DE10206782A1 - Method for preparing foundation with thermal insulation has load supporting inlays on a frost free base - Google Patents

Abstract

A method for preparing a foundation for a multi story building has a base layer (1) of sand and gravel to form a frost free support. A load supporting inlay (6) is positioned under a concrete mould with reinforcing inserts, for a base support (4). This is poured and levelled in situe. The inner part of the foundation has a second load supporting layers and any guide ducts for services, thermal pipes for heat pump heating etc. The foundation is completed with a rendering layer.

Description

The invention relates to a heat-protected foundation as a climate foundation plate for single and multi-storey buildings, consisting essentially of insulation materials, pourable building materials, basic and distribution lines and a frost-proof foundation pad and a method for producing such a climate foundation plate according to the features the main and secondary claims.

Energy-saving thermal insulation is one of the most important tasks at Erection of buildings and represents a basic building physics task. In all materials and heat conduction occurs between all adjoining substances, but differently strong. Therefore, you can never completely avoid heat loss, but you can significantly reduce it. density heavy materials - like concrete - have a high thermal conductivity, porous lightweight materials - like for example rigid foams - a low one. The aim of the energy-saving thermal insulation is that Reduce heat conduction of heavy solids by porosity or porous, well to introduce insulating layers in the building structure in order to improve their thermal insulation. For energy consumption and well-being in a building, the U-value is the External components - including those of the foundation - are crucial. Space enclosing areas, the warmth not dissipate, increase comfort, save energy and thus relieve u. a. also the Environment.

A common rule of thumb is that the liter-oil consumption per m ² per year for heating depends directly on the U-value. The lower the U-value of a casing, the lower the heat loss and thus the heating requirement. In order to keep the U-value as low as possible, the layer thickness of the materials could be increased. The consequence would be to make a floor structure on a foundation uneconomically strong in order to meet today's thermal insulation requirements. It is therefore already common practice to insert appropriate thermal insulation under or on a floor foundation slab. However, there is a limit to the static load capacity of such a foundation slab. In the past, therefore, solutions were sought to combine building materials that had less good insulation but were able to withstand static loads with light insulating materials. In the past, such foundation slabs could only be designed for lightweight construction, ie essentially for single-storey prefabricated houses.

So an essential task is by combining less good insulating, but good static load-bearing building materials with light and better insulating Materials an energy-saving and thermal bridge-free heat and all-round To ensure moisture protection.

DE 198 01 123 A1 describes a foundation structure with prefabricated ones Base elements known, which consist for example of a polystyrene lightweight concrete. After this According to this document, laying base elements is a lightweight concrete up to the upper edge the base elements introduced. In the base elements are tongue and groove Formwork profile elements introduced and concrete and a screed made up to their upper edge. Such a multilayer floor structure with prefabricated elements has high Process and transport expenses for the tongue and groove Formwork profile elements, the base elements, the light-burst concrete and the further floor structure. On site the base elements must be cut for fermentation, especially for foundation corners. Overall, this foundation structure still does not have thermal bridge-free thermal protection and is very expensive due to the high manufacturing costs.

DE 44 94 455 T1 describes a process for the production of Building foundations and a foundation structure described. The foundation plate is also constructed from prefabricated heat-insulating base parts made of cellular plastic, which all around the Have a groove in the edge of the foundation or in the area below the wall, into which an edge beam also made of heat-insulating material, in particular cellular Plastic is used, this edge beam with a fastener a band-shaped wedge is held in this groove. The foundation structure has one good thermal insulation, but is both in the prefabrication and in the Foundation production complex and not for multi-storey and especially not for solid buildings suitable. In addition, such foundation plates have the shortcoming that they with their lower insulation layer protrude horizontally below the usual vertical foundation boundary and there have a groove into which said fastener is introduced, which However, after years of ingress of moisture no longer holds back, so that by penetrating Moisture in the area of this fastening groove through it in the lower insulating material Frost effects lead to destruction of the insulating material and thus endanger the statics of the foundation is. The entire foundation system is in the moisture range and especially the insulation, due to the lack of moisture protection, temperature fluctuations, Exposed to moisture and frost. An absolutely necessary and required According to this document there is no splash water protection area above the upper edge of the site (OKG). The proposed solution is therefore not applicable in practice.

