RU2333324C2 - Building construction system - Google Patents

Abstract

FIELD: constructional engineering.

SUBSTANCE: invention refers to constructional engineering, in particular to building construction systems. The walled building construction system is formed by panel components. Panel components are made of material containing fibrous vegetable breakage, the latter being sawdust or wood chips. Panel components are grooved on one surface for bearing structure frame. Walls either consist of prefabricated non-load-bearing wall elements or are assemblied thereof. Non-load-bearing wall elements contain panel components. Frames, rift and overhead joist of coverage are constructed in panel components grooves.

EFFECT: increased heat insulation and air diffusion in non-load-bearing wall elements.

23 cl, 7 dwg

Description

The present invention relates to a construction system for the construction of buildings with walls formed by panel elements.

When erecting buildings in which a frame is used as a supporting structure, the gaps between its racks are often filled with panel elements. Such panel elements, to ensure good thermal insulation, are provided with appropriate heat-insulating materials, however, between the panel elements and racks at the joints they are constantly and primarily as a result of the temperature cracking of the mortar connecting them together, through cracks or seams are formed through which cold air enters the room.

To eliminate this problem, EP 0838557 A2 proposed a construction system in which shaped bricks are used to fill the wooden supporting structure, while the wooden racks are closed at least from the outside with parts of adjacent shaped bricks. This prevents the formation of through seams between shaped bricks and racks. Therefore, the construction system proposed in this application is not sensitive to temperature extremes, which could lead to cracking of the mortar between the uprights and shaped bricks. This well-known building system, which uses shaped bricks, the material for the manufacture of which can mainly be raw materials from renewable sources, for example wood shavings, is particularly suitable for use as a system for individual construction with the manufacture of its elements directly at the place of construction of the building, since after the construction of the supporting structure, the gaps between its racks need only be filled with shaped bricks. However, such a known building system is not suitable for industrial pre-fabrication of its components.

Based on the foregoing, the present invention was based on the task of proposing a building system that would allow the pre-industrial production of wall elements that would not allow cold air into the room and for the manufacture of which could be used environmentally friendly and not diffusing air through it ("breathable") material.

This problem with respect to a building system for erecting buildings with walls formed by panel elements is solved according to the invention due to the fact that the panel elements are made of a material containing crushed fiber material, primarily sawdust or wood shavings, and have recesses under the supports of the supporting structure . Until now, fibrous plant material, due to its large shrinkage, has been used in the manufacture of only formwork or solid bricks. However, when creating the invention, it was unexpectedly found that using this material it is also possible to produce very large panels and modules. The implementation of pre-manufactured on an industrial scale panel elements of the recesses for racks completely eliminates the possibility of formation between the panel elements and racks passing through the wall from its outer side to the inner seams. When assembling the wall from several panel elements, the edges of the panel elements joined together are rounded with teeth, which eliminates the possibility of the formation of through seams between the outer and inner sides of the building and in these places. The implementation of the panel elements from a material containing mainly crushed plant fiber material allows you to create an environmentally friendly building system, the material for the manufacture of elements of which is raw materials from environmentally renewable sources. In addition, panel elements allow the possibility of their complete disposal. The solution proposed in the invention allows the wall to be completely "breathable", which contributes to the creation of a healthy microclimate in the living room. A similar material already known for its use for the manufacture of shaped bricks has, in addition, an extremely low coefficient of thermal conductivity, and therefore, without the use of additional thermal insulation materials, it can be used for the construction of houses that require minimal energy consumption for their heating. The use in addition to this of wood racks, primarily of glued wood, and panel elements mainly of wood shavings allows you to get a wall with a structure completely made of the same material, namely: wood.

Recesses for racks can be performed in one or both surfaces of the panel elements. When performing such recesses under the racks on both sides of the panel element, they can be staggered. Such a location of the recesses allows, if necessary, to reduce the interval between the racks and place them relatively close to each other, without spending too much expensive wood on the manufacture of too thick racks.

Particular advantages are achieved when closing the walls on the side of those surfaces on which there are recesses under the racks, covering panels made of one with panel elements or another material. In this case, seamless smooth surfaces form on the outer sides of the panel elements, allowing for easy subsequent processing, for example, by applying a base under the plaster. Closing panels may have a thickness equal to the distance between the bottom of the recesses and the opposite surface of the panel elements. With such a thickness of the cover panels, the racks are located in the middle of the wall thickness, which is preferable both from the point of view of stabilizing the entire structure and from the point of view of manufacturability of the manufacture of wall elements.

