30 cm above the base element upwards. In the case of base elements which are installed in a basement foundation, the formwork profile elements 19 can extend over the upper edge of the construction pit, in particular thus 2 to 3 m. If the formwork profile elements 19 reach with their upper edge 20 up to the height of an upper edge of a base plate, the formwork profile elements enclose a flat, angular trough-shaped space 27 between them and tightly delimit it.

The strip profile elements 19 are preferably made of a thermally insulating polymer foam, for example an extruded polystyrene foam profile or comparable elements made of thermal insulation materials such as polyurethane foam or foam glass. The width of the strips or formwork profile elements 19 depends essentially on the desired heat-insulating effect. Accordingly, the width of the grooves 8 b must be adapted to the width of the strip or formwork profile elements.

In a further embodiment of the strip profile element 19 upwardly through the groove 8 b out projecting part is a formed thicker 19, whereby this part is adapted to flow wall 6 towards or to the groove 8 a back or for the out-flow wall and the groove 8 a down before jumping. As a result, in particular better insulation of a base plate to be poured on, but also an increased rigidity of the strip profile element 19 is achieved. In addition, base elements with consistently wide grooves 18 b can be used for strip profile elements 19 of different widths. Such strips profile elements 19 may in the wide part 19 a, at the abutting edges of the strip profile elements 19 via grooves 19 b and springs 19 add c ver. In addition, corner element strip profile elements 19 d can be provided for the corners of a foundation. In order to achieve a better frictional connection with the concrete floor slab, the strip profile elements 19 can have dovetail grooves 19 e on the inside. Grooves, in particular swallows, tail grooves can also be provided on the outside of the strip profile elements 19 , for example in order to insert decorative elements into these grooves.

On the layer or plate 18 usual reinforcement 22 for example in the form of reinforcing iron, grids or meshes can be inserted in the space 21 defined by the formwork profile elements 19 for a floor concrete slab ( Fig. 3). The reinforcement 22 can be laid over the entire area or in certain areas, for example the reinforcement can be placed in the area of the base elements 1 ( FIG. 3). In addition, if desired, supply lines which are to run in the ground can be placed on the layer 18 in a manner known per se.

To the upper edge 20 of the strip profile elements 19 a screed or concrete is poured into the formwork of the or Streifenpro filelementen 19 confined space 21st The poured concrete can, for example, be a conventional concrete of strength class B35, ie with a nominal strength of 35 N / mm ² after 28 days.

The poured screed or concrete results in a hardened state a concrete floor slab 23 which is delimited from the outside by the formwork elements or strip profile elements 19 . The concrete also flows into the free grooves 8 a, 8 b of the base elements 1 , whereby the hardened concrete floor slab 22 is in engagement with the insulating layer or plate 18 .

The concrete floor slab 23 is preferably cast in one piece, that is to say monolithically, so that the finished concrete floor slab has no joints. In the stiffened but not yet hardened state, the concrete floor slab can be smoothed, for example, with a smoother, in particular a wing smoother, so that the surface can be used as a floor or underlay for a floor covering without further major finishing work.

In the case of strip profile elements 19 extending upwards beyond the construction pit as perimeter insulation, the concrete is not poured in up to the upper edge 20 , but only at the height desired for a base plate, in particular 20 to 30 cm.

On this concrete floor slab 23 , the walls 14 , 15 , in particular lightweight walls, of prefabricated or wooden block houses can be set up and fastened in a conventional manner known per se.

The outer walls 14 close with their outer side 25 with the, limited by the formwork elements 19 outer side 26 of the Betonbo denplatte 23 . Au is a ßenputz or outer covering 27, for example a heat-insulating and water-repellent coating 27 applied, for example, a thermal insulation system on the outside wall 25 of the fourteenth

The covering or plaster 27 has, for example, a thickness which is greater than the width of the formwork strips 19 and thus projects outward beyond the formwork strips 19 . With its lower edge 28 , the plaster or covering 27 is in contact with the upper edge 20 of the formwork elements 19 , wherein the lower edge 28 of the plaster 27 can be formed by a U-shaped rail 29 and be limited.

