FI123454B - Procedure for arranging a fireplace in a room and foundation for the fireplace - Google Patents

Description

Method of arranging the fireplace in the space and the foundation of the fireplace

The invention relates to a method for arranging a fireplace in a space having a ventilated base, below which is an air space and a supporting structural member based on the ground. The invention further relates to a fireplace foundation.

5 In many new detached houses, a ventilated subfloor is used as the base structure. rossi base structure. In the ventilated bottom, the load-bearing structure is usually wooden beams, which at their ends rest on the plinth and in the middle part of the spacer. Below the bottom is a ventilated crawl space with a leveled gravel or gravel bed spread over the base of the site. In new small-10 houses, the height of the crawl space is typically 50-80 cm.

Most of the small houses with a rooftop are now built with a spare fireplace, such as a fireplace or baking oven, as a backup heat source. Reserve fireplaces are heavy, so they are usually built on the ground below the building. First, a concrete-15 turf is cast on top of the gravel or crushed stone overlying the foundation, which is used to build a fireplace base wall extending from the upper surface of the floor through the floor structures to the upper surface of the floor. The basic wall is usually built of lightweight gravel blocks.

There are several problems with the known method of building fireplace foundations. Foundation construction is a separate phase of work that slows down the completion of a fireplace. At the same time, the foundation forms a cold bridge that extends through the floor structure and therefore needs to be insulated on its external surfaces. The construction of foundations usually also requires cutting off the supporting beams at the base of the fireplace and supporting the foundation of the fireplace. The seam between the floor structure and the foundation of the fireplace passing through it needs to be further sealed to airtight. These 25 steps significantly increase the total cost of building a fireplace.

c \ i The steps involved in setting up a fireplace are particularly difficult when

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the slatted base is made of prefabricated elements, which have to be made a hole for the foundation. Similar difficulties are encountered when it comes to building a fireplace in an existing building with a ventilated floor.

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It is an object of the invention to provide a method for arranging a fireplace in a space having a ventilated base and a fireplace foundation which can reduce the drawbacks and disadvantages of the prior art.

The objects of the invention are achieved by a method and a foundation of a fireplace, which are characterized by what is stated in the independent claims. Certain preferred embodiments of the invention are set forth in the dependent claims.

The invention relates to a method for arranging a fireplace in a space with a ventilated bottom. One typical such space is a residential building, especially a small house.

5 There is an air space below the ventilated bottom. a crawl space, the bottom of which is usually a flat gravel or se-layer, which is spread over the ground of the building site. On top of the gravel or crushed stone layer is a load-bearing structural member, on which the vertical loads of the fireplace arranged in the space are guided. The load-bearing member rests either directly or through a gravel or crushed stone layer on the base 10. Preferably, the load-bearing structural member based on the ground is a concrete sensor. The concrete rail may be cast in connection with other building work, specifically for the fireplace. In ventilated subfloor structures, the distance from the upper surface of the gravel or crushed stone layer to the level of the upper surface of the subfloor is typically 90-120 cm. Thus, the height of the air space below the ventilated base can be 50-80 cm depending on the insulation thickness of the bottom-15 base. There is thus a high open space between the upper surface of the load-bearing member and the lower surface of the lower base.

The method comprises forming at least one through hole in the underside and providing in the hole a post having a lower end resting on the supporting member and an upper end extending substantially to the plane of the upper surface of the underside. The fireplace is arranged on the bottom 20 so that at least part of the weight of the fireplace is applied to the upper end of said pillar. Thus, at least part of the fireplace's own weight is transferred to the load-bearing structure through the post. Preferably, the method comprises forming at least three through holes in the underside and providing in each of the holes a post having a lower end supported by a structural member and an upper end extending substantially to the plane of the upper surface of the underside. The fireplace is arranged on the bottom floor so that the fireplace

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The weight is substantially entirely applied to the top ends of said posts. It is preferable to place said at least three poles below the fireplace in the shape of a triangle, whereby

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The 9 attachments' 'stand' firmly on the three posts of the supporting member.

