RU157001U1 - WALL MULTI-LAYER DESIGN - Google Patents

Abstract

1. Wall multilayer construction, characterized in that it contains external and internal cladding, interconnected external, internal and intermediate frames, heat-insulating material located between the frames, while the external frame is a combination of vertical wooden racks, lower and upper bindings of the outer frame and horizontal struts, the inner frame is a combination of vertical wooden racks, lower and upper harnesses of the inner frame and horizontal races a defect, the intermediate frame is a connection of horizontal bars located between the vertical posts of the external and internal frames distributed in a vertical plane and placed in the space between the struts of the external frame and the struts of the internal frame, the vertical posts of the external and internal frames are installed with an offset in the horizontal plane relative to each other each other and are located at an equidistant distance along the axis of the wall structure, the upper strapping of the vertical posts the outer and inner frames are offset relative to each other in a vertical plane, the struts of the inner frame are also offset in a vertical plane relative to the struts of the outer frame. 2. The wall structure according to claim 1, characterized in that the wall multilayer structure further comprises a vapor barrier material located between the inner skin and the inner frame of the structure, a hydro-windproof membrane located between the outer skin and the outer frame, a vertical counter bar, located

Description

The utility model relates to the field of construction, in particular to external and internal multi-layer wall structures for rapidly reproducible energy-efficient buildings with a wooden frame in low-rise construction.

Low-rise construction is a way to increase the pace of construction of residential real estate, increase the affordability of housing for the general population at a lower cost per square meter compared to multi-storey buildings, and at the same time ensure comfortable living conditions. For the quick erection of buildings of low-rise construction, typical wall panels are used (for example, RU 65535, 08/10/2007, RU 2342500, 12/27/2008), which contain a frame of wooden blocks, outer and inner cladding, insulation located between them. Also, structures of panels of a similar type in the lower part may contain gaps for laying electric cables and other communications (for example, JP 3733370, January 11, 2006). However, such wall panels cannot be used in the construction of buildings with several floors, since in this case the tightness of the connection of the panels to the building foundation is not ensured, the sound is poorly insulated, thereby reducing the comfort of living conditions. That is, designs can increase the pace of construction of structures, but at the same time they do not provide the necessary heat engineering properties, sound insulation, structural rigidity and fire resistance. In addition, buildings with such wall panels have low energy efficiency, which reduces their attractiveness. These panels can be used, for example, for the construction of country houses, suitable for permanent residence in the warm season.

A multilayer panel is known (RU 90820, 01/20/2010), consisting of a wooden frame, insulation and sheet sheathing, while the frame is formed by vertical and horizontal stiffeners from a solid board, the outer skin can be made of a wooden plate or metal sheet, mineral wool insulation can be used as insulation, also insulation can be flooded, that is, reinforced and fixed by means of a metal mesh in the panel body.

However, these wall panels have low thermal properties, since the corner unit when connecting the wall panels, as well as the connection of the wall panel to the foundation of the building, do not have the proper tightness with respect to air and moisture, which is especially noticeable in the cold season. In addition, in the case of using wooden plates and mineral wool insulation as the outer skin, the necessary rigidity of the frame structure is not ensured, which leads to its deformation during the operation of buildings and to a short service life. In the case of using in-fill insulation, the weight of the wall panel increases significantly, which complicates the delivery of panels to the construction site, and also does not allow the assembly of panels, if necessary, directly at the construction site. When pouring insulation in the wall structure between the frames, a metal mesh is used, which is unacceptable due to the risk of corrosion due to moisture or condensation due to the difference in temperature conditions, which also reduces the service life of the building.

Known wall panel (US 6308469, 10/30/2001), containing a frame of vertical and horizontal elements, inside which are located interconnected diagonal elements attached to the frame elements, while the lower part of the frame is connected to the foundation to stabilize the wall or floor under wall panel. This frame design allows you to increase the rigidity of the structure through the use of additional diagonal elements inside the main frame. However, the tightness of the wall structure with the angular connection of the panels remains insufficient, proper sound insulation is not ensured. In addition, in this design, the elements of the inner and outer sides of the panel, the stiffeners are interconnected, which increases the risk of rapid fire of the panel in case of fire.