Since the formwork strips or strip profile elements 19 are not removed, but are retained as insulation, they can be provided on the outside with a decor, for example a colored wall clinker decor, which at the same time takes over protection tasks.

In a further advantageous embodiment of a foundation according to the invention ( FIG. 4), carrier plates 32 for underfloor heating lines 33 are placed on the insulating plate 18 . These carrier plates 32 are plate-shaped elements, for example made of plastic, in particular rigid foam plates. On the upper side, the carrier plates 32 have integrally formed clamping knobs 34 for the heating lines 33 , between which the heating lines 33 can be clamped.

In order to facilitate the assembly of the plates 32 , strip-shaped elements 35 can be inserted into the grooves 8 a of the outer base elements 1 and into the grooves 8 a, 8 b of the inner base elements 1 . The strip-shaped elements 35 can, for example, consist of the same material as the formwork elements 19 , in particular of rigid foam. The elements 35 have a width which corresponds to that of the groove 8 a, 8 b and have a height which is selected so that the rigid foam elements 35 extend beyond the top wall 5 of the base elements 1 to such an extent that their upper edge 36 with the highest area of the carrier plate 32 completes.

By the strip-shaped elements 35 , the surface of the plate 18 is divided into narrow compartments 37 between the grooves 8 of a Soc kelelements 1 and wide compartments 38 between adjacent Soc kelelemente 1 .

The base elements 1 can be routed regularly, grid-like, so that quadrangular compartments 38 of the same size who formed the.

Reinforcements 22 can be inserted into the narrow compartments 37 , the carrier plates 32 are inserted into the wide compartments 38 . In the wide compartments 38 only one carrier plate 32 ( FIG. 4) or, if the compartment size is sufficient, several carrier plates 32 can also be inserted. The carrier plates 32 have a size of, for example, 0.5 × 1 m.

In a further advantageous embodiment, the strip-shaped elements 35 are formed in one piece with the carrier plates 32 on their outer edges. The carrier plates 32 can thus be inserted directly with the elements 35 into the grooves ( 8 a, 8 b) and anchored to the insulating plate 18 . A concrete or screed is poured into the space defined by the strip profile elements 19 space 21 to the upper edge 20 of the strip profile elements on the provided with heating coils such support plates 32 and reinforcements 22 provided insulating 18th The concrete or screed is preferably a concrete specially designed for the use of underfloor heating.

When the concrete is poured into the space 21 delimited by the strip profiling elements 19, the strip-shaped elements 35 ensure that the carrier plates 32 cannot slip. In addition, the strip-shaped elements 35 seal the edge region of the carrier plates 32 downward, so that no concrete can get under the carrier plates 32 . Because of the low density of the carrier plates 32 , they would otherwise float on the concrete.

The walls 14 , 15 are also set up in a known and described manner on a concrete floor slab 23 produced in this way.

In a further advantageous embodiment of a foundation structure according to the invention, the entire insulating layer or plate 18 is built up from base elements 1 . In one of the like embodiment, for. B. the outer contours of the plate 18 with base elements 1 with outward-facing drain wall 6 may be formed. The space delimited by these base elements 1 is then designed to cover the entire surface with further base elements, wherein these base elements can also be rectangular in cross section. Preferably, the base elements 1 for the formation of a complete ver layer 18 on their side walls grooves and tongues, for example in the form of dovetail guides, so that the base elements can be plugged together. Another option is to glue the base elements together using a thin-bed mortar or a tile adhesive. Such an arrangement is meaningful at high surface loads, since the base elements 1 have a higher compressive strength than the lightweight concrete.