Another possibility of obtaining walls with uprights removed inside them and with surfaces smooth on the outside is the formation of walls arranged in pairs opposite each other by panel elements, in which the recesses for the uprights are located opposite each other and form a common cavity. The advantage associated with such a design of the wall is that, with the exception of the panel elements, it does not require any additional elements to be manufactured, for example, thinner cover panels.

In both of the above options, in one of which the wall panels are used with cover panels, and in the other - panel elements arranged in pairs opposite each other, the wall thickness and its thermal conductivity can be adjusted by leaving between the cover panels and panel elements, respectively between both panel elements, air gap.

The wall structure proposed in the invention, which can be used for the construction of both external and internal walls, allows any further processing of their surfaces. In a preferred embodiment, the walls can be provided on one side or on both sides with plaster or gypsum panels.

The frame racks are preferably made of wood. However, racks can be made from other materials. So, in particular, for the construction of higher buildings, racks can also be made of concrete, steel or composite material.

For the possibility of economical construction of prefabricated houses using the construction system proposed in the invention, the walls are preferably constructed from prefabricated wall elements or can be assembled from them. For this, it is possible to prefabricate wall elements consisting of panel elements, racks, a threshold and an upper supporting beam of overlap. Wall elements can also be provided with cover panels made of one with the panel elements or another material, and in this way ensure that they have a smooth surface on both sides. Covering panels during their manufacture from one with the panel elements of the material may have the same or different density from them. In this case, it is possible to adjust the thermal conductivity of the wall and adjust it to the desired value. With an increase in the degree of prefabrication, the wall elements can still be sheathed on the one side of them or on both sides with plaster or gypsum panels or provided with a plaster system.

The method of manufacturing prefabricated wall elements according to the invention for the construction system proposed in the invention is characterized in that racks are placed and fixed in the recesses provided for the racks in the panel elements, and the upper supporting beam of the floor and the threshold are fixed on the upper and lower edges of the panel elements, respectively. The panel elements may be shaped panels with recesses already formed therein. Another possibility is to make recesses under the stands, for example, by milling in solid panels made using crushed plant fiber material. This option is preferably used primarily when making panel elements from materials that give great shrinkage during the manufacture of panel elements from them, since it is only difficult to obtain recesses with dimensions exactly matching the necessary ones directly in the process of forming panel elements. In the manufacture of panel elements, they can also immediately carry out installation channels for laying water pipes and water fittings and electrical wiring in them.

For the manufacture of wall elements with racks closed on the outside, on the recessed surfaces of the panel elements, cover panels made of one with panel elements or another material and / or gypsum or plaster panels can be applied and fixed at least on the racks, for example, with nails and / or glue.

For the manufacture of wall elements with panel elements in pairs opposite each other, racks protruding above the surface of the panel elements can be placed in their recesses and then a second panel element with recesses is inserted into which a part of the racks protruding above the surface of the first panel elements is recessed. In this case, as well as when the cover panels are applied to the panel element, an air gap can be left between the two panel elements, respectively, between the panel element and the closing panels. In the simplest case, for the formation of such an air gap using racks with a thickness that is the required width of the air gap exceeds the depth of the recesses.

Wall elements are preferably made in a horizontal position. After the covering panels, stucco or gypsum panels or second panel elements are applied to the first panel element with the uprights already placed in its recesses, these superimposed elements can be fastened with nails to the uprights, then the upper supporting beam and the threshold can be installed and fastened with nails to fasten them with racks and panel elements, then turn the wall element over and fasten the first panel element from the outside with the racks with nails. Such a technology allows the production of a completely prefabricated wall element in an economical way by performing a relatively small number of work operations.

Panel elements and cover panels can immediately be made to the desired shape. However, they can also be assembled from shaped bricks, which are prefabricated elements.

In the manufacture of concrete racks, the recesses in the panel elements can be supplied with formwork and then poured with concrete. Recesses for racks can also be pre-placed in the recesses. If it is necessary to further increase the degree of pre-fabrication of wall elements, they can be provided on one side or on both sides with a sheathing of dry building material or a plaster system.