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x Most fireplaces have a rectangular cross-section. In this case, it is often expedient to form four holes for the four posts and four holes for the posts in the bottom, so that the holes are located on the inner side of the circle defined by the outer surface of the fireplace near the corners of the fireplace. The fireplace arranged on the posts will then rest on its corners at the tops of the posts. Due to the placement and number of poles, the support of the pole should be as stable as possible and each pole has a substantially uniform load. The number of posts is not limited to four, but the number can be selected, for example, according to the size and weight of the fireplace. Thus, for example, there may be five, six, seven or even eight poles per one fireplace. However, from a technical point of view, it is generally sensible to keep the number of posts as small as possible.

In a preferred embodiment of the method according to the invention, the fireplace 5 is arranged in a space with a ventilated bottom surface having a combustible material surface plate and the base structures of which support members comprise wooden beams. Thus, this embodiment is a load-bearing base of wood structure commonly used in small houses.

In another preferred embodiment of the method according to the invention, the posts are formed by hole-mounted tubes having a lower end which extends into the supporting member and an upper end which extends substantially to the plane of the upper surface of the lower sole. The wall thickness and diameter of the pipes are dimensioned so that the pipes alone bear the load on the post, ie their share of the fireplace's own weights. An elongate reinforcement such as brush steel may be installed in the tube and concrete may be poured into the tube 15 and allowed to harden. For the lower end of the reinforcement, a recess is drilled through a hole in the lower base into a bearing structure, such as a concrete transducer, into which the end of the brush steel is fitted. Reinforcement and concrete support the lower end of the tube in place on the upper surface of the load-bearing member, i.e., prevent the lower end of the post from moving on the surface of the load-bearing member. Concrete can be nor-20 concrete with a density of natural aggregate, or so-called concrete. lightweight concrete, which uses a lighter material than natural rock material, such as light gravel, as the aggregate. The advantage of lightweight concrete compared to ordinary concrete is that it has a lower thermal conductivity, which prevents the formation of such a large bridge over the posts.

The tube may be poured into substantially full concrete, or alternatively, concrete shall be poured into the lower part of the tube and the upper portion of the tube filled with heat insulating material.

g The thermal insulation material may be, for example, polyurethane extruded in a tube.

i gj By forming the top end of the posts with heat insulation material, x can effectively break the cold bridge formed by the posts. The relative proportions of the heat-insulating material and the concrete 30 may be selected on a case-by-case basis. The pipes can even be completely filled with heat insulation material, whereby no concrete is cast into the pipes. In addition, a separate trough-type thermal insulation can be installed on the outside of the kay, further reducing the cold bridge formed by the posts.

In yet another preferred embodiment of the method according to the invention, at least one support plate 4 is provided on the upper end of the pole / posts with a support surface on the upper surface of the base. The fireplace arranged on the top ends of the posts then rests against the support surface of the support slab (s). The support surface of the support plate is clearly larger than the cross sectional area of the upper end of the post, so that the support plate distributes the upper end support reaction over a wider area on the underside of the fireplace. Each post may have its own support plate or two or more posts may have a common support plate. It is also possible to use only one support plate underneath the fireplace, to which the tops of all posts are attached.

The support plate is first fixed to the top ends of the tubes, after which the tubes are installed in the holes in the bottom. The lower surface 10 of the support plate has a short tubular sleeve with threads on its inner surface. Correspondingly, there are threads at the top of the tube. The tubes are attached to the support plates by screwing their top ends into the threads of the sleeve. The overall length of the posts, i.e. the distance between the lower end of the tube and the support plate, can thus be adjusted as needed by rotating the tube about its longitudinal axis. The support plate has a casting hole at the sleeve through which my be-15 can be inserted into the tube. The support plate can be glued to the bottom plate surface plate.

In another preferred embodiment of the method according to the invention, a fire-resistant insulating board is provided on the support surface of the support slab and a fireplace is provided on said insulating board. According to fire regulations, fireplaces should generally have a safety distance of at least 50 mm to combustible material below the fireplace. In wood-based subfloors, this will in practice always require the installation of a fire-resistant layer of material between the fireplace and the subfloor. The fireproof insulating panel used in the method conveniently provides the fireplace with a safety distance requiring fire standards. Preferably, a commercially available board consisting of calcium oxide (CaO) and silica (SiO 2) is used as the commercially available Skamol Super-lsol board. The insulation board may be a separate part that is glued ™ to the surface of the support plate, or the insulation board may be pre-attached to the support board.