The outside of the outer base elements 1 remaining space 40 of the construction pit 10 is filled with gravel, gravel or excavation up to the upper edge 41 of the grown soil 11 , the upper edge 42 of the backfill 43 preferably being higher than the outwardly projecting section of the ceiling wall 5 outer base elements 1, so that the base elements 1 are not visible from the outside. Preferably, a sealing film 44 is placed on the edge region of the foundation in such a way that the sealing film 44 extends from the top edge 42 of the backfill 43 or a piece above, on the outside of the formwork elements 19 adjacent to the ceiling wall 5 of the outer base elements 1 and extends from these over the drain walls 6 , the narrow side wall 4 on the sen lying on the lower outer edge of the base element 1 extends. From this, the sealing film 44 runs on the upper surface of the curling 12 to the edge of the pit or to the drainage pipes 13 laid . The sealing film 44 can also be clamped ge when inserting the formwork or strip profile elements 19 into the grooves 8 b with the strip profile elements 19 in the groove 8 b.

From the outer wall 15 or the outer plaster 27 running water first reaches the backfill 43 and runs along the film 44 over the drain walls 6 laterally into the backfill 43 and to the edge of the construction pit 10 or is led to the drainage pipe 13 . The water is thus advantageously led away from the building by the outer contour or shape of the base elements 1 .

This outer contour or shape of the base elements 1 , which projects, for example, 30 cm, but optionally also more outwards beyond the actual foundation, functions as a so-called frost apron or so-called frost bar. These frost bars or frost aprons have the task of protecting the ground beneath them from the frost from frost. The influence of frost in these foundation areas is particularly damaging, since freezing and thawing the immediately underlying soil layers and the associated expansion and contraction can cause the foundation floor to move, which can lead to subsidence in this area. Advantageously, a particularly effective shielding of the foundation sole from frost is achieved by the inventive design of the base element with an outwardly projecting frost bar and by the thermally well-insulating material of the base element.

In a further advantageous embodiment of a foundation structure according to the invention, an additional frost bolt 50 is arranged on the outside on the outer base elements 1 . This frost bar 50 is, for example, a rigid polymer foam plate, for example a polystyrene foam plate ( Fig. 8) This plate preferably has a height that corresponds to the outwardly facing narrow side wall 4 of the base element 1 and extends for example by half a meter to the outside, ie to the edge of the pit. The upward-facing surface of this additional frost bar can be seen with a trough-shaped indentation 51 running parallel to the foundation, so that this expanded frost bar 50 can also perform water-removing functions. The invention thus advantageously creates a foundation structure, which is highly iso liert, whereby a trough-like insulation is achieved by the sole-side arrangement of the insulating plate 18 and the inserted into the grooves 8 b strip elements 19 , which has no thermal leaks. In the case of strip elements 19 , which are designed as perimeter insulation extended to above the upper edge of a construction pit, the entire basement is thus surrounded by a trough-shaped, heat-leak-free insulating layer.

Another advantage with a foundation structure according to the invention with the frost bar according to the invention is that the frost protection the base of the foundation is so well developed that not the basement of the basement is not up to the in State of the art usual depths must be sunk, but the foundation sole can be arranged closer to the surface.

The invention thus creates stable, highly stable fun dam for buildings, especially lightweight buildings such as prefabricated houses water and wooden houses, which is well insulated and thermally for installing underfloor heating with minimal heat loss suitable and also with little effort in a short time can be created.

For example, such a foundation can be built in two days poses.

Claims (48)

