DE19801123B4 - Foundation structure and base element for use therein - Google Patents

Abstract

Foundation structure with a horizontal insulating layer or plate, the insulating layer or plate (18) having base elements (1) which form strip-shaped foundation strips made up of butted base elements (1) and the foundation strips made up of the base elements (1) form spaces (17) delimit, the spaces (17) being filled with a lightweight concrete (16) so that a continuous, load-bearing, highly insulating layer is formed, a concrete floor slab (23) being arranged on the highly insulating layer, and on the concrete floor slab (23) walls of buildings can be built or erected and fastened.

Description

The invention relates to a foundation structure as well as a base element for the use in it.

It is known for the foundation of one building Slab or strip foundations to use. Slab foundations are used to help with bad Soil through the foundation area a rigid foundation slab made of reinforced concrete, so to speak floats on the ground and prevents uneven settlement of individual buildings, to enlarge significantly.

In the case of strip foundations, under all load-bearing walls of the building first Foundation strips created.

To create these foundation strips, the floor on which the building to be built, initially edited so that he is absolutely flat. In buildings with a basement, this is on the sole of the excavation pit and, in the case of buildings with no basement, executed on level ground. Then be in the areas where the foundation strips are to be created, strip Excavations or trenches created. In these excavations are known and more common Wise reinforcements are inserted and then the excavations filled with concrete, whereby formwork can be provided above the floor, so that the hardened foundation strips about 20 cm above survive the ground. The areas delimited by the foundation strips are now usually used a rolling layer, i.e. a layer of gravel or crushed stone, which after it has been compacted, with the top edge of the foundation strips concludes. Possibly. a film can be applied to the compacted roller coating as moisture protection, especially in case of waterlogging, be put on. On the through the foundation strips as well as the Rolling formed flat surface can now be poured on a base plate in a known manner. After hardening the bottom plate becomes the walls of the building bricked up. One more way consists of building the walls directly on the foundation strip and individual floor slabs in the areas delimited by the walls to pour on the roll. That way, initially created a basement, extends on the outer walls of the foundation strips to over the top edge of the floor or the construction pit is a so-called perimeter insulation. This perimeter insulation consists for example of foam glass or polymer foams and especially in case of waterlogging the task of protecting the masonry from water.

The base of the foundation must be so deep that they lie by freezing and thawing the immediately below Bottom layer does not move. After is considered frost-free DIN 1054 a depth of at least 80 cm; in areas particularly exposed to frost it can be 1.50 m and more.

With such strip foundations is disadvantageous in that Area of the foundation strip often creates thermal bridges over which the heat out of the building flows into the ground.

Especially in basements in the lower outer edges and corner areas cold zones by tiling heat, which is why in these areas, for example, often internal insulation Styrofoam can be attached.

From the GB 2 018 854 A is a strip foundation for stone walls is known, in which trapezoidal blocks are placed on a roller in the area of the walls to be created. These tra pezohedral blocks have a wide contact surface in the area of the curling, which tapers towards the top, so that a narrower platform is formed at the top for supporting the building bricks. The weight forces acting through the walls are thus distributed over a larger area on the floor. These trapezoidal blocks should also be easy to lay.

From the US 3,673,750 curbs for a building foundation are known, these curbs simultaneously serving as formwork elements for an insulating layer to be cast under a floor slab and as formwork elements for the floor slab. These curbs also serve as foundation blocks for the outer walls of a building to be constructed. These curbs should consist of an insulating concrete. With such a foundation structure and with such curbs, it is disadvantageous that the curbs on the one hand should have a supporting function for the outer walls and on the other hand should have an insulating effect. If the curbs have sufficient load-bearing capacity to support the walls, it is not possible to make them highly insulating, since highly insulating lightweight concrete blocks can only have low load-bearing capacities. With such a foundation structure, it is therefore not possible to achieve optimal heat insulation with a high load-bearing capacity.

The object of the invention is a To create a foundation that is thermally good with a high load capacity isolated.