Below are described in more detail some embodiments of the walls in the proposed invention, the construction system and embodiments of the method of their manufacture with reference to the accompanying drawings, which show:

figure 1 - the first embodiment of the proposed invention, the wall shown in section,

figure 2 is a second embodiment of the proposed invention, the wall shown in section,

figure 3 is a third embodiment of the proposed invention, the wall shown in section,

figure 4 is a fourth embodiment of the proposed invention, the wall shown in section,

on figa-5d is a diagram illustrating the sequence of manufacturing shown in figure 2 of the wall in the form of a prefabricated wall element,

on figa-6B - views in plan, side and in section of the wall element manufactured by the method illustrated in figure 5 before applying the cover panel to it and

on figa and 7b are fragments of depicted in the context of the panel elements with racks connected to them with a geometric circuit.

The wall 10 shown in FIG. 1, which may be primarily the exterior wall of a building, is formed by a panel element 11 made of a material that contains predominantly plant fiber material. The panel element 11 can be made, for example, of wood concrete, i.e. from a mixture of wood sawdust and cement. However, instead of wood chips, cannabis fire, bamboo, coconut shells and other similar materials can also be used as a filler. The panel element 11 has recesses 12 for the racks 13. In a preferred embodiment, such recesses 12 can be made on the surface of the panel element 11 facing the inside of the building. In this case, the racks 13, when they are made of wood, are effectively protected from the weather. From the outside, the wall 10 can be covered with a layer of plaster not shown in the drawing, and from the inside by plaster or gypsum panels for possible subsequent final plastering, respectively, for a possible subsequent painting of the wall.

The wall 20 shown in FIG. 2 is also formed by a panel element 21, which is thinner than the panel element 11 shown in FIG. 1, and otherwise has a similar design. On one of the outer surfaces of this panel element 21, and in this embodiment, recesses 22 are provided under the racks 23. However, in this case, the racks 23 are closed externally by an element installed outside the panel element in the form of a cover panel 24. Unlike the wall 10, the wall 20 has both sides seamless smooth surface, which subsequently can immediately be subjected to further processing. At the wall 20, the thickness of the cover panel 24 is exactly equal to the distance between the bottom of the recesses 22 and the opposite side 21.1 of the panel element 21, and therefore, the posts 23 are located exactly in the middle of the thickness of the wall 20. However, such a wall is not strictly necessary.

Figure 3 shows another embodiment of the wall 30 with smooth seamless surfaces on both sides of it. In this embodiment, the wall is formed by two panel elements 31, 31 ′ arranged in pairs opposite one another. Both panel elements 31, 31 ′ have recesses 32, 32 ′. When both panel elements 31, 31 ′ are attached to each other, the recesses 32, 32 ′ are combined in them and form a common cavity under the stand 33, especially under the stand made of glued wood. The racks 33 shown in FIG. 3 are larger in cross section than the racks 13, 23 recessed into the recesses of the walls 10, 20 shown in FIGS. 1 and 2, respectively. A similar embodiment of the racks 33 of greater thickness allows them to be arranged at larger intervals than the racks 13 and 23. However, in principle, the racks 33 can have the same dimensions in cross section as the racks 13 and 23. In this case, the recesses 32, 32 ′ in the panel elements 31, 31 ′ can be suitably made smaller. The dimensions of the uprights 33 and the recesses 32, 32 ′ can be further coordinated with each other so that there is an air gap 34 between both panel elements 31, 31 ′, which positively affects the heat-insulating properties of the wall 30. The same air gap can equally be provided for in the wall 20 shown in FIG. 2 between the panel element 21 and the cover panel 24. The advantage of the wall 30 over the wall 20 is that it is constructed from the same panel elements 31, 31 ′. For the construction of the wall 20, it is required to use two different elements, namely: the panel element 21 and the cover panel 24. On the other hand, in the cover panel 24 of the wall 20 there is no need to provide recesses under the posts 23, the implementation of which is associated with corresponding costs.

Unlike walls 10, 20, 30, which can be used primarily as external walls, wall 40 of the structure shown in FIG. 4 is mainly suitable for use as an internal wall. Such a wall is formed by a panel element 41, which has recesses 42 under the racks 43 on both sides thereof. In this case, the recesses 42 are staggered, i.e. each recess located on one side of the panel element is located opposite the gap between two recesses located on the other side of the panel element. Such a location of the recesses allows the use of relatively thin racks 43 and to position them relatively close to each other, respectively, at short intervals to allow them to be fastened to the front of relatively narrow gypsum or plaster panels.