1. Foundation with a horizontal insulating layer or plate, the insulating layer or plate ( 18 ) has base elements ( 1 ) which form strip-shaped, from abutting base elements ( 1 ) built up foundation strips and the ten from the base elements ( 1 ) Built-up foundation strips delimit rooms ( 17 ), the rooms ( 17 ) being filled with lightweight concrete ( 16 ) so that a continuous, stable, highly insulating layer is formed, with a concrete floor slab ( 23 ) on the highly insulating layer. is arranged on, and on the concrete floor slab ( 23 ) walls of buildings can be built or set up and fastened. 2. Foundation structure according to claim 1, characterized in that the concrete floor slab ( 23 ) is formed in one piece or monolyte, so that the finished Betonbo denplatte ( 23 ) has no joints. 3. Foundation structure according to claim 1 and / or 2, characterized in that in the concrete floor slab ( 23 ) a floor heating is arranged. 4. Foundation structure according to one or more of claims 1 to 3, characterized in that the base elements ( 1 ) in the ceiling wall ( 5 ) have two grooves parallel to the longitudinal extension of the base element ( 1 ) ( 8 a, 8 b), wherein in the grooves ( 8 b) of the foundation-limiting base elements ( 1 ) strip elements or strip-shaped formwork profile elements ( 19 ) are inserted so that they enclose between them a square trough-shaped space ( 21 ) for a floor to be cast plate ( 23 ) and limit tightly, the height of the strip or formwork profile elements ( 19 ) being matched to the desired height of the base plate ( 23 ) and being chosen such that the upper edge ( 20 ) corresponds to the upper height level of the planned foundation. 5. Foundation structure according to one or more of claims 1 to 4, characterized in that the height of the strip or formwork profile elements ( 19 ) in a basement foundation corresponds approximately to the height of the basement, whereby the formwork profile elements form a perimeter seal on the outside of basement outer walls. 6. Foundation structure according to one or more of claims 1 to 5, characterized in that the strip or formwork profile elements ( 19 ) have a width which corresponds approximately to the groove ( 8 b). 7. Foundation structure according to one or more of claims 1 to 5, characterized in that the upwardly above the groove ( 8 b) projecting part ( 19 a) of the strip profile element ( 19 ) is formed thicker than the part of the stuck in the groove Strip profile elements ( 19 ), whereby the part ( 19 a) is designed to protrude towards the drain wall ( 6 ) or towards the groove ( 8 a) or towards the drain wall and towards the groove. 8. Foundation structure according to one or more of claims 1 to 7, characterized in that the strip profile elements ( 19 ) on the abutting edges of the strip profile elements ( 19 ) have grooves ( 19 b) or springs ( 19 c). 9. Foundation structure according to one or more of claims 1 to 8, characterized in that in the corner areas of a foundation over corner verlau fende corner element strip profile elements ( 19 d) are arranged. 10. Foundation structure according to one or more of claims 1 to 9, characterized in that the strip profile elements ( 19 ) in the angular tub-shaped space ( 21 ) enclosing walls swallows have tail grooves ( 19 e) in order to ensure a better adhesion with the concrete floor slab ( 23 ) to achieve. 11. Foundation structure according to one or more of claims 1 to 10, characterized in that on the outside of the strip profile elements ( 19 ) Nu ten, in particular dovetail grooves are arranged. 12. Foundation structure according to one or more of the preceding claims, characterized in that the strip profile elements ( 19 ) consist of a thermally insulating polymer hard foam. 13. Foundation structure according to claim 12, characterized in that the strip profile elements ( 19 ) consist of an extruded rigid polystyrene foam. 14. Foundation structure according to one or more of the preceding claims, characterized in that the space ( 21 ) which is laterally enclosed by the formwork profile elements ( 19 ) is filled with a concrete or screed to the level of a desired concrete floor slab, so that the concrete floor slab ( 23 ) on the insulating plate ( 18 ) is formed lying. 15. Foundation construction according to one or more of the preceding Expectations, characterized, that the lightweight concrete is a polystyrene concrete. 16. Foundation structure according to one or more of the preceding claims, characterized in that the hardened lightweight concrete has a density of 200 to 400 kg / m ³ . 