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cp cv In yet another preferred embodiment of the method of the invention, x the fireplace is brought into space as a substantially ready-to-use part and

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“30 on its bottom over the bottom. Stone fireplaces have traditionally been used to make on-site construction. However, factory-made fireplaces, which are brought into ready-to-use units on site, have become more common recently.

° Such a finished stone fireplace has a rigid base slab on which the fireplace is built. In a preferred embodiment of the invention, the finished stone-35 fireplace is brought into the space and installed at its intended location 5 on the base. The bottom of the fireplace may have a prefabricated fire-resistant insulating board pre-assembled.

In another preferred embodiment of the method according to the invention, a chimney is provided in connection with the fireplace. The chimney can be mounted on the fireplace 5 or it can be supported like a fireplace in a load-bearing structural member based on the ground. The chimney mounted on the fireplace is connected from its lower end to the upper surface of the fireplace so that it does not need its own pole. The chimney placed on the side of the fireplace, in turn, requires its own foundation, whereby it is appropriate to support the lower part of the structure through a column passing through the base. Preferably, the chimney is a prefabricated building component that is brought to the site as one ready-to-install component.

The fireplace foundation of the invention is intended to be used in particular in connection with a ventilated subfloor. The ventilated bottom has a ventilated air space, the so-called. crawl space, between the underside of the base and the surface of the base. The foundation 15 has a load-bearing structural member below the base, separate from the base, to which the loads of the fireplace above the base are led. Preferably, said bearing member is a concrete sensor based on the ground. According to the basic idea of the invention, the foundation comprises at least one post for passing through a base, which has a lower end supported by a structural member 20 and an upper end extending substantially to the plane of the upper surface of the base. Preferably, the foundation comprises at least three posts passing through the bottom, for supporting the fireplace, the posts having a lower end supported by a structural member and an upper end extending substantially to the plane of the upper surface of the base.

In a preferred embodiment of the foundation of the fireplace according to the invention, the posts / posts comprise a pipe having a lower end extending to the bearing member and extending substantially to the plane of the upper surface of the lower base. The wall thickness S and the diameter of the pipes are dimensioned so that the pipes alone bear the load on the column i, i.e. their share of the fireplace's own weights. Preferably, the tubes are made of a metal such as steel. The tube may contain elongated reinforcement and concrete. There may also be heat insulating material inside the pipe to o reduce the cold bridge at the post.

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Another preferred embodiment of the foundation of the fireplace according to the invention the form has at least one support plate with a support surface on the upper surface of the base, at the top of the pole (s). Preferably, the distance 35 between the lower end of the post and the support plate is adjustable. The adjustability of the distance between the lower end of the post and the support plate allows for fine adjustment of the overall length of the post at the installation site to the dimensions of the installation site.

In another preferred embodiment of the fireplace foundation according to the invention, the support surface of the support slab has a fire-resistant insulating plate which provides the protection distance required by the fire regulations between the lower surface of the fireplace and the upper surface of the lower base.

An advantage of the invention is that it significantly speeds up the construction work of the foundation of the fireplace, resulting in savings in labor costs. The acceleration of foundation work is particularly noteworthy in prefabricated ventilated bases, whereby 10 inventions avoid breaking and re-supporting the bearing beams of the basement elements.

A further advantage of the invention is that it requires significantly less building material than known fireplace foundations. This results in savings in material costs.

A further advantage of the invention is that it reduces the formation of cold bridges and air leaks in the foundations of the fireplace, which improves the energy economy of the buildings and increases the comfort of living.

The invention will now be described in detail. Reference is made to the accompanying drawings, in which Fig. 1 is a cross-sectional view of a fireplace arranged in a space according to the invention and its foundation, and Fig. 2 exemplifies a method according to the invention in a simple flow diagram.