Another job is to get one To create foundation structure that can be created easily and quickly can.

In addition, a task a base element for to create such a foundation structure with which a stable foundation with high thermal insulation can be quickly installed and created can.

These tasks are solved with regard to one Foundation construction by the features of claim 1 and with regard a base element by the features of claim 37. Advantageous further developments are in the subclaims specified.

The invention provides, first of all Rolling, i.e. a leveling fill made of gravel or crushed stone in an excavation pit in a basement building or in a shallow pit applied. This rolling must then be compressed so that it meets the static requirements. On the curling can if necessary, a sealing film can be applied. On this rolling or the sealing film, the base elements according to the invention become loose in the area planned walls hung up. In the simplest case, these Sokel elements are elongated, boxy and in cross section essentially rectangular shaped bodies or Blocks. This results in foundation base strips, which consist of individual Base elements are constructed. The base elements consist of a lightweight concrete, preferably from a polystyrene lightweight concrete. This Elements can be easily installed, with a correction during the Laying possible at any time is. The elements are arranged where future exterior walls will be, as well even where partition walls especially load-bearing partitions should be created. About that furthermore it is possible these base elements also within the outer contours of the building or of the foundation regularly, d. H. to be arranged in a grid pattern.

The base elements point in the upward-facing side at least one longitudinal groove. In the longitudinal grooves the the outer contour of the building forming base elements become upright rectangular strip elements inserted, which preferably with a slight pressure in sit and over the grooves the base elements protrude upwards. The stripe-shaped elements can, for example up to the top of a planned foundation, one in one However, excavation pit arranged foundation for a building with a basement to over extend the upper edge of 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 refilled. The lightweight concrete preferably has the same material properties in terms of Density, strength and heat transfer behavior on like the concrete from which the sock elements are made.

The base elements function for this to be filled in at the construction site Concrete (also called in-situ concrete) as formwork. As a result an insulating layer or plate resting on the curling Lightweight concrete achieved.

The from the base elements and the hardened Insulating plate or insulating layer formed on site serves as a base for one on this concrete floor slab to be applied. This is after the pour in of the concrete in the grooves of the outer base elements inserted formwork elements limited. The concrete of the floor slab can in the free grooves of the base elements lying within the outer contour flow, whereby in the hardened Condition is caused. With several grooves per Base element, the concrete can also be in the free grooves of the outer elements tiles. A building, in particular, can be placed on this base plate in the usual way a prefabricated house or wooden block house can be erected.

The bounding the base plate and in the outer sock elements inserted formwork elements are preferably made of an insulating rigid foam material made, which is so strong and stiff that it withstands the poured concrete and after hardening the base plate sticks to the base plate. These insulating formwork elements fulfill the function of thermal insulation sideways outwards, when used as perimeter insulation with a basement foundation up to The top edge of the excavation is extended are.

In addition, it is possible to the insulating plate or insulating layer known carrier plates for the Heating coils of underfloor heating hang up.

With such a foundation structure is advantageous that the Base elements very quickly and easily in the manner of a strip foundation can be relocated and, after a desired Contour was reached and they were connected to each other interspaces be filled with an insulating lightweight concrete. This gives yourself regarding the heat transfer value a homogeneous, insulating layer as a base for one on top base plate to be applied, the base plate also heating coils for one underfloor heating may contain.

In addition, such Foundation construction is advantageous that this due to its massive, yet light construction, it does not swing and this enables the application of a solid screed layer. About that is also an advantage that at the foundation structure according to the invention excellent thanks to the inserted insulating formwork elements Thermal insulation after Outside is achieved so that building down and down outside is insulated. The one in underfloor heating produced heat flows therefore not over the outside or through the bottom of the bottom plate.

The invention is illustrated below the drawing exemplified. Show it:

1 a cross section through a base element according to the invention;

2 a plan view of a sock element according to the invention;

3 a cross section through a foundation according to the invention;

4 a cross section through a further embodiment of a foundation according to the invention for the use of an underfloor heating;

5 a plan view of an inventive corner base element;

6 a plan view of an inventive T-connection base element;

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

8th a cross section through an inventive foundation with widened frost bar.