FIG. 5 illustrates one possible embodiment of a method of manufacturing the wall 20 shown in FIG. 2 as a prefabricated wall element. In a completely similar way, in principle, it is possible to produce the element forming the wall 30 shown in FIG. 3, provided that instead of the cover panel 24, in this case, a second panel element 31 ′ is mounted. Fig. 5a shows a one-piece panel 50 made predominantly of fibrous plant material. From this panel 50, by making recesses 22 therein, a panel element 21 is obtained. For this, the panel 50 is fixed to the desktop 51, which is shown in FIG. After that, the panel can be processed, for example, with a milling cutter. Panel 50 can also cut window openings. Waste generated in this process allows the possibility of their complete disposal.

After making the recesses 22, as well as the recesses not shown in the drawing, for the upper supporting beam of the floor and the threshold, the racks 23 are placed in the recesses 22, and the upper supporting beam of the floor and the threshold are placed in the recesses provided for them, clamped together with the racks 23 and knocked down with nails. Then, a cover panel 24 is applied to the panel element 21 and fastened to the posts 23, the upper supporting beam of the floor and the threshold with nails 52 and / or glue. After that, the entire structure is turned through 180 °, as a result of which the cover panel 24 is on the working table 51. Finally, the panel element 21 can be connected to the posts 23, also using nails 52.

The cover panel 24 may be made of one material panel 50. At the same time, the cover panel can also be made of another material, for example, a material with a lower coefficient of thermal conductivity.

FIGS. 6a-6c show a wall element 60 made in the manner illustrated in FIG. 5 at a stage before the covering panel is applied to it. This wall element 60 has a doorway 66, which is similar to the recesses for the uprights 63, the upper supporting beam 64 of the floor and the threshold 65 can be made in the whole panel, from which the panel element 61 is made. Above the doorway 66 there is a door jumper 67, under which in the panel element 61 is also provided with a recess. The embedment of the upper supporting beam 64 of the overlap and the threshold 65 into the material of the panel element 61 is most clearly visible primarily in FIG. 6c, where this panel element is shown in longitudinal section. Racks 63 are sandwiched between the upper supporting beam 64 overlap and the threshold 65 and are fastened with nails.

On figa and 7b shows two examples of the cross section of the uprights 71 and 72, which due to their similar profile can be connected to the panel element 70 with a geometric closure. The stand 71 shown in FIG. 7a has a trapezoidal cross-section, and the stand 72 shown in FIG. 7b has an I-profile.

Claims (23)

