RU2311516C2 - Resilient member for false floor and production method thereof - Google Patents

Abstract

FIELD: construction, particularly flooring or floor layers composed of a number of similar elements.

SUBSTANCE: resilient member defines mounting member having length substantially exceeding width thereof and including upper and lower structures. The first support means and the second support means are arranged between the upper and lower structures. The first support means provide upper and lower structure installation at the first distance H1 one from another in height direction. The second support means are located from opposite side of lower structure with respect to the first support means. The second support means provide lower structure arrangement at the second distance H2 from structure located under lower structure in height direction.

EFFECT: provision of uniform floor flexibility.

11 cl, 7 dwg

Description

The invention relates to an elastic element for a suspended floor, and the specified element is to be placed under the surface layer of the floor and provides the possibility of springing of the surface layer when subjected to loading, while the specified elastic element forms an installation element, the length of which significantly exceeds its width, and the element contains:

the upper structure and the lower structure, the structures being elastic, at least to some extent parallel to each other and essentially horizontal and located one above the other in the installed elastic element;

the first supporting means, which are located between the upper structure and the lower structure at a first distance from each other in the longitudinal direction of the elastic element, the first supporting means providing the upper structure and the lower structure at a first distance in the height direction from each other;

second supporting means that are located on the opposite side of the lower structure with respect to the first supporting elements and at a second distance from each other in the longitudinal direction of the elastic element, the second supporting means having a height for placing the lower structure at a second distance in the height direction from the structure, located under the specified design;

moreover, the first support means are located in the longitudinal direction of the elastic element in places in the specified elastic element, essentially different from the locations of the second support means.

The invention also relates to a method of manufacturing a suspended floor, and in this method, the surface layer is placed on the elastic elements, and the elastic element forms a mounting element, the length of which significantly exceeds its width, and the element contains:

an upper structure and a lower structure, wherein the structures are resilient, at least to some extent, parallel to each other and substantially spaced one above the other in the installed elastic member;

the first supporting means, which are located between the upper structure and the lower structure at a first distance from each other in the longitudinal direction of the elastic element, the first supporting means providing the upper structure and the lower structure at a first distance in the height direction from each other;

second supporting means that are located on the opposite side of the lower structure with respect to the first supporting elements and at a second distance from each other in the longitudinal direction of the elastic element, the second supporting means having a height for placing the lower structure at a second distance in the height direction from the structure, located under the specified design;

moreover, the first support means are located in the longitudinal direction of the elastic element in places in the specified elastic element, essentially different from the locations of the second support means.

In some rooms, the floor should not be too rigid, but it should be accordingly elastic, that is, the floor should be a suspended floor. Such facilities include, for example, places for ball games in rooms, such as squash, basketball and volleyball courts, floors in dance halls, floors for ballet dances, gyms, etc.

In a suspended floor, the surface layer may be made of parquet, laminate or plastic flooring. Elastic structural elements, that is, elastic elements located between the black floor - formed, for example, from concrete - and the surface layer, are an essential part of the suspended floor. Elastic elements lift the surface layer from the subfloor and allow the surface layer and other possible floor coverings located above it to spring [apply] under the influence of a local and often suddenly applied load of short duration to which the surface layer is exposed. There are a number of standards that define the elastic properties required from suspended floors.

To create a suspended floor, there is a known construction in which elastic elements are used, consisting of a plywood board, which has a width of approximately 400 mm and a length of 2.4 m, and its edge sections on the lower surface of both longitudinal sides are provided with rubber gaskets located at a given distance from each other. On the upper surface of both longitudinal sides there are attached plywood panels that have a width of approximately 60 mm and extend over the entire plywood plate, while the plywood panels serve as load-bearing beams on which structures are located, located on top of the elastic elements. Before installing the covering boards, the elastic element is fixed to the base using anchor means configured to pass through the plywood board. The problem associated with the design described above is the weight and consumption of materials on the elastic elements. In addition, the range of regulation of the elastic properties of the elastic element is limited: the change in the elastic properties can be carried out only by changing the material of the rubber gaskets or the distance between them. Another design is also known in which elastic elements are used and which is intended to create a suspended floor. In this design, the first slats, which have a width of approximately 50 mm and are made of plywood, are placed as the lowest elements with a predetermined interval on the black floor. On the bottom surface of the rails there are rubber gaskets at predetermined distances from each other: in this way the rails rest on rubber elements on the black floor. The second transverse rails made of the same plywood as the first rails are mounted on top of the first rails perpendicular to them. Seen from above, it can be seen that the slats form a lattice structure. Between the intersecting rails can be placed rubber elements. A covering board, such as a plywood board, is fixed on top of the second battens, and a surface material such as parquet is fixed to the plywood board. The problem associated with this design is the complex and slow installation, which increases installation costs.