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

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

11 an inventive strip profile element in a perspective view.

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

The broadside 3 points from the bottom 2 a height or width that is about 2.5 times the width of the narrow side 4 is. Across the floor 2 runs with the broadside 3 including a right angle a ceiling side 5 of the base element 1 , The ceiling side 5 extends from the broadside 3 about two-thirds the width of the bottom 2 , The ceiling side 5 and the narrow side 4 are through a drain page 6 connected to each other, which, for example, inclined by 30 ° to 50 ° to the bottom side 2 is oriented.

On the front side, the sock element has a vertical front side that forms a right angle with the bottom side 7 on.

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

The ceiling side 5 has approximately equally spaced from its transverse center two parallel to the longitudinal extent of the base element 1 running grooves 8a . 8b on ( 2 ). The grooves 8a . 8b are rectangular recesses or recesses that are about a third to a fifth of the height of the base element 1 are brought into this. A groove 8a is on the broadside 3 arranged adjacent and from this about the width of the groove 8a spaced. A second groove 8b is to the common edge 9 the ceiling side 5 and the drain page 6 arranged adjacent and from this about the width of the groove 8b spaced. The grooves 8a . 8b are preferably of the same width and have a width which is approximately one sixth of the total width of the ceiling side 5 equivalent.

Such a base element according to the invention 1 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, for example, foamed or expanded polystyrene as the lightweight aggregate, although 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 according to the invention 1 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 preferred of in their dimensions as well as their weight and set them still by hand by two people can be relocated.

A suitable material for the production 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 ( 3 ) is in a shallow trough-shaped excavation pit 10 which in the grown soil 11 is introduced. The excavation pit 10 is up to a third or up to half with a filling 12 or rolling 12 filled up with 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, can be known drainage pipes 13 be misplaced. With this leveling layer 12 is not just a leveling, that is, setting an equal height level of the top of the curling 12 reached, but also interrupted the capillarity of the soil. 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 rolling 12 must be condensed.

If the foundation is expected to be exposed to water rising from the ground, in particular pressurized water or in the case of buildings in flood areas, the curling is applied a sealing film is placed over the entire surface, preferably up to the edge of the excavation pit.

On the rolling 12 become the base elements 1 placed loosely on the butt and can still be aligned once they have been placed on. The base elements 1 are laid according to the course of the planned walls and thus form strip-like foundation bases. In the area of the outer walls 14 The base elements of a building to be created 1 with the expiration pages 6 laid facing the building exterior. In the area of the inner sides 15, the orientation of the outlet sides can be 6 optionally done. Miter-cut plinth elements can be used in the corner areas of the contour 1 on top of each other, but it is also possible to use prefabricated corner elements ( 5 ) to use. In addition, crossing elements ( 7 ) and at branch points, for example T-shaped branch elements ( 6 ) be used. If the base elements 1 are installed and aligned, are in the outer grooves 8b the outer base elements forming the outer contour, strip profile elements 19 with which the individual base elements 1 be connected to each other. The strip profile elements 19 are upright rectangular profiles, which are preferably pressed in the grooves 8b rest and look up over the ceiling side 5 the base elements 1 extend out.

The base elements 1 can also in the area of their end faces 7 be provided with grooves and tongues, for example with grooves and tongues in dovetail shape. This allows the individual base elements 1 plug together in a suitable manner, causing a displacement of the base elements after alignment 1 is prevented. Another way to avoid displacement is the base elements 1 to cling to each other.

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

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

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

The edge areas of the layer or plate 18 point through the outward-facing discharge sides 6 the outer base elements 1 a bevel. In the, the discharge pages 6 adjacent grooves 8b the outer contour of the plate 18 delimiting base elements 1 , are the narrow, elongated stripe elements or formwork profile elements with a rectangular cross section 19 inserted which the base elements 1 connect with each other.