DE 40 15 474 A1 describes a foundation structure with underfloor heating known. Between a foundation wall encompassing the foundation is a concrete bed as Substructure arranged with large pipes inside. Between the concrete bed and the insulation is arranged around the foundation wall. In turn is above the concrete bed insulation with an overlying heat storage layer and inside Underfloor heating arranged. Such a foundation structure is complicated to manufacture and complex, requires a high level of prefabrication and is due to the use of relatively English large-sized pipes costly.

The object of the invention is to address the existing shortcomings, as in the prior art Technique are described to fix. Furthermore, it is an object of the invention to provide a method for Production of a foundation slab for single and multi-storey buildings and such Propose building foundation plate itself, which can be produced in a simple and inexpensive manner and can be carried out on site without significant prefabrication. The technical The solution is intended to make it possible to produce a foundation slab with a circumferential one thermal bridge-free thermal insulation, a good living climate and sufficient strength.

The task is considered with a heat-protected foundation Climatic foundation slab for single and multi-storey buildings, consisting essentially of insulation materials, pourable building materials, basic and distribution lines and a frost-proof Foundation pad and a method for producing such a climate foundation plate according to the Main and secondary claims resolved. Advantageous further developments are in the Subclaims described. A heat-protected foundation is proposed, which has its function according to the invention is a climate foundation plate. The process of making a such heat-protected foundation in the form of a climate foundation plate for one and Multi-storey buildings are carried out according to the following process steps.

In the area selected for the construction of a building The topsoil is excavated up to the stable foundation sole and the foundation sole is compacted. Per se Known earth registers for air preheating for a heat pump system are on the Foundation sole laid and there is a usual layered structure of a frost-resistant foundation padding from filling soil, preferably from a gravel-sand mixture or Sand-gravel mixture. This filling soil is compacted and a fine planum is made. According to the future usage requirements for the building to be erected Drainage and protective pipes for the installation of media as well as a ring and earthing strap in or laid on the filling floor. A construction foil is placed over the foundation structure prepared so far designed. This will be in the dimensions of the future foundation with all the projections and angulations a perimeter insulation that limits the foundation for heat and Moisture protection installed and anchored. Anchoring takes place in a conventional manner and Way from the outside or by connection with reinforcements to be inserted. The Perimeter insulation is cut on site. It forms an outer part of the foundation Framework of the foundation. The perimeter insulation consists of foamed, moisture-resistant plastic with high load-bearing capacity. The one built using perimeter insulation With its upper edge, the foundation frame also forms the upper edge for the future Structure of the climate foundation plate.

A strip of load insulation is laid horizontally within the perimeter insulation set up as the outer foundation frame. The load insulation is also cut on site. This consists of a foamed plastic with a high load-bearing capacity and a minimum bulk density of> 40 kg / m ³ . The load insulation is laid out along the perimeter insulation and in strips where future load-bearing walls will be built on the foundation slab. The two layers of insulation are joined together. The perimeter insulation and the load insulation are preferably welded or glued together.

Alternatively, it is provided according to the invention, the perimeter insulation and Load insulation as a one-piece, industrially prefabricated insulation body in the Install climate foundation plate. It goes without saying that the perimeter insulation is the same Compressive strength requirements such as load insulation must meet. As industrially prefabricated Insulating molded parts, angular and U-shapes are preferred, with the use of a U-shaped insulation body with its two vertical legs is set up so that a vertical leg acts as perimeter insulation and outer foundation boundary and a Another vertical leg represents a boundary within the foundation. It is also conceivable as an industrially prefabricated insulation body for perimeter insulation and load insulation insert an angle and a separate molded body made of insulating material for receiving Air distribution pipes vertically next to the angular insulation body between the Arrange load insulation or the angular insulation body and the interior insulation. Becomes a industrially prefabricated insulating body used as a one-piece U-shape, so according to the Invention of the vertical leg of the insulating body arranged in the interior of the foundation a shape for receiving air distribution pipes. The remaining one Cavity of the u-shaped insulating body or the angular insulating body and the vertically arranged molded body is later filled with a flowable building material.