An object of the present invention is to provide an improved resilient element for a suspended floor and a method for manufacturing such a floor.

The elastic element according to the invention is characterized in that there is a tongue at one end of the upper and lower structure, and a ridge at the opposite end, the ridge and tongue being made in such a way that the elastic element can be connected at its ends to another similar elastic element by means of a tongue and groove joint .

The elastic element according to the invention has the advantage that it is supplied ("spring") uniformly and essentially the same way at all points of the floor. In addition, the advantage is that the elastic properties can be easily and simply changed. An additional advantage is that the elastic elements provide the ability to quickly and firmly connect them to each other due to the tongue and groove connection, and the connection between the elements will be strong. Another advantage is that the manufacturing costs of the resilient member are low.

The method according to the invention, intended for the manufacture of a suspended floor, is characterized in that there is a tongue at one end of the upper and lower structure, and a ridge at the opposite end, the ridge and tongue being made in such a way that the elastic element can be connected at its ends to another similar elastic element through the tongue and groove connection, and in this method, the elastic elements are connected to each other at their ends by means of tongue and groove joints.

The method according to the invention, intended for the manufacture of a suspended floor, has the advantage that it is characterized by the speed and ease of implementation, while the installation costs remain low. An additional advantage is that the elastic elements can be tightly packed, and therefore, the transportation costs will be much lower: the required area for transportation and storage is only one fifth of the area for a known structural element such as trusses.

In addition, the main idea of the preferred embodiment of the elastic element is that its upper and lower structures and supporting means are made of at least mainly plywood, which is a strong and flexible material with fatigue resistance. The main idea of the second preferred embodiment of the elastic element is that the first and / or second supporting elements are made of elastic material, which increases the elasticity of the elastic element and the suspended floor. In addition, the main idea of the third preferred embodiment of the elastic element is that the upper and lower structures are made stepwise with respect to each other, as a result of which the connections of the series-connected elastic elements form a kind of sheet pile structure that ensures equalization of stresses, which exposed element.

Below the invention is described in more detail with reference to the attached drawings, in which

figure 1 is a schematic side view of a variant of implementation of the elastic element according to the invention;

figure 2 is a schematic top view of the elastic element of figure 1;

FIG. 3 is a schematic side view of an embodiment of a support member of an elastic member according to the invention; FIG.

FIG. 4 is a schematic side view of the ends of one embodiment of the elastic member of the invention; FIG.

5 is a schematic side view of the connection of an elastic element according to one embodiment of the invention with another similar element;

6 is a schematic side view of an embodiment of an elastic element according to the invention; and

Fig.7 is a schematic top view of a suspended floor made by the method according to the invention, and the view is made with a partial opening of the inner part of the floor.

FIG. 1 is a schematic side view of an embodiment of an elastic element according to the invention, and FIG. 2 is a schematic top view of an elastic element of FIG. 1.

The elastic element 1 comprises an upper structure 2 and a lower structure 3, which is located at a first distance H1 from the upper structure and which is parallel to the upper structure. In the installed elastic element 1, the upper structure 2 is located above the lower structure 3. The first supporting means 4, which hold the structures 2, 3 at a first distance H1 from each other, are located between the structures 2, 3. The elastic element 1 contains many of the first supporting means 4 the length of the element, with the first supporting means 4 following one after the other located at a first distance D1 from each other.