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Fig. 1 shows, by way of example, a cross-sectional view of a fireplace 100 arranged in a space of 25 cm according to the method of the invention. Shown in the picture the fireplace is arranged in a small house with a wooden, ventilated base 40.

The bearing structure of the base is made of wooden beams 46 with a heat insulation between them 48. The top surface of the beams has a continuous surface plate 44 which is made of chipboard material. A floor covering is applied to the surface plate, which may be pre-30, for example parquet, laminate or plastic mat (floor covering not shown). On the underside of the thermal insulation there is a windshield layer 50, which may be, for example, porous fibreboard, windshield paper, windshield wool or plywood.

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Below the bottom is a ventilated airspace 60, so-called. a crawl space, the bottom of which is formed by a smoothed crushed stone layer 82. The air space may be, for example, 50 to 80 cm high. The construction of a ventilated wood-based subfloor is a well-known technique and is not described in further detail herein. On top of the crushed stone layer 5 is a frost insulation layer 62 of extruded polystyrene, on which is placed a concrete anchor 70. The concrete anchor is molded in connection with the casting of the foundations of a small house.

The bottom floor 40 is drilled with holes 42 extending from the inside of the building through the surface plate 44, the thermal insulation 48 and the wind protection layer 50 to the air space 60. The hole diameter 10 can be, for example, 80 mm. Figure 1 shows two holes. In reality, there are four holes, and they are inside the circle defined by the outer surface of the fireplace, close to 100 corners of the fireplace. Holes are provided with steel tubes 12, the lower end of which lies against the upper surface of the concrete anchor 70 and whose upper end extends substantially up to the level of the upper surface of the lower base. The pipes may be, for example, te-15 tufted plumbing pipes with an outer diameter of about 76 mm and a wall thickness of a few millimeters. Inside the tube is a ridge steel bar 18 with a downwardly facing end disposed in a recess 19 drilled on the upper surface of the concrete anchor. the upper surface being substantially flush with the upper surface of the lower sole. The wall thickness and diameter of the tube are dimensioned so that the tube alone can carry the loads applied to the post. Concrete poured into the pipe supports the lower end of the post with a brushed steel inside the pipe, fixedly fixed to the concrete transducer.

25 At the top of each post is a support plate 14 with a lower base face

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^ lays against the face plate 44. The support plate is a steel plate with a thickness of about 6 mm. The support plates are fixed to the base plate surface plate by means of an adhesive arranged between the contact surfaces.

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9 floors. At the same time, the adhesive layer acts as a seal to prevent air leakage from the space through the gap between the support plate and the surface plate in the hole 42. The bottom half of the support plate | 30 has a tubular sleeve 15 with threads on its inner surface. The diameter of the sleeve w is dimensioned to fit a hole 42 drilled in the lower base. The outer surface of the upper end of the pipe dow 12 has threads compatible with the threads of the sleeve. Tube £! can thus be secured to the sleeve by rotating its upper end onto the threads of the sleeve. The pipe w, with a transverse, flat diameter steel tube at its top end. The flat steel acts as a gripping element that can be grasped by a tool used to rotate the tube. By rotating the tube, the total length of the column, tube, sleeve, and 8 support plate can be adjusted so that the lower end of the tube sits against the upper surface of the pod when the lower surface of the support plate rests against the upper surface of the upper base. The possibility of adjusting the length of the post allows the distance between the surface of the transducer and the dimensional deviations of the base to be compensated during the post installation step.

The support plate has a casting hole 17 at the sleeve through which fresh concrete mass can be poured into the pipe from the room space of the building. The upward facing surface of the support slab forms a fireplace bearing support surface 20. The support surface is provided with a fire resistant, 50 mm thick, insulating board 16 having the same shape as the horizontal projection of the fireplace base. On top of the insulating board is a prefabricated stone fireplace 100, which is brought into the building as a ready-to-use part and lowered into place on the base. On top of the fireplace is a chimney 110, the flue of which is connected to a flue connection on the top of the fireplace. The dead weight of the fireplace and chimney is transferred through the insulating board and support plates 15 to the top ends of the posts 10 and further along the posts to the concrete sensor 70 below the bottom floor 40.