The area of the foundation structure that has not yet been covered with insulation is now exactly coated with an internal insulation, which in turn is cut on site. Also the Internal insulation is provided with the load insulation that defines it, or with the angular or U-shaped one Insulation bodies connected. The connection is made by gluing or welding. The Internal insulation has a lower minimum bulk density than load insulation. The The main insulation is at least twice as strong as the load insulation in its vertical extent. It lies within the scope of the invention of insulating materials, in particular for load insulation To use foam glass.

On the individual firmly connected at their vertical abutting edges horizontally applied insulation layers, a release film is laid out and cold and Hot water pipes and a defined network of air distribution pipes laid. According to the invention provided in or on the internal insulation or in the flowable still to be applied Construction materials a stationary suction line for a vacuum cleaner connection with a corresponding Transition to arrange in the building to be built on the foundation. When laying It should be noted for all lines that supply and discharge lines are all vertical, so that they do not get into the area of the installed load insulation.

Over the load insulation - both in the edge area and in the load-bearing Areas - becomes a structural reinforcement and alternatively a structural reinforcement for Tension compensation and designed to avoid cracking. As above executed, individual reinforcements can be connected to the perimeter insulation in such a way that the perimeter insulation forming the outer foundation frame from the reinforcement during Construction is held and supported. The conventional anchoring of the Perimeter insulation from the outside. Before introducing flowable building materials into the so The prepared foundation structure will be over the outer foundation frame, i.e. over the Perimeter insulation protruding foundation pad covered with construction film, slightly beveled. This is necessary to prevent the ingress of moisture between the construction film and Prevent perimeter insulation or load insulation.

The further foundation construction takes place according to the invention in different Variants. In the prepared foundation structure is now over the load insulation in Edge and concrete in the load-bearing areas within the climate foundation slab. The structural reinforcements and the structural reinforcements completely enclosed by concrete. The concrete is compacted and leveled and in Fine print of the same. In the interior insulation, the air distribution pipes are made according to the later intended use relocated, the air distribution pipes with fittings as a connection to the rooms to be built on the climate foundation slab. This Fittings are advantageously designed as telescopic fittings, so that a appropriate height compensation can take place. A dry screed is now over the interior insulation laid that corresponding slot openings are above the air distribution pipes and one Connection to these can be made through the fittings. You can also choose to a dry screed is placed in the edge or in the load-bearing areas become. This completes the construction of the climate foundation plate and the other one Building construction can take place.

Another useful development of the invention provides that with the Entry of concrete over the load insulation also a concrete over the inner insulation, so over the entire foundation plate. In this case, the laying out of dispensed with a dry screed. The air distribution pipes can optionally be in the Internal insulation or in the concrete layer above the internal insulation and - how already described - through the concrete telescopic fittings as a connection between the air distribution pipes and the upper edge of the foundation structure.

It is also within the scope of the invention if the air distribution pipes in the outer Edge area in the concrete. Such a procedure is preferred for Wall structures with so-called air duct blocks, d. H. the walls to be built face vertically running flow channels. For structures provided in this way, Concrete strips provided over the load insulation supply and exhaust air ducts.

The following the individual process steps described and different Design foundation climate plate is suitable for one and Multi-storey building in prefabricated and solid construction. The climate foundation plate consists of one Dry line with defined openings for air circulation, one in edge and load-bearing Areas brought in concrete, in which static load-bearing reinforcements and / or structural Reinforcements are available. Under the dry screed there is an interior insulation, this its dimensions are many times larger than the one above it lying dry screed. In the edge and load-bearing areas there is one under the concrete Load insulation arranged, which forms an inner foundation frame, the load insulation a has higher load-bearing capacity than the internal insulation. The load insulation is vertical Expansion dimensioned smaller than the inner insulation, preferably it has a height that is less than or equal to half the height of the interior insulation.

The entire climate foundation plate is covered on the outside by perimeter insulation limited. It also forms an outer frame and is firm with the load insulation connected. The horizontal dimension of the perimeter insulation is smaller than that Height of the load insulation and preferably has a material thickness that is equal to or less is than half the height of the load insulation. The perimeter insulation is above the top edge Terrain arranged and therefore serves as a bulkhead. The perimeter insulation, the Load insulation and the interior insulation form one in the designed or in the assembled state channel-like recess, which is filled with concrete, in which - as mentioned - the Reinforcements.