The elastic element 1 also contains many second supporting means 5 located on the lower surface of the lower structure 3 along the entire length of the element. Subsequent second support means 5 are located at a first distance D2 from each other. The second support means 5 hold the lower structure 3 at a second distance H2 from the structure located below the elastic element 1. The first and second support means 4, 5 are located so that they are located at substantially different places in the elastic element 1, when viewed in the longitudinal direction elastic element.

Structures 2, 3 and support means 4, 5 are made of wood material, preferably plywood, which is a durable and resilient material. The plywood layers can be arranged so that they will be either in a horizontal position or in a vertical position in the elastic element 1 mounted on the floor. The supporting elements 4, 5 are attached to the structures 2, 3 with nails, screws, by means of glue or in a similar manner, which is known per se.

In addition to plywood, structures 2, 3 and support means 4, 5 can be made of any wood material that is partially or completely wood, plastic or metal, or combinations thereof. Structures 2, 3 and support means 4, 5 can be made of the same material or of different materials.

The length of the elastic element 1 significantly exceeds its width. Its length can be, for example, 2400 mm, and width - from 40 to 100 mm. The thickness of the upper and lower structures 2, 3 and supporting means 4, 5 may be, for example, from 6 to 50 mm. The dimensions, of course, may differ from those shown, but, nevertheless, the length should significantly exceed the width.

1 and 2 show the structure under the elastic element 1, which is a lifting beam 8, under which there is a black floor 9, which can be made of concrete or the like. The lifting beam 8 is made of glued wooden beams, for example, with cross-sectional dimensions of 50 · 60 mm. Lifting beam 8 can also be made of other wood material, metal or plastic, or combinations thereof. The lifting beam 8 contains adjusting elements 10, which provide the ability to control the distance between the lifting beam and the subfloor 9. By means of the adjusting elements 10, the lifting beam 8 can be installed in an exact horizontal position despite the unevenness or tilting of the black floor 9. In most cases, the operation of the adjusting element 10 is based on a threaded bolt, which is located in a sleeve with a corresponding thread. The adjusting element 8 is a component that is known per se, and therefore is not described in detail. In the case where a lifting beam 8 is used, the adjusting elements 10 are preferably located at the first support means 4, as a result of which said support means reinforce the elastic element 1 when a hole is made in the elastic element 1, for example, by drilling the first and second structures 2, 3, for adjusting the height from above. The adjusting elements 10 can also be located directly in the second support means 5, while the elastic element 1 can be placed directly on the black floor 9. This ensures a particularly low floor structure. It goes without saying that the elastic element 1 can also be located directly on the black floor 9, even without adjusting elements 10. It should also be noted that in addition to the adjusting beam 8, it is also possible to place other structures known per se, such as adjusting wedges, between the elastic element 1 and black floor 9.

In principle, a suspended floor is made by means of elastic elements 1 by placing them side by side on the floor at a predetermined distance from each other. The indicated distance can be, for example, from 300 to 600 mm, but other distances are also possible, since the properties that are required from the suspended floor in question and the surface material used determine this distance. First, a base layer 6 is first placed on the elastic elements 1, such as a particleboard or plywood plate covering the floor area, and on top of it is a surface layer such as parquet, laminate, mat or a similar floor surface. Some surface materials, such as floorboards or floorboards or load-bearing parquet floors, can be attached directly to the elastic member 1.

The elastic elements 1 support the surface layer 7, which is made with the possibility of support on them. If necessary, a plurality of elastic elements 1 can be connected in series, so that a continuous structure of elastic elements will extend over the entire length of the floor. If necessary, the elastic element 1 can be cut to the appropriate size.

When the surface layer 7 is subjected to local loading, which constantly takes place, for example, in the case of sports or dancing, the loading force acts on the upper structure 2 of the elastic element 1 located below. On the one hand, the force causes the upper structure 2 to bend in the area between the first support means 4, and, on the other hand, a part of the force is transmitted through the first support means 4 to the lower structure 3. Thus, the lower structure 3 is bent in the area between the second supporting means 5. Thus, the elastic element 1 is spring (fed) and at the same time creates the possibility of spring surface layer 7 and the base layer. Thus, the floor is to some extent elastic, or, in other words, the floor has a given rigidity.