Figure 2 illustrates, by way of example, the steps of the method according to the invention by means of a simple flow chart. The reference numerals used in the description of the figure refer to the fireplace foundation shown in Figure 1. The method comprises arranging 20 fireplaces in a small house with a wooden, ventilated bottom 40. Initially, holes 42 for the posts 10 are drilled into the bottom. The locations of the holes are selected so that they remain below the fireplace arranged on the bottom, i.e. inside the circuit defined by the outer surface of the fireplace. The holes are intended to be positioned substantially uniformly within the circuit so that substantially equal load is applied to the post. In addition, the selection of hole positions 25 takes into account that the holes do not break or damage the base of the base.

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5 through the wooden beams 46. The holes are drilled through the entire bottom, i.e. the hole passes through the surface ™ 44, the thermal insulation 48, and the wind protection layer 50.

cp £ j After the holes for the posts have been drilled, recesses 19 are provided for the upper surface of the concrete sensor i 70 on the bottom of the airspace 60 for the ribbed steel bars 18. The locations 30 of the recesses are defined so that the recesses enter as precisely as possible into the center of the posts to be formed. The posts are arranged in a substantially vertical position <3, so that the recesses 19 are formed in the concrete sensor so that they are substantially vertical with the centers of the holes 42. The recesses are made by drilling short holes in the concrete anchor. Drilling can be done with a long drill 35 through the holes 42 from inside the building or from the air space below the floor.

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Next, the posts 10 are made by screwing the upper ends of the tubes 12 onto the sleeves on the underside of the support plates 14. Glue is applied to the surfaces facing the underside of the support slabs and the tubes are fitted into the holes in the underside so that the support slab at the top of the tube rests firmly against the underside topsheet 44. The lengths of the tubes 5 are dimensioned so that their lower ends are then fixed on or very close to the surface of the concrete anchor. By twisting the tube, adjust the length of the post so that the lower end of the tube rests firmly against the upper surface of the probe. When the tubes are in place, the ribbed steel bars 18 are mounted inside them. The downwardly facing ends of the bars are inserted into the recesses on the surface of the concrete anchor and the concrete 10 is cast into the tubes 10 and allowed to harden. After the concrete has hardened, the posts are ready to receive the weight of the fireplace on them. As a concrete, it is preferable to use a fast curing so-called. fast concrete, which reaches sufficient strength in just a few hours.

A fireproof insulating panel 16 is mounted on top of the support slabs, on which 15 a ready-to-use, stone-built fireplace 100 is placed. Finally, the necessary finishing work is carried out, such as the barrel damper and the installation of the smoke dampers, after which the fireplace is ready for use.

The method of the invention is particularly well suited for use when a stone-built fireplace is provided in the space 20 and is brought in as a single, complete, ready-to-use part, and a one-piece ready-to-use chimney is connected to the fireplace. In this case, all the foundation work of the fireplace and the installation of the fireplace and chimney can be done within one working day. However, the invention is not limited to the use of ready-to-use stone fireplaces and chimneys. A fireplace arranged on a Ti-25 can thus also be a brick or soapstone masonry on site. A built-in fireplace, a fireplace made of refractory castings, a masonry fireplace, or a predominantly metal fireplace or fireplace. In this case, arranging a fireplace in a C \ 1 9 space means masonry or assembling the fireplace in its intended location.

c \ i Chimney can be a brick chimney, of refractory drainage mass | 30 of the formed pieces is a masonry barrel or a predominantly metal structural barrel.

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eu Some preferred embodiments of the method of the invention and the fireplace foundation have been described above. The invention is not limited to the examples described above, but the inventive idea can be applied in various ways within the scope defined by claims 35.