For the air conditioning of the premises is located in the Climate foundation plate a defined network of air distribution pipes. This defined network of air distribution pipes can in accordance with the various embodiments of the invention in the interior insulation or in a concrete arranged above the internal insulation or in the concrete that is in the edge areas of the Load insulation is introduced, be arranged. So an embodiment provides that Install air distribution pipes directly in the interior insulation or the air distribution pipes in Arrange moldings made of insulating material, which as a separate element between load insulation and internal insulation can be adjusted vertically while the foundation is being built. Both at a structure with dry screed as well as when using a concrete become independent of the further construction of the foundation plate fittings for connecting the air distribution pipes with the upper edge of the foundation structure. These connections are made with prefabricated telescopic fittings. If a building is to be built on the foundation slab Outside walls with flow channels located therein are more appropriate Way arranged in the edge-placed concrete supply and exhaust air ducts.

It is known that the heating temperature can be reduced without reducing the Living comfort can be reduced by a few degrees in an energy-saving manner, if the Surface temperature of the components surrounding the room. In practice, one has in the Mainly concerned with wall structures. For prefabricated houses in particular, according to the given dimensions and specifications of the prefabricated house provider foundation slabs and the Heating, ventilation and / or air conditioning systems only with the on the foundation plate too the building under consideration or delivered with it. With the present Invention should include all components that surround the room, including the foundation, in the design be involved in the design of better living comfort. The in this invention based on the laying of pipes for earth registers for air conditioning and air distribution The basic idea described for the distribution of energy carrier media does not apply exclusively on the energy medium air. It is specifically emphasized that too all other gaseous and liquid energy carriers are considered.

The invention is described below using exemplary embodiments Using the drawing explained in more detail. Show it:

Fig. 1 shows a schematic structure of an air foundation plate with dry screed in section,

Fig. 2 shows an alternative to Fig. 1 with concrete entry on the internal insulation,

Fig. 3 shows an alternative to Fig. 1 with molding of insulating material,

Fig. 4 shows an alternative to FIG. 2 Luftverteilrohr in peripheral concrete,

Fig. 5 shows an alternative to Fig. 4 with two Luftverteilrohren in peripheral concrete,

Fig. 6 is a partial section of the foundation with a stationary suction line arranged in concrete for vacuum cleaner connection.

example 1

The invention provides, according to FIG. 1, first to dig out the topsoil to the load-bearing foundation sole in a conventional manner. The foundation sole is compacted and a layer-by-layer build-up of a frost-resistant foundation pad 1 consisting of a gravel-sand mixture or a sand-gravel mixture with compaction and subsequent fine planum takes place. Drainage pipes and protective pipes for receiving additional media lines and a ring earthing strap are laid in or under the foundation pad 1 . Additional lines are installed as earth registers for air preheating for a heat pump during the foundation work. These earth registers absorb geothermal energy as a heat source and feed it to the heat pump. The heat pump can also be supplied with exhaust and / or outside air via additional heat collectors.

Exactly in the dimensions of the future foundation with all projections and angulations, a perimeter insulation 5 for the heat and moisture protection, which limits the foundation, is set up and anchored on a construction film. This perimeter insulation 5 is cut on site and forms an outer frame of the foundation as a component of the foundation. The perimeter insulation 5 consists of foamed moisture-repellent plastic with a high load-bearing capacity. The upper edge of the perimeter insulation 5 is also the upper edge of the structure of the climate foundation plate. Within the perimeter insulation 5 , which, as mentioned, forms the outer frame of the future foundation structure, a load insulation 6 is laid horizontally in strips. This also consists of foamed plastic, has a high load-bearing capacity with a minimum bulk density of> 40 kg / m ³ and is also moisture-repellent. The load insulation 6 forms an inner frame and is connected to the perimeter insulation 5 during installation. The two insulation layers are connected by welding or gluing. It is within the scope of the invention to alternatively manufacture the perimeter insulation 5 and the load insulation 6 in one piece in an angular or U-shape. This is done either by connecting on the construction site or already industrially, but then as a compact angle or U-shape as perimeter insulation 5 and with the corresponding compressive strength values as are required for the static load bearing. The load insulation 6 can also be made of foam glass.