The stiffness of the elastic element 1, that is, the elastic properties of the floor can be adjusted very flexibly and simply. For example, as the distance between the first support means 4 and the second support means 5 increases, that is, when the first distance D1 or the second distance D2 increases, the stiffness of the elastic member 1 decreases. Accordingly, as the first distance D1 or the second distance D2 decreases, the stiffness of the elastic member 1 increases. Some of the elastic elements in the floor can be adjusted so that they have a stiffness different from that of other elastic elements. This may be preferred, for example, at entrances or under structures for spectators, where the floor should be more rigid than in other parts of the floor. In this case, the elastic element 1 is made more rigid in accordance with the principle described above, for example, by adding support means between the first and / or second support means 4, 5 or by otherwise reducing the first and / or second distance D1, D2 . It is also possible to perform one part of the elastic element 1 with a stiffness different from the stiffness of other parts of the same elastic element 1. This can be realized by changing the distances D1, D2 between some of the supporting means 4, 5 relative to other corresponding distances. Thus, the first and second distances D1, D2 need not be constant over the entire length of the elastic element 1. The elastic element 1 can be given very great rigidity, so that the first and second support means 4, 5 will be essentially located one above the other, and the first and / or the second distance D1 and D2 will be further reduced. In general, the resilient properties of a suspended floor can be provided in accordance with customer requirements in a very precise manner.

The properties of the elastic element 1 can also be changed by making the support means 4, 5 either partially or completely from a substantially elastic material, such as rubber, foam rubber or foam or granular rubber. In this case, in addition to the upper and lower structures, these supporting means 4, 5 spring, which increases the elasticity of the floor. One application of this design may be, for example, a dance floor.

In the elastic member 1 of FIGS. 1 and 2, the first distance D1 is substantially equal to the second distance D2, even though this is not necessary, but the indicated distances may differ from each other.

The lower support means 5 may have a slightly wider width compared to the rest of the elastic element. Thus, the element will stand stably, being installed before fixing it in place, which facilitates installation work.

FIG. 3 is a schematic side view of an embodiment of a support means of an element according to the invention. The described support means can be used as the first or second support means 4, 5. The support means is a combination of two different materials, so that the upper component 15 is made of plywood, the layers of which are in a horizontal position, and the lower component 16 is made of elastic material for example, rubber based on a copolymer of ethylene, propylene and diene monomer, granular rubber, foam, or the like. The upper and lower components 15, 16 are connected to each other by glue. It goes without saying that the parts can also be arranged in the opposite direction or, for example, so that the elastic component is located between two essentially inelastic components. The support means can also be completely made of elastic material.

By changing the stiffness or thickness of the part made of an elastic material, it is possible to modify the elastic properties of the support means and, therefore, affect the elastic properties of the suspended floor.

FIG. 4 is a schematic side view of the ends of an embodiment of one elastic member according to the invention. At the end portion of the elastic member 1 shown to the left in FIG. 4, the upper structure 2 extends further than the lower structure 3; accordingly, at the end portion shown to the right, the lower structure 3 extends farther than the upper structure 2. In other words, the ends of the structures 2, 3 are stepped, and they end in different lines - along an imaginary outer line 17a and along an inner line 17b - on both ends of the elastic element. The indicated lines 17a and 17b in Fig. 4 are shown only in connection with the left end. Lines and structures 2, 3 are interconnected so that structures 2, 3 are perpendicular to the outer line 17a and the inner line 17b.

The distance between the outer line 17a and the inner line 17b is equal at both ends of the elastic element 1. When two elastic elements 1 are connected to each other end to end, the connection will be something like a tongue and groove connection in which the contact surface of the upper structures 2 is offset from the contact surface lower structures 3. This design provides equalization of stresses to which the joint is exposed. However, it should be noted that constructions 2, 3 can also end in the same line.

In the elastic element 1 of FIG. 4, the upper structure 2 has a greater thickness than the lower structure 3. The structures 2, 3 may also have the same thickness, or the lower structure 3 may have a greater thickness than the upper structure 2.