17. Foundation structure according to one or more of the preceding claims, characterized in that the hardened lightweight concrete has a compressive strength of 30 to 90 t / m ² . 18. Foundation structure according to one or more of the preceding claims, characterized in that the base elements ( 1 ) and the hardened lightweight concrete ( 16 ) form an insulating layer or plate ( 18 ) which on a in a building pit ( 10 ) arranged roller ( 12 ) or compensating layer ( 12 ) or a sealing film applied to the rollie is arranged lying thereon. 19. Foundation structure according to one or more of the preceding claims, characterized in that the base elements ( 1 ), which are located on the outer sides of the insulating plate ( 18 ), with the drain walls ( 6 ) are arranged facing outward. 20. Foundation structure according to one or more of the preceding claims, characterized in that in the drain walls ( 6 ) adjacent grooves ( 8 b), the outer contour of the plate ( 18 ) delimiting base elements ( 1 ) narrow, elongated, in cross section upright rectangular strip elements (19) or shuttering profile elements (19) are inserted. 21. Foundation structure according to one or more of the preceding claims, characterized in that the formwork profile elements ( 19 ) on the bottom plate te ( 23 ) facing away are provided with a decor. 22. Foundation structure according to one or more of the preceding claims, characterized in that in the concrete floor slab ( 23 ) in the area of the base elements ( 1 ) the reinforcements ( 22 ) customary for concrete floor slabs are arranged. 23. Foundation structure according to one or more of the preceding claims, characterized in that the reinforcements ( 22 ) are arranged in the concrete floor slab ( 23 ) inserted. 24. Foundation structure according to one or more of the preceding claims, characterized in that on the insulating plate ( 18 ) support plates ( 32 ) for foot floor heating lines ( 33 ) are arranged, wherein the support plates ( 32 ) are plate-shaped elements, the top receiving devices ( 34 ) for Heizlei lines ( 33 ), in which the heating lines ( 33 ) are arranged inserted. 25. Foundation structure according to claim 24, characterized in that strip-shaped elements ( 35 ) in the grooves ( 8 a) of the outer base elements ( 1 ) and in the grooves ( 8 a, 8 b) of the inner base elements ( 1 ) are arranged, wherein the elements ( 35 ) have a width which corresponds to that of the groove ( 8 a, 8 b) and a height which is chosen so that the elements ( 35 ) over the ceiling wall ( 5 ) of the base elements ( 1 ) as far stand out that their upper edge ( 36 ) with the highest area of the insulating plate ( 18 ) placed on the support plate ( 32 ) ends. 26. Foundation structure according to claim 24 and / or 25, characterized in that the elements ( 35 ) the surface of the plate ( 18 ) in narrow compartments ( 37 ) between the grooves ( 8 ) one and the same base element ( 1 ) and other compartments ( 38 ) between adjacent base elements ( 1 ). 27. Foundation structure according to one or more of claims 24 to 26, characterized in that the elements ( 35 ) consist of a polymer foam. 28. Foundation structure according to one or more of claims 24 to 27, characterized in that reinforcements ( 22 ) are arranged in the narrow compartments ( 37 ). 29. Foundation structure according to one or more of claims 24 to 28, characterized in that the carrier plates ( 32 ) are arranged inlaid in the further compartments ( 38 ). 30. Foundation structure according to one or more of claims 24 to 29, characterized in that the hard foam elements ( 35 ) are integrally formed on the outer edges of the carrier plates ( 32 ). 31. Foundation structure according to one or more of claims 24 to 30, characterized in that the space ( 21 ) bounded by the formwork profile elements ( 19 ) is filled with a screed or concrete up to the upper edge ( 20 ) of a desired base plate ( 23 ), wherein form the hardened screed or concrete of the concrete floor slab ( 23 ). 32. foundation structure according to claim 31, characterized, that the screed or concrete is using one in it underfloor heating is matched. 33. Foundation structure according to one or more of the preceding claims, characterized in that the outside of the outer base elements ( 1 ) remaining space ( 40 ) of the excavation pit ( 10 ) with gravel, crushed stone or excavation up to the upper edge ( 41 ) of the grown soil ( 11 ) is backfilled. 