If the foundation structure is intended to accommodate load-bearing walls in the interior of the building, load insulation 6 is also installed at corresponding points in the foundation structure. The inner surfaces not yet lined with insulation are now lined with internal insulation 8 . The vertical dimension of the inner insulation 8 is larger than that of the load insulation 6 previously laid. The inner insulation 8 consists of a foamed plastic. It has a defined load-bearing capacity and is also moisture-repellent. No separate prefabrication was required for the previous foundation construction, since both the perimeter insulation 5 and the load insulation 6 and the interior insulation 8 are cut on site. The inner insulation 8 is firmly connected to the previously installed load insulation 6 by welding or gluing.

A defined network of air distribution pipes 10 for the air conditioning is introduced into the interior insulation 8 . These and the air distribution pipes 10 provided with an overhead slot are connected to the further foundation structure in such a way that air can escape into rooms located above the foundation. The air distribution pipes 10 consist either of metal or metal composite pipes or of prefabricated parts made of plastic or ceramic. In Fig. 1, the embodiment is shown in which the air distribution pipes are inserted in the inner insulation 10 and 8, the slot-like compounds of the air distribution pipes 10 through a subsequent further base construction - namely, a dry screed 12 - lead. Instead of a dry screed 12 , any other further foundation or floor structure is also conceivable, this further floor construction or the dry screed 12 being delimited from the inner insulation 8 by means of a separating film 9 . The separating film 9 is, however, designed as it were over the load insulation 6 . Concrete 4 with reinforcements 11 is introduced over the load insulation 6 . A dry screed 12 is also laid over the hardened concrete 4 or a further floor construction is carried out.

The defined network of air distribution pipes 10 is dimensioned and laid in such a way that, after completion of the climate foundation plate, air conditioning can take place in the desired temperature ranges in the rooms used in the future. The air distribution pipes 10 are connected via the heat pump to the earth register (not shown in FIG. 1) of a heat collection system arranged below the upper edge of the terrain and / or to heat collectors fed via exhaust air and / or outside air. Other systems (e.g. gas or oil firing systems) can also be used for heat generation. After the inserted concrete 4 has hardened, the climatic foundation plate according to the invention and the edge area are finely removed and the upper floor is rubbed or rubbed off.

Example 2

The foundation structure according to Fig. 2 is basically the same as that described in Example 1. According to this exemplary embodiment, concrete 4 is introduced above the load insulation 6 up to the upper edge of the perimeter insulation 5 . Instead of a dry screed 12, a concrete floor structure 14 is built over the internal insulation 8 . The air distribution pipes 10 are arranged in the inner insulation 8 and are provided with a telescopic connection at the top, so that air can escape unimpeded through the concrete structure 14 .

Example 3

FIG. 3 shows the structure of an air-conditioning foundation slab, which was also provided with a dry screed 12 , as described in Example 1. In distinction from the previous exemplary embodiments, the air distribution pipe 10 is arranged here in a special shaped body 13 . The molded body 13 can consist of an insulating material, but then has to have a minimum bulk density, like the inner insulation 8 . However, it is also conceivable to prefabricate this molded body from any other material. For example, it can also be made in one piece as an angle part from load insulation 6 and molded body 13 . An embodiment as a U-shaped insulating part, ie a U-shaped connection of perimeter insulation 5 , load insulation 6 and molded body 13 is also within the scope of the invention.

Example 4

Which in this example to be described configuration of an air foundation plate is explained in more detail in Fig. 4 and Fig. 5. In a modification of example 2, the air distribution pipe 10 is not arranged in the interior insulation 8 , but instead for a special wall structure of one of the buildings to be erected above the climate foundation plate, it is provided here that the air distribution pipe 10 is arranged in the concrete 4 placed on the edge above the load insulation 6 , This type of arrangement of the air distribution pipes 10 is intended for special wall ventilation systems. In Fig. 5, an embodiment is shown to '"is arranged. The arrangement of Luftverteilrohren 10 and / or supply air ducts 10 and exhaust duct 10' and exhaust air channels 10 'at the edge placed concrete 4, a supply air channel 10 in the edge placed concrete 4 enables the erection of walls to be erected above, for example according to the principle of so-called hypocausal firing.