The elastic elements are preferably connected to each other by means of nails, screws or other similar fixing means and by means of elastic glue or paste or by means of other adhesive or elastic material, such as paste-like adhesive or paste-like adhesive sealant. The elastic material makes it possible to slightly move the elastic elements 1 relative to each other. The first support means 4, located at the contact surfaces, serve as a support for the connection of the upper and lower structures 2, 3. In addition, nails, screws, pins or other similar fastening means can be used for fastening. In this case, the elastic material, which creates the possibility of displacement of the elements relative to each other, can be located between the elastic elements 1.

Figure 5 shows a schematic side view of the connection of the elastic element according to one embodiment of the invention with another similar element. The first end of the upper and lower structures 2, 3 is made with a comb, and the opposite end with a tongue, through which the elastic elements 1, which must be connected in series, are connected by means of a tongue and groove joint 18. In tongue and groove joint 18, elastic glue or paste can be used, which create the ability to move the elastic elements 1 relative to each other. The shape and size of the tongue and groove joint 18 may differ from those shown in FIG. The first support means 4, located between the structures 2, 3, support the tongue and groove joint 18, and the support means may be part of one of the elastic elements to be connected to each other, or it may be a separate tool that is configured to serve as the tongue and groove joint connection 18 after connecting the elastic elements 1 to each other.

Treated and grooved structures 2, 3 can also be applied to the stepped ends of the elastic element, shown in figure 4. On the other hand, the simple connection of FIG. 5 can be made without ridges and dowels, while the straight (even) or appropriately beveled ends of the structures 2, 3 are connected to the corresponding ends of the second elastic element 1 in a known manner using an elastic material or without elastic material. Another possibility of connecting the elastic elements 1 to each other is to connect them by means of support means 4, 5: the support means is placed between the ends of the first and second structures 2, 3 of the elastic elements 1 connected end-to-end. After that, the support means is attached to both elastic elements, for example, using screws or nails, without connecting structures 2, 3 of various elastic elements directly to each other.

6 is a schematic side view of one embodiment of an element according to the invention. The elastic element 1 contains the upper structure 2, the lower structure 3, the first support means 4 and the second support means 5, which are made with each other as a whole, that is, they all form one part made of the same material. In this regard, the elastic element 1 of FIG. 6 differs from the above-described elastic elements in which these components are manufactured separately and subsequently assembled with glue, nails or screws to form an elastic element. The integral elastic element 1 of FIG. 6 can be quickly made, for example, of plywood, the layers of which are in a vertical position when the elastic element is installed on the floor.

The combination can also be carried out partially, so that some of the main components of the elastic elements, that is, structures 2, 3 or supporting elements 4, 5, will be integrated into one, and some will be attached to this integrated whole by using known methods of fastening.

Figure 7 shows a schematic top view of a suspended floor made by the method according to the invention, and the view is made with a partial opening of the inner part of the floor. The room 20 is made with a suspended floor covered with parquet so that the first structures 22a of the elastic elements formed from the elastic elements are installed in the direction of the walls in the areas adjacent to the walls. There is a small gap between the wall and the first structures 22a of the elastic elements, so that the movement of the elastic element during springing will not cause sounds arising from friction. Most of the resilient elements are in the second resilient structures 22b, which are located at an angle of 45 degrees with respect to the main directions of the floor and with respect to the direction of the parquet boards 21, which are used as the surface material. Due to the angle at which the elastic elements are located, the load that the floor is exposed to is distributed evenly. The elastic elements 1 are connected in series or cut to the appropriate size if necessary. The edges of the surface layer rest at all points, and the elasticity of the floor is the same also near the wall. Zones in front of doors and other similar zones can be made with the same rigidity.

For a person skilled in the art it is obvious that as the technology improves, the basic idea of the invention can be implemented in many different ways. Thus, the invention and its embodiments are not limited to the examples described above, but they can vary within the scope of the claims.