The strip or formwork profile elements 19 have a width which is approximately that of the groove 8b equivalent. The stripe elements 19 are in the grooves 8b plugged in butt and with slight pressure. The height of the strips or formwork profile element 19 is chosen so that the top edge 20 corresponds at least to the upper level of the planned foundation or a floor slab still to be poured on. For example, it is 5 to 6 times the width of the strip element 19 and stands, for example, 20 to 30 cm above the base element 1 upwards. For base elements 1 , which are installed in a basement foundation, the formwork profile elements 19 up to the top of the excavation pit 10 extend, in particular 2 to 3 m. Are the formwork profile elements sufficient 19 with their top edge 20 up to the height of an upper edge of a floor slab, enclose the formwork profile elements 19 a flat, angular tub-shaped space between them 27 sideways and tightly delimit it.

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

In a further embodiment of the strip profile element 19 is the up over the groove 8b protruding part 19a formed thicker, causing this part to the drain side 6 towards or towards the groove 8a towards or to the discharge page 6 and to the groove 8a is protruding. In particular, this results in better insulation of a base plate to be poured on, but also increased rigidity of the strip profile element 19 achieved. In addition, for strip profile elements 19 different width base elements 1 with consistently wide grooves 18b be used. Such strip profile elements 19 can in broad part 19a , on the abutting edges of the strip profiles mente 19 over grooves 19b or feathers 19c feature. In addition, corner element strip profile elements can be used for the corners of a foundation 19d be provided. The strip profile elements can be used to achieve a better adhesion with the concrete floor slab 19 over dovetail grooves 19e feature on the inside. Also on the outside of the strip profile elements 19 grooves, in particular dovetail grooves, can be provided, for example in order to insert decorative elements into these grooves.

On the layer or plate 18 can in the of the formwork profile elements 19 bounded space 21 reinforcements usual for a floor concrete slab 22 for example in the form of reinforcing irons, grids or braids ( 3 ). The reinforcement 22 can be applied across the board or in certain areas, for example the reinforcement in the area of the base elements 1 to be in the mood ( 3 ). In addition, if desired, in a manner known per se, supply lines that are to run in the ground can be on the layer 18 be in the mood.

To the top edge 20 the strip profile elements 19 becomes a screed or concrete in the formwork or strip profile elements 19 bounded space 21 cast. The poured concrete can be, for example, 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 concrete floor slab when hardened 23 which of the formwork elements or strip profile elements 19 is limited to the outside. The concrete also flows into the free grooves 8a . 8b the base elements 1 , causing the hardened concrete floor slab 22 in engagement with the insulating layer or plate 18 stands.

The concrete floor slab 23 is preferably cast in one piece, ie monolithically, so that the finished concrete floor slab 23 has no joints. The concrete floor slab 23 can be smoothed in the stiffened but not yet hardened state, 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.

With perimeter insulation up to the construction pit extending up to the strip profile elements 19 the concrete will not reach the top edge 20 , but only cast in at the height desired for a base plate, in particular 20 to 30 cm.

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

The outer walls 14 close with their outside 25 with that of the formwork elements 19 limited outside 26 the concrete floor slab 23 from. On the outside 25 the Wall 14 is an exterior plaster or exterior covering 27 , for example a heat-insulating and water-repellent covering 27 applied, for example a full heat protection system.

The covering or plaster 27 has, for example, a thickness that is greater than the width of the formwork strips 19 and thus stands over the formwork strips 19 outwards. With its bottom edge 28 is the plaster or covering 27 in contact with the top edge 20 the formwork elements 19 , with the bottom edge 28 of the plaster 27 through a U-profile rail 29 can be educated and limited.

As the formwork strips or strip profile elements 19 not removed, but retained as insulation, they can be provided on the outside with a decor, for example a colored wall clinker decor, which also takes on weather protection tasks.