Known wall panel (RU 59096, 12/10/2006), which is the closest solution to the claimed one, containing a supporting frame of wooden beams in the form of an external frame with a power element made of wood along its length and an internal frame with at least three by the strength elements of wood along its width, the outer and inner cladding of wooden plates, insulation, hydro- and vapor insulator placed between the claddings, while the protrusions for attaching to other panels are covered with a tape seal based on foamed polyethylene. This design, when connecting the outer and inner frames into a single frame, has an intermediate part formed by the vertical power element of the external frame and at least three power elements of the internal frame, which allows to increase the rigidity of the wall panel to prevent deformation of the single frame. The thermotechnical properties of the wall panel are improved due to the possibility of installing an additional insulation layer between the inner and outer cladding, as well as due to the presence of a tape seal at the junction of the panels.

However, the disadvantages of this design are the lack of tightness at the junction of the panels with the foundation, which leads to insufficient heat and technical properties and possible freezing of the floor in the building during operation in the cold season, as well as to the penetration and localization of moisture during the rainy season in the lower part of the panels, which can lead to swelling of wooden elements, rotting of the insulation in the direction from the bottom up and, as a result, to a decrease in the service life of buildings.

The technical task is to provide the ability to quickly erect low-rise buildings, increase their energy efficiency and increase the operating life.

The technical result is to improve the thermal properties, increase spatial rigidity, increase sound insulation and fire resistance.

The technical result is achieved by using a wall multilayer structure containing external and internal cladding, interconnected external, internal and intermediate frames, heat-insulating material located between the frames, while the external frame is a combination of vertical wooden posts, lower and upper strands of the external frame and horizontal struts, the inner frame is a combination of vertical wooden racks, lower and upper strands of the inner to frame and horizontal struts, the intermediate frame is a connection of horizontal bars located between the vertical posts of the external and internal frames distributed in a vertical plane and placed in the space between the struts of the external frame and the struts of the internal frame, the vertical posts of the external and internal frames are installed with an offset in the horizontal planes relative to each other and are located at an equidistant distance along the axis of the wall structure, the upper the strapping of the vertical struts of the outer and inner frames are offset relative to each other in the vertical plane, the struts of the inner frame are also offset in the vertical plane relative to the struts of the outer frame.

The implementation of the external and internal frames in the form of connections from vertical wooden racks, lower and upper bindings and horizontal struts, an intermediate frame in the form of a connection of horizontal bars located between the vertical racks of the external and internal frames distributed in a vertical plane and placed in the space between the external and external struts inner frames, prevents the deformation of the frames during loading, eliminating the risk of longitudinal bending, allows to separate the frames between themselves, uv lichit rigidity and reliability of the multilayer wall structure as a whole. The offset of the vertical struts of the outer and inner frames located at an equidistant distance along the axis of the wall structure in a horizontal plane relative to each other, the offset of the upper strands of the vertical struts of the outer and inner frames in a vertical plane relative to each other, the offset of the struts of the inner frame in the vertical plane relative to the struts of the outer frame, provide the formation of cells between the inner and outer frames for laying heat-insulating material with zero overlap of the wooden parts of the multilayer wall structure. In addition, the use of an intermediate frame creates a space between the internal and external frames, where an additional layer of thermal insulation material is laid. These structural characteristics of the claimed design can significantly improve the heat engineering and sound insulation parameters. Improving the fire resistance of the wall structure is achieved due to the lack of contact between the wooden elements of the external and internal frames, the possible use of a non-combustible heat-insulating material in this wall structure and the use of casing materials of a reduced combustibility class.

