RU2334050C2 - Basement structure - Google Patents

Abstract

FIELD: building.

SUBSTANCE: invention refers to construction of the basements of buildings. The basement structure of a building includes heat - and waterproofing layer (17, 18, 40) which is laid on a flat horizontal surface (51) layer of the material breaking capillary action. The basement structure includes a frame (31) which surrounds specified heat - and waterproofing layer (17, 18, 40), at least, in its top part, thus fixing integrity of basement structure in a horizontal plane and which serves for punctiform bracing of the building supported by basement structure. The specified basement structure is encapsulated with foil (111) from a metal material.

EFFECT: prevention of smell penetration in a building and water-proofing maintenance; possibility of fast and energy conserving erection of the basement.

8 cl, 8 dwg

Description

The present invention relates to the foundation structure of a building. Foundation structures of this type possess the features set forth in the restrictive part of claim 1 of the claims of the present invention.

More specifically, the invention relates to a foundation structure erected on the ground. Usually, the soil is drained, and a layer of material that violates the capillary action, for example, crushed stone (crushed stone) having a particle size of 2-4 mm, is laid on a flat horizontal upper surface of the soil.

From the experience gained over a long period of construction of foundations, it is well known that when building a foundation directly on the ground there is always a risk of moisture seeping through the foundation and entering it into the structure erected on this foundation. Smells are also able to penetrate the foundation. In particular, it was also found that the intrinsic soil odor, the “jasmine” odor, also tends to penetrate well-known foundation structures.

The foundation structure must not only be impervious to odors, but also must be installed quickly and at low cost, while the impermeability of the foundation structure will also satisfy the requirements of its integrity.

In accordance with this, the aim of the present invention is the manufacture of a generally odor-tight foundation structure of the desired size, which can be easily assembled from lightweight elements.

A foil impervious to jasmine odors and retaining its integrity in the medium in which it is placed for an extremely long time, for example, about a hundred or several hundred years, is placed on a bearing surface in the form of a properly leveled layer laid on a soil site. . Such a foil is often exposed to soil moisture and condensate in an environment, which can often be acidic or contain aggressive substances. Therefore, a metal foil is particularly suitable, which can withstand exposure to such an environment for a long time, while remaining impervious to jasmine odors.

If a metal foil, for example aluminum foil, is laid directly on the said leveling layer so that it is in direct contact with the granular material of this layer, then the foil should preferably be relatively thick, for example, about 0.1-1 mm thick, so that over time did not become permeable due to the influence of the building weight on it through the foundation elements and close contact with the leveling layer. Metal foil of such thickness can be obtained in the form of a roll, which can be rolled right at the installation site of the foundation structure in the area for the foundation. To reduce the risk of damage to the foil when it is laid under the foundation, the foil must also have high tensile strength. If, in practice, the width of the foil is less than the width of the foundation structure, the foil panels can be stacked side by side and interconnected, for example by a lap, to ensure that the foil is impervious to odors. In accordance with this task, the width of the foil to be injected may be specified, which may have a strip or layer of glue, adhesive tape or easily deformable foil, preferably an elastic foil, having a sufficient width to overlap the inlet and thereby ensure that the foil is impervious to odors over a wide area of air penetration . Typically, a single lap joint between adjacent sheets of aluminum foil is sufficient, since such joints are usually under overpressure along their entire length. Before laying the metal foil, the leveling surface may first be covered with plastic foil, for example, to prevent sand from entering the possible lap between adjacent aluminum foil sheets. In one embodiment, the aluminum foil may be laminated with a plastic foil if necessary, for example, for the convenience of manual operations, although the relatively thick and odorless foil, preferably the aluminum foil used in accordance with the present invention, can maintain its integrity for extremely long time and even in hostile environment. Most types of plastic foil will not maintain integrity in such an environment for the same period of time.

Of course, an embodiment of the invention is possible in which an odor-proof foil, for example aluminum foil, can be placed between two layers of heat-insulating material contained in the foundation structure. In this case, the aluminum foil may be thinner, since the insulating material forms a smooth and even bearing surface on which the foil can be rolled.

The purpose of the present invention has been achieved. The invention is described in the following independent claim, while particular embodiments of the present invention are described in the dependent claims.

In a particularly preferred embodiment of the present invention, the soil surface is first prepared by draining the soil and then laying on the surface a layer of material that violates the capillary action, for example, gravel having a particle size of 2-4 mm, followed by leveling this layer to create a flat and horizontal surface.

The first layer is laid densely, one on top of the other, of the finished sheet or finished sheets of a standard size, for example rectangular sheets of porous insulating material, such as 50 mm thick foamglass (foamglas ^R ). It is also possible to lay another layer of such closely adjacent sheets; wherein the connections between adjacent sheets of the second layer should be shifted relative to the connections between adjacent sheets of the first layer.