In a further advantageous embodiment of a foundation according to the invention ( 4 ) are on the insulating plate 18 carrier plates 32 for underfloor heating pipes 33 hung up. These backing plates 32 are plate-shaped elements, for example made of plastic, in particular hard foam panels. The carrier plates face upwards 32 one-piece molded nubs 34 for the heating cables 33 on between which the heating cables 33 can be pinched.

To assemble the panels 32 can facilitate strip-shaped elements 35 in the grooves 8a the outer base elements 1 and in the grooves 8a . 8b the inner base elements 1 be plugged in. The stripe-shaped elements 35 can for example be made of the same material as the formwork elements 19 , in particular consist of rigid foam. The Elements 35 have a width that that of the groove 8a . 8b corresponds and have a height which is chosen so that the rigid foam elements 35 over the ceiling side 5 the base elements 1 stand so far that their top edge 36 with the highest area of the carrier plate 32 concludes.

Through the stripe-shaped elements 35 becomes the surface of the plate 18 in narrow compartments 37 between the grooves 8th a pedestal element 1 and wide compartments 38 between adjacent pedestal elements 1 divided.

The base elements 1 can be laid regularly, grid-like, so that square compartments 38 of the same size.

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

In a further advantageous embodiment, the strip-shaped elements are 35 in one piece with the carrier plates 32 formed on the outer edges. The carrier plates 32 so can directly with the elements 35 in the grooves 8a . 8b plugged in and on the insulating plate 18 be anchored. On the support plates provided with heating coils 32 and reinforcements 22 provided insulating plate 18 becomes a concrete or screed in the of the strip profile elements 19 bounded space 21 to the top edge 20 the strip profile elements 19 cast. The concrete or screed is preferably a concrete specially designed for the use of floor heating.

When pouring the concrete into the strip profile elements 19 bounded space 21 ensure the stripe-shaped elements 35 that the carrier plates 32 cannot slip. In addition, the strip-shaped elements seal 35 the edge area of the carrier plates 32 downwards, so that no concrete under the carrier plates 32 can reach. Due to the low density of the carrier plates 32 otherwise they would float on the concrete.

Even on a concrete floor slab produced in this way 23 become the walls 14 . 15 set up in a known and described manner.

In a further advantageous embodiment of a foundation structure according to the invention, the entire insulating layer or plate 18 from base elements 1 built up. In such an embodiment, for. B. the outer contours of the plate 18 with base elements 1 with outward-facing discharge side 6 be trained. The one of these base elements 1 bounded space is then created with additional base elements 1 designed throughout, these base elements 1 can also be rectangular in cross section. The base elements preferably have 1 for the formation of a complete laid layer 18 grooves and tongues on their sides, for example in the form of dovetail guides, so that the base elements 1 can be plugged together. Another option is the base elements 1 to be glued together with a thin-bed mortar or a tile adhesive. Such an arrangement makes sense for high surface loads because the base elements 1 have a higher compressive strength than lightweight concrete.

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

From the outer wall 15 or the exterior plaster 27 running water is thus initially filled into the backfill 43 and runs along the slide 44 via the expiration pages 6 laterally in the backfill 43 and to the edge of the construction pit 10 from or to the drainage pipes 13 directed. The water is thus advantageously by the outer contour or shape of the base elements 1 led away from the building.

This outer contour or shape of the base elements 1 Which, for example, protrudes 30 cm, but optionally also more to the outside than 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 floor layers immediately below and the associated expansion and contraction can cause the foundation floor to move, which can lead to subsidence in this area. Advantageously, the shape of the base element according to the invention 1 with an outwardly projecting frost bar and the thermally well insulating material of the base element 1 achieved a particularly effective shielding of the foundation base against frost.