The multilayer wall structure may also include a vapor barrier material located between the inner skin and the inner frame of the structure, a hydroprotective membrane located between the outer skin and the outer frame, a vertical counter bar located between the hydroprotective membrane and the outer skin with the formation of a ventilation gap, a horizontal counter bar between the vapor barrier material and the inner lining with the formation of an air gap for laying comm unique features such as piping and / or electrical cables.

The effectiveness of a hydro-windproof membrane (for example, Tyvek, Yutavek) lies in the fact that due to the porous structure it prevents the penetration of water and air from the outside, while allowing fumes from the inner layers of the wall structure to pass through the membrane. Wall panels remain dry, which helps to extend the life of the building. In addition, these materials of hydro-windproof membranes have a reduced combustibility class, which increases the fire safety of structures.

The vapor barrier material (for example, “Utafol”, “Tyvek”, “IZOSPAN”) prevents the penetration of water vapor from the interior of the house into the heat-insulating material, which allows it to maintain its properties for a long time and also increase the service life of the building. The vapor barrier material helps maintain the tightness of the wall multilayer structure, which additionally allows you to retain heat indoors. At the same time, the material has a reduced flammability, which also allows to increase the fire safety of buildings.

Such materials as Paroc, Rockwool, Isover, Isoroc, Izovol and similar heat-insulating materials in the form of plates with a density of 25 kg / m ³ are used as heat-insulating material. These materials are used with the mandatory installation of hydro-windproof membranes, vapor barrier films and air gaps.

Also, in the production of a wall multilayer structure in the factory, ECOVATA can be used as a heat-insulating material. In this case, installation of a hydro-wind-proof membrane and vapor-proof material is not required.

The inventive wall multilayer structure is illustrated by the following figures.

FIG. 1 is a general view, partly in section, of an element of a wall multilayer structure mounted on a foundation.

FIG. 2 represents two views of a vertical section of a wall multilayer structure (FIG. 2a and FIG. 2b) and a horizontal section AA of an element of a wall multilayer structure (FIG. 2c). The view of FIG. 2a illustrates the use of a wall multilayer structure with a strip foundation and wooden floor, the view in FIG. 2b - with a monolithic overlap or a monolithic slab.

FIG. 3 is a horizontal section of a portion of a wall multilayer structure comprising angular joints of wall structures and window opening elements, as well as a vertical section of wall BB in the region of the window opening.

FIG. 4 represents four views: FIG. 4a is a vertical sectional view of a panel with a wooden overlap, FIG. 4b is a vertical section of a panel with an embodiment on a monolithic plate, FIG. 4c is a horizontal section of the panel BB, FIG. 4g is a horizontal section of a universal warm corner element used in the installation of these panels, and which can be used both external and internal angle.

FIG. 5 is a general view of a wall multilayer structure from two sides.

FIG. 6 is a horizontal sectional view of a portion of a wall multilayer structure as the width of the wall structure changes.

The multilayer wall structure shown in FIG. 1 includes an inner frame 1, an outer frame 2, an intermediate frame 3, a lower frame of an inner frame 4, an upper frame of an inner frame 5, a lower frame of an external frame 6, an upper frame of an external frame 7, a heat-insulating material 8, a water-proof membrane 9, a vertical counter bar 10, forming a ventilation gap 11 (Fig. 2), the outer casing 12, vapor barrier material 13, a horizontal counter bar 14, defining an air gap 15 (Fig. 2) for laying communications, the inner casing 16.

The outer skin 12 may be, for example, OSB boards, material with imitation timber, lining or other sheet material intended for the outer skin of buildings.

The inner lining 16 may be, for example, GSP, OSB, GVL, GKL or other finishing material.