Example 5

In FIG. 6, an insertable for all the aforesaid examples embodiment is illustrated, wherein in or on the internal insulation, or in the introduced concrete 14, a stationary suction line 15 for a vacuum cleaner connection with a corresponding transition in the disposed on the foundation to be constructed building. The stationary suction line 15 is led through the foundation structure, ends during the construction of the foundation in a temporarily lockable connecting sleeve 16 , into which a flexible suction line 17 arranged therein is let in with the construction of an inner wall 18 . Foundation structures of this type are intended in particular for commercial buildings, save on having to pry open later and ensure a smooth construction process. With such prefabrication, such a foundation structure will also find its way into individual residential construction.

The advantages of the climate foundation plate described here and the method for producing them are that the climate foundation plate guarantees thermal bridge-free thermal protection with all-round moisture protection and by making use of the free heat from the heat source nature and the environment as well as heat conduction and air conditioning make a significant contribution to the reduction of the energy costs for later use and thus a reduction in CO ₂ emissions. The climate foundation plate also has the advantage that predefined, defined temperature ranges are made available for individual rooms in the building in a controllable manner. Due to the on-site cuts of the individual insulation layers and layers, transport optimization also comes into consideration, so that overall environmental pollution is reduced in the manufacture of the climate foundation plate according to the invention and considerable construction and energy costs are saved due to the cost-effective use of energy-saving installation techniques.

Claims (22)