In a further advantageous embodiment of a foundation structure according to the invention, the outer base elements are attached to the outside 1 an additional frost bar 50 arranged. This frost bar 50 is, for example, a rigid polymer foam sheet, for example a polystyrene foam sheet ( 8th ). This plate preferably has a height that that of the outwardly facing narrow side 4 of the base element 1 corresponds and extends, for example, by half a meter to the outside, ie to the edge of the excavation pit. The upward-facing surface of this additional frost bolt can have a trough-shaped indentation running parallel to the foundation 51 be provided so that this extended frost bar 50 can also take over water-draining functions. The invention therefore advantageously creates a foundation structure which is highly insulated, the insulating plate being arranged on the sole side th 18 as well as those in the grooves 8b inserted strip elements 19 a tub-like insulation is achieved, which has no thermal leaks. With strip elements 19 , which are designed as perimeter insulation extended beyond the top edge of a construction pit, the entire basement is therefore 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 of the base of the foundation is so well developed that when not basemented buildings the foundation sole is not up to the usual in the prior art Depths must be sunk but the foundation base should be arranged closer to the surface can.

The invention thus creates a stable, highly sustainable Foundation for Building, especially lightweight buildings like prefabricated houses and wooden houses, which is thermally well insulated and is suitable for installing underfloor heating with minimal heat loss suitable and above can also be created with little effort in a short time.

For example, such Foundation laid in two days.

Claims (48)