34. Foundation structure according to one or more of the preceding claims, characterized in that a sealing film ( 44 ) is placed on the edge region of the foundation structure so that the sealing film ( 44 ) from the upper edge ( 42 ) of the backfill ( 43 ) or a piece above on the outside of the Schalungsele elements ( 19 ) adjacent to the ceiling wall ( 5 ) of the outer base elements ( 1 ) and from these over the drain walls ( 6 ), the narrow side walls ( 4 ) lying on these to the lower outer edge of the Socket elements ( 1 ) extends. 35. Foundation structure according to one or more of claims 1 to 33, characterized in that the sealing film ( 44 ) with the formwork profile elements ( 19 ) in the groove ( 8 b) is clamped so that the sealing film ( 44 ) from the groove ( 8 b) on the ceiling wall ( 5 ) extends outwards and extends from the ceiling wall ( 5 ) over the drain wall ( 6 ), the narrow side walls ( 4 ) lying on these to the lower outer edge of the base element ( 1 ) extends. 36. Foundation structure according to claim 34 or 35, characterized in that the sealing film ( 44 ) from the lower outer edge of the outer base elements ( 1 ) on the surface of the Rollie tion ( 12 ) to an edge region of the construction pit ( 10 ) or to be relocated Drainage pipes ( 13 ) run so that water running out of the outer wall ( 15 ) first comes from the filling ( 43 ) and along the foil ( 44 ) over the drain walls ( 6 ) laterally into the backfill ( 43 ) and to the edge of the excavation pit ( 10 ) or to the drainage pipes ( 13 ) is derived. 37. Base element ( 1 ) for a foundation structure, in particular a foundation structure according to one or more of claims 1 to 30, wherein the base element ( 1 ) is flat kastenför shaped and the base element ( 1 ) consists of a hardened lightweight concrete, the flat kastenför shaped base element ( 1 ) has a horizontal bottom wall ( 2 ), two vertical side walls ( 3 , 4 ), a horizontal ceiling wall ( 5 ) running parallel to the bottom wall, a drain wall ( 6 ) and two end walls ( 7 ), the Drain wall ( 6 ) drops from the top wall ( 5 ) to one of the side walls ( 3 ) with an inclination relative to the top wall ( 5 ) and the top wall ( 5 ) is approximately equally spaced from its transverse center by two grooves running parallel to the longitudinal extension of the base element ( 1 ) ( 8 a, 8 b). 38. Base element according to claim 37, characterized in that the lightweight concrete has a bulk density of 200 to 800 kg / m ³ in the hardened state. 39. Base element according to claim 37 and / or 38, characterized in that the compressive strength of the lightweight concrete is between 30 and 120 t / m ² . 40. Base element according to one or more of claims 37 to 39, characterized, that the lightweight concrete is a polystyrene lightweight concrete, which Contains polystyrene granules as light aggregate. 41. Base element according to one or more of claims 37 to 40, characterized in that the side wall of 20 ° to 50 ° relative to the bottom wall ( 2 ) is oriented inclined. 42. Base element according to one or more of claims 37 to 41, characterized in that the grooves ( 8 a, 8 b) are rectangular recesses or recesses which by a third to a fifth of the height of the base element ( 1 ) in this are introduced. 43. Base element according to one or more of claims 37 to 42, characterized in that a groove ( 8 a) adjacent to the side wall ( 3 ) is net and spaced from this approximately by the width of the groove ( 8 a) and a second groove ( 8 b) is arranged adjacent to a common edge ( 9 ) of the ceiling wall ( 5 ) and the drain wall ( 6 ) and is spaced therefrom approximately by the width of the groove ( 8 b). 44. Base element according to one or more of claims 37 to 43, characterized in that the grooves ( 8 a, 8 b) are of equal width and have a width which corresponds approximately to one-sixth of the entire width of the ceiling wall ( 5 ) . 45. Base element according to one or more of claims 37 to 44, characterized in that the base element in an end wall ( 7 ) vertically extending grooves and in the opposite Stirnwan extension ( 7 ) has vertically extending springs for grooves. 46. Base element according to one or more of claims 37 to 45, characterized, that the grooves undercut dovetail-shaped leads and the feathers are a corresponding swallow have tail shape.   47. Base element according to one or more of claims 37 to 46, characterized in that the base element ( 1 ) has a length of about 0.5 m to 1.5 m and / or a width of 0.4 m to 1 in and / or has a height of 0.1 in to 0.5 m. 48. Base element according to one or more of claims 37 to 47, characterized in that the base element ( 1 ) has a volume of 0.05 m ³ to 0.15 m ³ .