1.Procedure for the production of a thermal insulation foundation plate as a climate foundation plate for single and multi-storey buildings in prefabricated and solid construction, consisting essentially of a frost-resistant foundation pad ( 1 ), flowable, curable building materials, insulation agents and ground pipes after the process steps - Excavation from topsoil to the stable foundation sole, - compacting the foundation sole, - laying of lines as an earth register for air preheating for a heat pump system, - Laying and compacting filling soil in layers and producing fine planum, - Laying of drainage and protection pipes as well as a ring earthing strap, laying construction foil, On-site fine cutting, installation and anchoring of a perimeter insulation forming an outer frame ( 5 ), - On-site fine cutting and laying out a load insulation ( 6 ) forming an inner frame and connecting it to the perimeter insulation ( 5 ), - On-site fine cutting and laying out an internal insulation ( 8 ), this being installed only within the load insulation ( 6 ) forming the inner frame and the internal insulation ( 8 ) being connected to the load insulation ( 6 ), - laying cold and hot water pipes, Laying a defined network of pipes for energy carrier media, preferably air distribution pipes ( 10 ) for air conditioning, - laying out a separating film ( 9 ), - Laying statically load-bearing reinforcement ( 11 ) over the load insulation ( 6 ) in edge and load-bearing areas and / or laying a structural reinforcement for tension compensation and avoiding crack formation, - Entry of concrete ( 4 ) over the load insulation ( 6 ), - compacting and leveling the concrete ( 4 ), - Fine deduction of the concrete ( 4 ) and - Laying a dry screed ( 12 ) over the internal insulation ( 8 ), the dry screed ( 12 ) having defined openings with connections to the pipes for energy carrier media. 2. A method for producing a thermal insulation foundation plate as a climate foundation plate for single-storey and multi-storey buildings in prefabricated and solid construction, consisting essentially of a frost-resistant foundation pad ( 1 ), flowable, curable building materials, insulation agents and ground pipes, essentially according to the process steps described in claim 1 , wherein with the entry of concrete ( 4 ) over the load insulation ( 6 ) at the same time a concrete ( 14 ) is introduced over the inner insulation ( 8 ), the connections to the pipes for energy carriers, preferably air distribution pipes ( 10 ) are made by means of fittings and then the Compacting, leveling and fine deduction of concrete ( 4 ) and the entire concrete surface ( 14 ) takes place, the pipes for energy carrier media with their fittings as connecting elements depending on the intended use of a future air conditioning system in the concrete ( 4 ) above the load insulation ( 6 ) or in or under the concrete ( 14 ) above the internal insulation ( 8 ). 3. A method for producing a thermal insulation foundation plate as a climate foundation plate for single-storey and multi-storey buildings in prefabricated and solid construction, consisting essentially of a frost-resistant foundation pad ( 1 ), flowable, curable building materials, insulation means and ground pipes essentially according to the process steps described in claim 1, whereby the laying of a defined network of pipes for energy carriers, preferably air distribution pipes ( 10 ) for air conditioning after laying statically load-bearing reinforcement ( 11 ) and / or laying a structural reinforcement over the load insulation ( 6 ) and the concrete ( 4 ) Reinforcements and the pipes for energy carrier media, is introduced. 4. The method according to one or more of claims 1 to 3, wherein for the production of the outer frame of the foundation, the connection of perimeter insulation ( 5 ) and load insulation ( 6 ) is carried out by gluing or welding. 5. The method according to one or more of claims 1 to 3, wherein the perimeter insulation ( 5 ) with the load insulation ( 6 ) assembled on site to form an angular part and installed in the climate foundation plate. 6. The method according to one or more of claims 1 to 5, wherein the load insulation ( 6 ) has a minimum bulk density of> 40 kg / m ³ . 7. The method according to one or more of claims 1 to 3, wherein industrially prefabricated one-piece angular parts of perimeter insulation ( 5 ) and load insulation ( 6 ) are used for the outer frame of the foundation and these one-piece angular parts have a minimum bulk density of> 40 kg / m ³ , 8. The method according to one or more of claims 1 to 3, wherein for the outer frame of the foundation industrially prefabricated one-piece, U-shaped parts of perimeter insulation ( 5 ), load insulation ( 6 ) and molded body ( 13 ) are used and integrally, u -shaped parts have a minimum bulk density of> 40 kg / m ³ . 9. The method according to one or more of claims 1 to 3, wherein the air distribution pipes ( 10 ) in moldings ( 13 ) made of insulating material under the concrete ( 14 ) or under the dry screed ( 12 ) are arranged. 10. The method according to one or more of claims 1 to 3, wherein the defined network of air distribution pipes ( 10 ) in the concrete ( 4 ) have a supply air duct ( 10 ') and an exhaust air duct ( 10 "). 11. The method according to one or more of claims 1 to 3, wherein in or on the internal insulation or in the concrete ( 14 ), a stationary suction line for a vacuum cleaner connection with a transition is arranged in the building to be built on the foundation. 