Seams when joining these sheets should be tried to be impervious to liquids. A porous insulating material is preferably foam glass (foamglas ^R ) or any other material that has minimal surface absorption and volume absorption with respect to water, and is extremely resistant to pressure, able to withstand parasites, is an effective heat insulator and has diffusion impermeability.

It is convenient to surround the insulating layers with a frame, the elements of which can consist of channel profiles made of sheet metal, the concave side of which is turned inside the foundation element. The section inside the frame is filled with compression-resistant heat-insulating material, for example, two layers of porous insulation superimposed on each other (foam glass 2 × 100 mm). The foundation element frame can be stabilized by mounting I-beams made of sheet metal into it parallel to one of the channel profiles of the frame. The beams of the foundation element are mechanically connected so as to stabilize it. The foundation element may have a thickness of, for example, 200 mm. When channel profiles and I-beams are used in the foundation element, the fixation of porous insulating sheets with respect to the beams is ensured by giving the sheets an appropriate shape and introducing a portion of the sheet adjacent to the beam into the recess of the beam. At the same time, the upper horizontal shelves of the beams can serve for the point of fixing the wall structure of the building, erected on the foundation structure. The building by design may take the form of a finished box, as a rule of factory production, manufactured at a distance from the foundation structure. It is also possible that the foundation element is placed separately on the foundation structure, and then loose components of a wooden structure or frame house are installed on it, which are then attached to the metal shelves of the foundation element.

It has been found that, in practice, odors do pass through the sealing foil, even plastic foil with a low transmission of odors, so it is preferable to use a sealing layer comprising a metal alloy or metal.

As far as we know, aluminum foil provides the necessary impermeability to odors already at a thickness of 0.01 mm, although a thicker foil, of course, will be more reliable in this regard, and will also contribute to the early cocking of the foundation structure, since this type of foil can be delivered to rolls that can be easily turned into strips, straightened and laid on a foundation structure.

The invention is further described with reference to the accompanying drawings, in which:

figure 1 schematically depicts a vertical section of the proposed base structure;

figure 2 schematically depicts the lap connection of two strips of foil from impervious to odors of the material;

figure 3 depicts a variant of the vertical section shown in figure 1;

figure 4 schematically depicts a vertical section of the proposed foundation structure in another embodiment;

5, 6 and 7, respectively, depict cross-sections of frame elements in the frame structure, which can be included in the base structure; and

Fig. 8 shows an embodiment of a sheet to which a sealing foil is attached.

As shown in FIG. 1, at the installation site of the foundation structure, there is a dried layer of soil 50, which itself can serve as a barrier to capillary action or have a coating serving as such a barrier, preferably in the form of a crushed stone layer, with the upper surface 51 of the barrier 50 being essentially flat and horizontal.

An aluminum foil or metal sheet material 111 having a preferred thickness of at least 0.1 mm, preferably 0.3-0.5 mm, is placed on surface 51. A layer of heat-insulating material, preferably foam glass, is laid over the foil 111. The foam glass sheets 40 are joined together and stacked on top of the foil 111. The sheets 40 are stabilized by a frame 31 that surrounds at least the mutually connected sheets 40.

If the foil 111 is obtained in the form of strips whose width is less than the width of the base structure, the foil strips can be laid with the connection 112 lap. To minimize the likelihood of odors penetrating in the vertical direction through the interconnected strips of foil 111, a sealing layer, such as a durable adhesive, can be applied across the width of the joint. Otherwise, the tightness of the seam can be achieved by welding, adhesive tape or similar technical means.

Figure 3 shows an embodiment in which a layer 17 of heat-insulating material, for example, mutually connected sheets of foam glass 10, is placed on the surface 51 of the barrier that prevents capillary action, and aluminum foil is placed on the layer 17 before laying the layer of the base layer, made in the form of sheets 40 and frames 31, on foil 111.

Figure 4 shows a variant in which before laying the frame with sheets 40 on the layer 18 on the foil 111 there is another layer 18 of sheets 10, mutually connected at the edges.

The frame 31 surrounds the foundation layer formed by sheets 40, fixing the integrity of the foundation structure in the horizontal plane, and also serves to pinpoint the building supported by the foundation structure. In accordance with one embodiment of the invention, cut-outs for the shelves of frame elements 32, usually in the form of a channel, can be made in the open parts of the edges of the sheets 40 (Fig. 5). In the embodiment of the invention shown in FIG. 6, the frame member 32 has approximately the same height as the sheets 40, with the upper and lower surfaces of these sheets being slightly cut to allow shelves of the frame members 32 to be placed. As shown in FIG. 6, I-beams 37 can be arranged in the joints between adjacent sheets 40, said sheets having cutouts at the junction points to fix the flanges of the I-beams, so that the I-beams can also have the same height as the sheets 40. However, it is currently preferred that the free distance between the shelves of the frame elements corresponds to the thickness of the sheets of insulating material. Shelves of frame elements have only a small thickness, for example, a thickness of 1 mm, and their location above the main surface of the sheets usually does not cause problems.