Foundation structure with a horizontal insulating layer or plate, the insulating layer or plate ( 18 ) Base elements ( 1 ), which has strip-shaped base elements made of butt joints ( 1 ) build up the foundation strips and the base elements ( 1 ) built-up foundation strip rooms ( 17 ), the spaces ( 17 ) with a lightweight concrete ( 16 ) are filled so that a continuous, load-bearing, highly insulating layer is formed, with a concrete floor slab on the highly insulating layer ( 23 ) is placed on top, and on the concrete floor slab ( 23 ) Walls of buildings can be built or erected and fastened. Foundation structure according to claim 1, characterized in that the concrete floor slab ( 23 ) is made in one piece or monolithic, so that the finished concrete floor slab ( 23 ) has no joints. Foundation structure according to claim 1 and / or 2, characterized in that in the concrete floor slab ( 23 ) underfloor heating is arranged. Foundation structure according to one or more of claims 1 to 3, characterized in that the base elements ( 1 ) in a ceiling side ( 5 ) two parallel to the longitudinal extension of the base element ( 1 ) running grooves ( 8a . 8b ), whereby in the grooves ( 8b ) of the base elements bounding the foundation ( 1 ) Strip elements or strip-shaped formwork profile elements ( 19 ) are plugged in so that they have an angular trough-shaped space between them ( 21 ) for a base plate to be cast ( 23 ) enclose and delimit tightly, the height of the strip or formwork profile elements ( 19 ) to the desired height of the base plate ( 23 ) is matched and chosen so that the top edge ( 20 ) corresponds to the upper level of the planned foundation. Foundation structure according to claim 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, which means that the formwork profile elements ( 19 ) form a perimeter seal on the outside of basement outer walls. Foundation structure according to claim 4 or 5, characterized in that the strip or formwork profile elements ( 19 ) have a width that is roughly the same as the groove ( 8b ) corresponds. Foundation structure according to claim 4 or 5, characterized in that the upwards over the groove ( 8b ) protruding part ( 19a ) of the strip profile element ( 19 ) is thicker than the part of the strip profile element which is inserted in the groove ( 19 ), which makes the part ( 19a ) to the discharge page ( 6 ) or towards the groove ( 8a ) or to the discharge page ( 16 ) and projecting towards the groove. Foundation structure according to one or more of claims 4 to 7, characterized in that the strip profile elements ( 19 ) on the abutting edges of the strip profile elements ( 19 ) over grooves ( 19b ) or springs ( 19c ) feature. Foundation structure according to one or more of claims 4 to 8, characterized in that in the corner regions of a foundation, corner element strip profile elements ( 19d ) are arranged. Foundation structure according to one or more of claims 4 to 9, characterized in that the strip profile elements ( 19 ) in the angular tub-shaped room ( 21 ) surrounding walls dovetail grooves ( 19e ) to ensure a better adhesion with the concrete floor slab ( 23 ) to reach. Foundation structure according to one or more of claims 4 to 10, characterized in that on the inside and / or outside of the strip profile elements ( 19 ) Grooves, especially dovetail grooves ( 19e ) are arranged. Foundation structure according to one or more of claims 4 to 11, characterized in that that the strip profile elements ( 19 ) consist of a heat-insulating rigid polymer foam. Foundation structure according to claim 12, characterized in that the strip profile elements ( 19 ) consist of an extruded polystyrene foam. Foundation structure according to one or more of claims 4 to 13, characterized in that the space ( 21 ), which of the formwork profile elements ( 19 ) is enclosed on the side, 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 designed to rest. Foundation construction according to one or more of the preceding Expectations, characterized in that the Lightweight concrete is a polystyrene concrete. 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 . 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 . Foundation structure according to one or more of the preceding claims, characterized in that the base elements ( 1 ) and the hardened lightweight concrete ( 16 ) an insulating layer or plate ( 18 ) form, which on a in a construction pit ( 10 ) arranged rolling ( 12 ) or leveling layer ( 12 ) or a sealing film applied to the curling is arranged to rest. Foundation structure according to one or more of the preceding claims, characterized in that the base elements ( 1 ), which are located on the outside of the insulating plate ( 18 ) with the expiration pages ( 6 ) are arranged facing outwards. Foundation structure according to one or more of the preceding claims, characterized in that in the discharge sides ( 6 ) adjacent grooves ( 8b ), the outer contour of the plate ( 18 ) limiting base elements ( 1 ) narrow, elongated stripe elements with a rectangular cross section ( 19 ) or formwork profile elements ( 19 ) are inserted. Foundation structure according to one or more of claims 4 to 20, characterized in that the formwork profile elements ( 19 ) on the bottom plate ( 23 ) are provided with a decor on the opposite side. 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 usual reinforcements for concrete floor slabs ( 22 ) are arranged inlaid. Foundation structure according to claim 22, characterized in that the reinforcements ( 22 ) area-wide in the concrete floor slab ( 23 ) are arranged inlaid. Foundation structure according to one or more of the preceding claims, characterized in that on the insulating plate ( 18 ) Carrier plates ( 32 ) for underfloor heating pipes ( 33 ) are placed on top, the carrier plates ( 32 ) are plate-shaped elements which have receiving devices ( 34 ) for heating cables ( 33 ) in which the heating cables ( 33 ) are arranged inlaid. Foundation structure according to claim 24, characterized in that strip-shaped elements ( 35 ) in the grooves ( 8a ) of the outer base elements ( 1 ) and in the grooves ( 8a . 