12. Climatic foundation slab for single and multi-storey buildings in prefabricated and solid construction, consisting essentially of a frost-resistant foundation pad ( 1 ), flowable, curable building materials, insulation means and ground pipes, essentially manufactured according to one or more of the described in claims 1 to 11 Process steps consisting of - a dry screed ( 12 ) with defined openings, - a concrete ( 4 ), which is placed in edge and load-bearing areas and statically load-bearing reinforcements ( 11 ) and / or structural reinforcements for tension compensation are arranged in these areas, an inner insulation ( 8 ) lying under the dry screed ( 12 ), the vertical dimension of which is dimensioned many times stronger than the dry screed ( 12 ) lying above it, - In edge and load-bearing areas under the concrete ( 4 ) lying load insulation ( 6 ), which forms an inner foundation frame, the load insulation ( 6 ) has a higher load capacity than the inner insulation ( 8 ) and is dimensioned smaller in its vertical extent than the inner insulation ( 8 ), preferably a height ≤ half the height of the inner insulation ( 8 ), - A perimeter insulation ( 5 ) that vertically delimits the climate foundation plate, the horizontal dimension of which is smaller than the height of the load insulation ( 6 ), preferably a material thickness of ≤ half the height of the load insulation ( 6 ), the perimeter insulation ( 5 ) is arranged above the upper edge of the site and is firmly connected to the load insulation ( 6 ) and this in turn to the inner insulation ( 8 ), a space between the perimeter insulation ( 5 ) and the inner insulation ( 8 ) forming a channel-like recess, which space is delimited at the bottom by the load insulation ( 6 ), this space being filled with concrete ( 4 ), - A defined network of pipes for energy carrier media, preferably air distribution pipes ( 10 ) for air conditioning and arranged under the dry screed ( 12 ) - A foundation pad ( 1 ), with a system of lines embedded therein or below as an earth register for the absorption of geothermal energy. 13. Climatic foundation plate for single and multi-storey buildings in prefabricated and solid construction, consisting essentially of a frost-resistant foundation pad ( 1 ), flowable, curable building materials, insulation means and ground pipes, essentially manufactured according to one or more of the described in claims 1 to 11 Process steps consisting of - a concrete slab ( 14 ) lying on the inner insulation ( 8 ) with defined openings, - The concrete ( 4 ) lying on the load insulation ( 6 ), this being introduced in edge and load-bearing areas and containing statically load-bearing reinforcements ( 11 ) and / or structural reinforcements for tension compensation in these areas, an inner insulation ( 8 ) lying under the concrete slab ( 14 ), the vertical dimension of which is dimensioned many times stronger than the concrete slab ( 14 ) lying above it, - In edge and load-bearing areas under the concrete ( 4 ) lying load insulation ( 6 ), which forms an inner foundation frame, the load insulation ( 6 ) has a higher load capacity than the inner insulation ( 8 ) and is dimensioned smaller in its vertical extent as the internal insulation (8), preferably a height ≤ half the height of the main insulation (8), - A perimeter insulation ( 5 ) which delimits the climate foundation plate vertically on the edge, the dimensions of the horizontal expansion being ≤ half a height of the load insulation ( 6 ) and the perimeter insulation ( 5 ) with the load insulation ( 6 ) and this in turn with the inner insulation ( 8 ) in each case are firmly connected a space between the perimeter insulation ( 5 ) and the inner insulation ( 8 ) forming a channel-like recess, which space is delimited at the bottom by the load insulation ( 6 ), this space being filled with concrete ( 4 ), - A defined underneath and / or in the concrete slab ( 14 ) and / or in the concrete ( 4 ) arranged defined network of pipes for energy carrier media, preferably air distribution pipes ( 10 ) for air conditioning and - A foundation pad ( 1 ) with a system of lines ( 2 ) embedded therein or below as an earth register for the absorption of geothermal energy. 14. Climate foundation plate according to claims 12 and 13, wherein the air distribution pipes ( 10 ) in a molded body ( 13 ), which is vertically between load insulation ( 6 ) and inner insulation ( 8 ), are arranged. 15. Climate foundation plate according to claims 12 and 13, wherein the perimeter insulation forming the outer frame of the foundation ( 5 ) and the load insulation ( 6 ) are arranged as a one-piece angular element and these have a minimum bulk density of> 40 kg / m ³ . 16. Climate foundation plate according to claims 12 and 13, wherein industrially prefabricated one-piece, u-shaped parts as perimeter insulation ( 5 ), load insulation ( 6 ) and molded body ( 13 ) are arranged and these have a minimum bulk density of> 40 kg / have m ³ . 17. Climate foundation plate according to claims 12 and 13, wherein the defined openings in the dry screed ( 12 ) and in the concrete ( 4 ; 14 ) are preferably slot-shaped and these openings are connected to air distribution pipes ( 10 ) and / or with prefabricated components for air distribution , 18, climate foundation plate according to claims 12 and 13, wherein the defined openings in the dry screed ( 12 ) and in the concrete ( 14 ) offset in edge areas above the load insulation ( 8 ) are arranged in the climate foundation plate, so that an air outlet occurs directly on the walls to be erected , 19. Climate foundation plate according to one or more of claims 12 to 18, wherein the perimeter insulation ( 5 ), and / or the load insulation ( 6 ) and / or the inner insulation ( 8 ) and / or the molded body ( 13 ) consists of foamed plastic. 20. Climate foundation plate according to one or more of claims 12 to 19, wherein the perimeter insulation ( 5 ) and / or the load insulation ( 6 ) and / or the inner insulation ( 8 ) and / or molded body ( 13 ) consist of foam glass. 21. A climate foundation plate according to one or more of claims 12 to 20, wherein the defined network of pipes for energy carrier media has a supply air duct ( 10 ') and an exhaust air duct ( 10 ") and these in the concrete ( 4 ; 14 ) and / or the internal insulation ( 8 ) are arranged. 22. A climate foundation plate according to one or more of claims 12 to 21, wherein a stationary suction line for a vacuum cleaner connection with a transition is arranged in or on the internal insulation or in the concrete ( 14 ), in the structure to be erected on the foundation.