The frame 31 is usually rectangular in shape and includes straight, channel profiles made of sheet metal, which are connected to each other (Fig. 7) in the corners of the frame using rivets, screw joints, adhesive joints or corresponding devices for connecting between overlapping portions of the profile shelves . Moreover, the profiles have essentially the same dimensions of the jumpers and a small thickness of the material, for example 1 mm

From figure 6 it is seen that between the elements of the frame 31 can be stretched rods 43 to hold the frame elements in a horizontal plane.

It should be noted that the frame 31 with the attached sheets 40 of thermal insulation material can be part of the finished volume unit, so that the foundation can be made by installing such a unit on the foundation structure and adding any parts of the foundation that can be previously mounted at the installation site of the foundation structure and by which blocks can be interconnected with the formation of the building on a foundation structure.

Obviously, the foundation structure can be made as shown in FIGS. 1, 3, and 4, and a building frame can be erected on it from loose wooden parts or blocks and attached to the frame structure.

In a modification of the embodiment shown in FIGS. 3 and 4, it is possible to use an additional frame that fixes the remaining insulating layers and, possibly, intermediate or external sheets 111 of foil or metal.

One of the heat-insulating layers (17, 18) can be formed preferably by rectangular heat-insulating sheets 10 connected to each other at the edges. One main surface of the respective sheets 10 may be coated with a piece of metal foil 11, preferably aluminum foil. The pieces of metal foil 11 on the sheets 10 can be hermetically sealed to the inlet, for example, by means of the overlapping edges 12 of the metal foil located on the foil side of the neighboring elements along their respective joints. It is also possible that the foil covering the respective sheets 10 may have an edge 12 protruding beyond the edges of two adjacent elements and overlapping the foil covering the edges of the neighboring elements.

Both layers 17, 18 can be formed by connecting the finished sheets 10 to the coated foil 11. The sheets 10 of these two layers are conveniently oriented so that their shells of the foil 11 are in contact with each other, so that the insulating sheets 10 layers 17, 18 were separated by adjacent foil layers. Shells or foil coatings 11 on sheets 10 are equivalent in composition to the foil 111 described above.

Preferably, the joints between the sheets 10 of the respective layers 17, 18 are offset from each other.

Claims (9)

1. The base structure of the building, including heat and moisture insulation layer (17, 18, 40), which is laid on a flat horizontal surface (51) of the layer of material that violates the capillary action, characterized in that it includes a frame (31) that surrounds the specified a heat and moisture insulation layer (17, 18, 40), at least in its upper part, while fixing the integrity of the foundation structure in the horizontal plane, and which serves to pinpoint the building supported by the foundation structure, while the specified foundation The structure is sealed with a foil (111) of a metal material. 2. The base structure according to claim 1, characterized in that the foil (111) is located under the specified layer (17, 18, 40). 3. The base structure according to claim 1 or 2, characterized in that the foil (11) is located directly on the specified surface (51), which is formed by a layer that serves as a barrier to capillary action and preferably consisting of crushed stone or gravel. 4. The base structure according to any one of claims 1 to 3, characterized in that the aluminum foil is used as a foil, at least about 0.1 mm thick, preferably less than 1 mm thick, and more preferably about 0.5 mm thick. 5. The base structure according to claim 1, characterized in that said layer (17, 18, 40) includes at least two rows (17, 18) of insulating material, while the metal foil (111) is located between two adjacent vertical direction in insulating rows. 6. The base structure according to claim 5, characterized in that the foil (111) has a thickness of at least 0.01 mm, preferably a thickness of at least 1 mm. 7. The base structure according to any one of claims 1 to 6, characterized in that the parts of the frame (31) together with the parts of the heat and moisture insulation layer are connected to the corresponding finished building volume blocks, which, when installed on the foundation structure, form the building frame on it. 8. The base structure according to claim 5, characterized in that each of the heat-insulating layers (17, 18) is formed by sheets of insulating material connected to each other (10), while one main surface of each sheet (10) is covered with a piece of foil (11) , these pieces of foil (11) together form the specified foil (111), the layers (17, 18) are covered with the indicated pieces of foil (11) on the sides facing each other, the edge (12) of the specified foil material, preferably aluminum foil, seals the coatings (11) of foil on adjacent sheets (10) of at least bottom of the layers (17, 18); and the connections between the sheets (10) in the respective layers (17, 18) are offset from each other. 9. The base structure according to claim 8, characterized in that the edges (12) are formed by the edges (12) of the foil covering the sheets that protrude beyond the edges of the respective sheets (10) along their two adjacent edges, the protruding edges (12) of the specified coating of foil are arranged so that they overlap the adjacent edges of the foil coatings (11) on adjacent sheets.

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