1. A construction system for the construction of buildings with walls (10, 20, 30, 40, 60) formed by panel elements (11, 21, 31, 31 ′, 41, 61, 70), characterized in that the panel elements (11, 21, 31, 31 ′, 41, 61, 70) are made of a material containing crushed fibrous plant material, primarily sawdust or wood shavings, and have recesses on one of their surfaces (12, 22, 32, 32 ′, 42 ) under the racks (13, 23, 33, 43, 63, 71, 72) of the supporting structure, and the walls (10, 20, 30, 40) consist of prefabricated wall elements or are made with the possibility of assembly of them, and the wall elements contain panel elements (11, 21, 31, 31 ′, 41, 61), racks (13, 23, 33, 43, 63), a threshold (65) and an upper supporting beam (64) of the ceiling, which are placed in the recesses of the panel elements (11, 21, 31, 31 ′, 41, 61). 2. The construction system according to claim 1, characterized in that the panel elements (11, 21, 31, 31 ′, 41, 61, 70) have recesses (12, 22, 32, 32 ′, 42) under the racks (13, 23, 33, 43, 63, 71, 72) from the inside and outside. 3. The construction system according to claim 2, characterized in that the recesses (42) under the racks are staggered from the inside and outside. 4. The construction system according to one of claims 1 to 3, characterized in that the walls (20) from the side of those surfaces on which recesses (22) are provided under the posts (23) are closed with cover panels (24) made of one with panel elements (21) or other material. 5. The construction system according to claim 4, characterized in that the closing panels (24) have a thickness that is equal to the distance between the bottom of the recesses (22) and the surface (21.1) of the panel elements (21) located opposite them. 6. The construction system according to one of claims 1 to 3, characterized in that the walls (30) are formed by panel elements (31, 31 ′) arranged in pairs opposite each other, in which recesses (32, 32 ′) under the racks (33) are located against each other and form a common cavity. 7. The construction system according to claim 4, characterized in that there is an air gap (34) between the panel elements (21) and the closing panels (24) or between the panel elements (31, 31 ′) arranged in pairs opposite each other. 8. The construction system according to one of claims 1 to 3, characterized in that the walls (10, 20, 30, 40) on one side or on both sides are provided with plaster or gypsum panels (44). 9. The construction system according to one of claims 1 to 3, characterized in that the racks (13, 23, 33, 43, 63, 71, 72) are made of wood, primarily of glued wood. 10. The construction system according to one of claims 1 to 3, characterized in that the racks (13, 23, 33, 43, 63, 71, 72) are made of concrete, steel or composite material. 11. The building system according to claim 1, characterized in that the wall elements (20) contain cover panels (24) made of one with the panel elements (21) of a material with the same or different density. 12. The construction system according to claim 1, characterized in that the wall elements (10, 20, 30, 40, 60) are sheathed on one side or on both sides with plaster or gypsum panels (44). 13. The building system according to claim 1, characterized in that the wall elements (10, 20, 30, 40, 60) are provided on one side or on both sides with a plaster system. 14. The construction system according to claim 1, characterized in that the wall elements (10, 20, 30, 40, 60) are equipped with mounting channels for laying water pipes and water fittings and electrical wiring in them. 15. The construction system according to claim 1, characterized in that the racks (71, 72) are connected to the panel elements (70) with a geometric circuit. 16. A method of manufacturing prefabricated wall elements (10, 20, 30, 40, 60) for a building system according to one of claims 1 to 15, characterized in that the racks (13, 23, 33, 43, 63, 71, 72 ), the upper supporting beam (64) of the overlap and the threshold (65) are placed in the recesses provided under them (12, 22, 32, 32 ′, 42) in the panel elements (11, 21, 31, 31 ′, 41, 61, 70 ) and fixed in these recesses, moreover, the recesses (12, 22, 32, 32 ′, 42) under the racks (13, 23, 33, 43, 63, 71, 72), under the upper supporting beam (64) of the ceiling and under the threshold (65) perform in whole, made using crushed plant material panels (50). 17. The method according to p. 16, characterized in that on the having recesses (12, 22, 32, 32 ′, 42) the surface of the panel elements (11, 21, 31, 31 ′, 41, 61) impose cover panels (24) made of one with panel elements (21) or another material, and / or plaster or gypsum panels (44) and fasten them at least on racks (13, 23, 33, 43, 63, 71, 72). 18. The method according to p. 16 or 17, characterized in that the racks (33) protruding above the surface of the panel elements (31) are placed in their recesses (32) and then a second panel element (31 ′) with recesses is applied ( 32 ′) into which a portion of the uprights (33) protruding above the surface of the first panel elements (31) is sunk. 19. The method according to 17, characterized in that the closing panel (24) or the second panel elements (31 ′) are applied to the panel elements (21, 31) with the formation of an air gap (34). 20. The method according to 17, characterized in that after applying the cover panels (24), plaster or gypsum panels (44) or second panel elements (31 ′) they are fastened to the uprights (13, 23, 33, 43, 63) nails, then install the upper supporting beam (64) of the ceiling and the threshold (65) and fasten them with nails to the uprights (13, 23, 33, 43, 63) and panel elements (11, 21, 31, 41, 61), after which the wall element (10, 20, 30, 40, 60) is turned over and the first panel element (21, 31, 61) is fastened with nails to the uprights (23, 33, 63) from the outside. 21. The method according to p. 16 or 17, characterized in that the panel elements (11, 21, 31, 31 ′, 41) and / or the closing panels (24) are assembled from shaped bricks, which are prefabricated elements. 22. The method according to p. 16 or 17, characterized in that the recesses (12, 22, 32, 32 ′, 42) are provided with formwork and then poured with concrete. 23. The method according to p. 16 or 17, characterized in that the wall elements (10, 20, 30, 40) on one side or on both sides thereof are provided with a sheathing of dry building material (44) or a plaster system.

Images