8b ) of the inner base elements ( 1 ) are arranged plugged in, the elements ( 35 ) have a width that that of the groove ( 8a . 8b ) and have a height that is selected so that the elements ( 35 ) over the décor side ( 5 ) the base elements ( 1 ) so far that their upper edge ( 36 ) with the highest area on the insulating plate ( 18 ) placed support plate ( 32 ) completes. Foundation structure according to claim 25, characterized in that the elements ( 35 ) the surface of the plate ( 18 ) in narrow compartments ( 37 ) between the grooves ( 8a . 8b ) one and the same base element ( 1 ) and other compartments ( 38 ) between neighboring base elements ( 1 ) divide. Foundation structure according to claim 25 or 26, characterized in that the elements ( 35 ) consist of a polymer foam. Foundation structure according to claim 26 or 27, characterized in that in the narrow compartments ( 37 ) Reinforcements ( 22 ) are arranged inlaid. Foundation structure according to one or more of claims 26 to 28, characterized in that in the other compartments ( 38 ) the carrier plates ( 32 ) are arranged inlaid. Foundation structure according to one or more of claims 25 to 29, characterized in that the hard foam elements ( 35 ) in one piece on the outer edges of the carrier plates ( 32 ) are trained. Foundation structure according to one or more of Claims 24 to 30, characterized in that the formwork profile elements ( 19 ) bounded space ( 21 ) with a screed or concrete up to the top edge ( 20 ) a desired base plate ( 23 ) is filled in, whereby the hardened screed or concrete of the concrete floor slab ( 23 ) train. Foundation structure according to claim 31, characterized in that the screed or concrete on the use of underfloor heating inserted in it is coordinated. 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 ) the excavation pit ( 10 ) with gravel, crushed stone or excavation up to the upper edge ( 41 ) of the grown soil ( 11 ) is filled. Foundation structure according to one or more of claims 4 to 33, characterized in that a sealing film ( 44 ) is placed on the edge area of the foundation structure in such a way that the sealing film ( 44 ) from the top edge ( 42 ) the backfill ( 43 ) or a bit above on the outside of the formwork elements ( 19 ) adjacent to the ceiling side ( 5 ) of the outer base elements ( 1 ) extends and extends from these to the discharge pages ( 6 ), the narrow sides ( 4 ) resting on this to the lower outer edge of the base element ( 1 ) extends. Foundation structure according to claim one or more of claims 4 to 33, characterized in that the sealing film ( 44 ) with the formwork profile elements ( 19 ) in the groove ( 8b ) is clamped so that the sealing film ( 44 ) from the groove ( 8b ) on the ceiling side ( 5 ) extends outwards and extends from the ceiling ( 5 ) via the discharge page ( 6 ), the narrow sides ( 4 ) resting on this to the lower outer edge of the base element ( 1 ) extends. 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 curling ( 12 ) up to an edge area of the construction pit ( 10 ) or to installed drainage pipes ( 13 ) so that from the outside ( 15 ) water running out of the backfill ( 43 ) and along the foil ( 44 ) via the expiration pages ( 6 ) laterally into the backfill ( 43 ) and to the edge of the construction pit ( 10 ) or to the drainage pipes ( 13 ) is derived. 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, box-shaped and the base element ( 1 ) consists of a hardened lightweight concrete, the flat box-shaped base element ( 1 ) a horizontal bottom side ( 2 ), two vertical sides ( 3 . 4 ), a horizontal ceiling side running parallel to the floor side ( 5 ), an expiration page ( 6 ) and two end faces ( 7 ), the discharge side ( 6 ) from the ceiling side ( 5 ) to one of the pages ( 3 ) with inclination towards the ceiling side ( 5 ) falls off and the ceiling side ( 5 ) approximately equally spaced from their transverse center two parallel to the longitudinal extension of the base element ( 1 ) running grooves ( 8a . 8b ) having. 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. 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 . Base element according to one or more of claims 37 to 39, characterized in that the Lightweight concrete is a polystyrene lightweight concrete, which is polystyrene granulate contains as a light aggregate. Base element according to one or more of claims 37 to 40, characterized in that the outlet side ( 6 ) from 20 ° to 50 ° opposite the bottom side ( 2 ) is inclined. Base element according to one or more of claims 37 to 41, characterized in that the grooves ( 8a . 8b ) are rectangular recesses or recesses which are a third to a fifth of the height of the base element ( 1 ) are incorporated into this. Base element according to one or more of claims 37 to 42, characterized in that a groove ( 8a ) to the side ( 3 ) arranged adjacent to and about the width of the groove ( 8a ) is spaced apart and a second groove ( 8b ) to a common edge ( 9 ) the ceiling side ( 5 ) and the discharge page ( 6 ) arranged adjacent to and about the width of the groove ( 8b ) is arranged at a distance. Base element according to one or more of claims 37 to 43, characterized in that the grooves ( 8a . 8b ) are of equal width and have a width that is approximately a six of the entire width of the ceiling side ( 5 ) corresponds. Base element according to one or more of claims 37 to 44, characterized in that the base element ( 1 ) in one face ( 7 ) vertical grooves and in the opposite end face ( 7 ) has vertical springs for grooves. Base element according to claim 45, characterized in that the grooves schalbenschwanzförmig undercut are and the springs have a corresponding dovetail shape. 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 m and / or a height of 0.1 m to 0.5 m. 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 .