Claims (11)

1. An elastic element for a suspended floor, wherein said element is to be placed under the surface layer (7) of the floor and provides the possibility of springing of the surface layer (7) when subjected to loading, while the elastic element (1) forms an installation element, the length of which significantly exceeds it width, wherein the element comprises an upper structure (2) and a lower structure (3), the structures being elastic, at least to some extent parallel to each other and substantially horizontal and arranged above the other in the installed elastic element (1), the first supporting means (4) located between the upper structure (2) and the lower structure (3) at a first distance (D1) from each other in the longitudinal direction of the elastic element (1), the first supporting means (4) ensure the placement of the upper structure (2) and the lower structure (3) at a first distance (H1) from each other in the direction of height, the second supporting means (5) located on the opposite side of the lower structure (3) with respect to to the first support elements (4) and the second race melting (D2) from each other in the longitudinal direction of the elastic element (1), the second supporting means (5) having a height for placing the lower structure (3) at a second distance (H2) in the height direction from the structure located under the specified structure, moreover, the first support means (4) are located in the longitudinal direction of the elastic element (1) in places in the specified elastic element, essentially different from the locations of the second support means (5), characterized in that at one end of the upper and lower structures (2 , 3) performed a tongue and groove at the opposite end, and the tongue and tongue are configured to connect the elastic element (1) with their ends to another similar elastic element (1) by means of a tongue and groove joint (18). 2. An elastic element according to claim 1, characterized in that it comprises first and second support means (4, 5) arranged alternately in the longitudinal direction of the elastic element (1). 3. An elastic element according to claim 1 or 2, characterized in that the upper and lower structures (2, 3) are at least mainly made of wood material. 4. An elastic element according to claim 1, characterized in that the first and second support elements (4, 5) are made of at least mainly from essentially inelastic wood material. 5. The elastic element according to claim 1, characterized in that the first supporting elements (4) and / or second supporting elements (5) are made essentially of elastic material. 6. The elastic element according to claim 1, characterized in that the upper structure and the lower structure (2, 3) are configured to end on the same line (17a, 17b) and perpendicular to this line. 7. The elastic element according to claim 1, characterized in that the upper structure and the lower structure (2, 3) are configured to end in different lines (17a, 17b) and perpendicular to these lines. 8. The elastic element according to claim 1, characterized in that the successive elastic elements are configured to connect them to each other by means of elastic glue. 9. The elastic element according to claim 1, characterized in that at least some of its upper supporting elements (4) are made in one piece with the upper or lower structure (2, 3), and / or at least some of its lower supporting elements (5) are made in one piece with the lower structure (3). 10. A method of manufacturing a suspended floor, in which the surface layer (7) is placed on top of the elastic elements (1), and the elastic element (1) forms a mounting element, the length of which substantially exceeds its width, the element comprising an upper structure (2) and a lower structure (3), wherein the structures are elastic, at least to some extent parallel to each other and essentially horizontal and located one above the other in the installed elastic element (1), the first supporting means (4) located between the upper structure (2) and the lower structure (3) at a first distance (D1) from each other in the longitudinal direction of the elastic element (1), and the first supporting means (4) ensure the placement of the upper structure (2) and the lower structure (3) on the first distance (H1) from each other in the direction of height, the second support means (5) located on the opposite side of the lower structure (3) with respect to the first support elements (4) and at a second distance (D2) from each other in the longitudinal the direction of the elastic element (1), with the second supporting media The properties (5) have a height for placing the lower structure (3) at a second distance (H2) in the height direction from the structure located under the specified structure, the first supporting means (4) located in the longitudinal direction of the elastic element (1) at elastic element (1), essentially different from the locations of the second support means (5), characterized in that at one end of the upper and lower structures (2, 3) there is a tongue, and on the opposite end there is a tongue, and the tongue and tongue perform with the ability to connect pack the other element (1) at its ends with another similar elastic element (1) by means of a tongue-and-groove connection (18), while the elastic elements (1) are connected to each other by their ends by means of a tongue-and-groove connection (18). 11. The method according to claim 10, characterized in that the elastic elements (1) are positioned at an angle of 45 ° relative to the main directions of the floor.

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