Claims (21)

A method of arranging a fireplace (100) in a space having a resilient lower bottom (40), below which the lower bottom is an air space (60) and a supporting structural member supporting the ground (80), characterized by In the process of forming at least one through-going shark (42) in the lower bottom, a post (10) having a lower end supporting the supporting structural member and an upper end extending substantially thereto are provided the level of the upper surface of the lower bottom, and a fireplace is arranged on the lower bottom so that at least part of the weight of the fireplace is directed to the upper end of said post. Method according to claim 1, characterized in that in the method, at least three through-going heels (42) are formed in the lower bottom (40) and in each heel there is provided a post (10) having a lower end which supports the supporting structural part. and an upper end which extends substantially to the level of the upper surface of the lower base, and a fireplace (100) is arranged on the lower bottom so that the weight of the fireplace is directed substantially entirely towards the upper ends of said posts. Method according to Claim 1 or 2, characterized in that the supporting structural part supporting the ground (80) is a concrete bottom plate (70). Method according to any one of claims 1-3, characterized in that the fireplace 20 is arranged in a space, the resilient lower bottom (40) having a surface plate (44) of a combustible material and whose lower base supporting structures comprise wooden beams (46). Method according to any of claims 1-4, characterized in that the posts CO 5 (10) are formed of tubes (12) installed in the heel (42), which tubes have a lower end, extending to the supporting structural part. , and an upper end which extends substantially C \ 9 to the level of the upper surface of the lower bottom (40). CM x Method according to claim 5, characterized in that an "elongated iron bracket (18) is installed in the pipe (12) and concrete (30) cast into the pipe which has been hardened. CO o in Process according to claim 5 or 6, characterized in that at least part o of the pipe (12) is filled with a heat insulating material. CM 14 Method according to any one of claims 1-7, characterized in that at least one support plate (14) is provided on the upper end of the pillar (s) (10) located on the upper surface of the lower bottom (40), which has a support surface ( 20). Method according to claim 8, characterized in that the support plate (14) is glued to the surface plate (44) of the bottom bottom (40). Method according to claim 8 or 9, characterized in that on the supporting surface (20) of the support plate (14) a fire-resistant insulating plate (16) and the fireplace (100) are arranged on said insulating plate. Method according to any of claims 1-10, characterized in that the fireplace (100) is retrieved into the space as a substantially ready-to-use part and lowered into place on the lower bottom. Method according to any one of claims 1-11, characterized in that a chimney (110) is installed in connection with the fireplace (100), which chimney is installed in the fireplace or supported as well as the fireplace on the supporting structure part (70). ) which rests on the ground (80). 13. A fireplace (100) base in connection with a resilient lower bottom (40), which base has a supporting structural part below the lower bottom, separately from the bottom bottom, characterized in that said base comprises at least one post (10) which through the lower bottom for supporting the fireplace, said post having a lower end supporting the supporting structural member and an upper end extending substantially to the level of the upper surface of the lower bottom. 14. A fireplace (100) base according to claim 13, characterized in that it comprises two or more at least three posts (10) which pass through the lower bottom (40) to support the fireplace, which posts have a lower end which supports the structural member and an upper end which extends substantially to the level of the upper surface of the lower bottom. X £ 15. Fireplace (100) foundation according to claim 13 or 14, characterized in that the g bearing structural part supporting the ground (80) is a concrete bottom plate (70). δ ^ 30 Fireplace (100) base according to any of claims 13-15, characterized in that the post (s) (10) comprises a pipe (12) having a lower end extending to the supporting structural part and an upper end. which extends substantially to the level of the upper surface of the lower bottom (40). Fireplace (100) foundation according to claim 16, characterized in that inside the pipe (12) there is an elongated iron bracket (18) and concrete (30). 18. A fireplace (100) foundation according to claim 16 or 17, characterized in that inside the pipe (12) there is thermal insulation material. A fireplace (100) foundation according to any of claims 13-18, characterized in that at the upper end of the post (s) (10) there is at least one support plate (14) located on the upper surface of the lower bottom (40), which has a support plate. support surface (20). Fireplace (100) base according to claim 19, characterized in that the distance between the lower end of the post (10) and the support plate (14) can be controlled. Fireplace (100) foundation according to claim 19 or 20, characterized in that on the supporting surface (20) of the support plate (14) there is a fire-resistant insulation board (16). CO δ C \ J C \ l O CM X IX CL CO o CM m CM δ CM