The external frame 2 is a connection of vertical wooden racks 17, lower 6 and upper 7 strapping, as well as horizontal struts 18. The internal frame is a connection of vertical wooden racks 19, lower 4 and upper 5 strapping, as well as horizontal struts 20. External 2 and the inner 1 frames are installed with an offset in the horizontal plane relative to each other and are located at an equidistant distance along the axis of the wall structure. The distance between the uprights 17 and 19 is designed for sheathing with sheet material from the outer and inner sides of the wall structure. Spacers 18 and 20 support the vertical struts of the outer and inner frames 17 and 19 and prevent their deformation during loading, eliminating the risk of longitudinal bending.

The intermediate frame 3 is a connection of horizontal bars that are located between the uprights of the outer frame 17 and the inner frame 19, are distributed among themselves in a vertical plane and are placed in the space between the struts of the outer frame 18 and the struts of the inner frame 20, as shown in the drawing in FIG. 2.

The structures of the outer 2 and inner 1 frames are not in contact with this. The upper beam of the intermediate frame 3 is rigidly bonded to the upper strands of the outer 7 and inner 5 of the frame using a nail connection or other similar method. All other bars of the intermediate frame are rigidly bonded to the uprights of the external 17 and internal 19 of the frame using a nail connection or other similar method. Thus, a rigid spatial framework is formed.

In the intermediate frame 3, horizontal laying of the heat-insulating material 8 is provided. In the cells of the outer and inner frames, the heat-insulating material 8 is stacked vertically. Since the structures of the outer 2 and inner 1 frames do not touch each other, the heat-insulating material 8 overlaps all the wooden elements of the spatial frame. As a result, freezing is eliminated and heat losses occurring due to different thermal conductivity of the materials used are reduced. With a significant difference in internal and external temperatures, the possibility of condensation is excluded, which can significantly increase energy efficiency and increase the service life of the materials used, as well as the entire building. In addition, the laying of the heat-insulating material 8 in the cells formed between the frames 1 and 2, virtually eliminates the possible shrinkage of the heat-insulating material 8 during the long-term operation of the building, which preserves the energy efficiency of the wall multilayer structure throughout the life of the building.

All frame elements 1, 2, and 3 are attached to each other using a nail or similar method. When assembling elements of a wall multilayer structure, metal connecting elements (for example, mounting angles) are not used, which to some extent reduces the cost of consumables. In addition, the use of only wooden elements in the wall structure allows you to use it with a significant difference in temperature conditions without the risk of condensation on the metal connecting elements, which, in turn, allows you to increase the life of the building.

The outer 2 and inner 1 frames can be equipped with vertically and horizontally oriented counter bars 10 and 14. The bars 10 and 14 are attached to the vertical posts 17, 19 and horizontally spaced bars 18, 20 using a nail connection or other similar method, and act as supports for installing the outer 12 and inner lining 16 of the wall multilayer structure at a distance of the air gap from the heat-insulating material 8.

On the outside of the wall multilayer structure, the fastening of a vertically arranged counter bar forms a ventilation gap 10 between the windproof hydro-membrane 9 and the outer skin 12, which helps to remove moisture from the heat-insulating material 8, which may have formed during the operation of the building. On the inner side of the wall multilayer structure, the fastening of a horizontally arranged counter bar 14 forms an air gap 15 between the vapor barrier material 13 and the inner casing 16, which can be used for concealed laying of communications 21, for example pipelines and / or electric cables. In addition, it becomes possible to install sanitary faucets, mounting boxes for socket groups and switches on the external walling without violating the vapor barrier.

The absence of contact between the wooden elements of the outer 2 and inner 1 frames, the use of non-combustible heat-insulating material 8 in this wall multilayer structure, as well as materials for the outer 12 and inner 16 cladding of a reduced combustibility class, can significantly increase the fire resistance of walls in buildings with a wooden frame.

Another advantage is the use of this wall multilayer structure with different types of foundations and basement, as illustrated by the drawings in FIG. 2a (strip foundation with wood flooring) and FIG. 2b (monolithic plate).

According to FIG. 2a, the lower strapping of the outer frame 6 and the lower strapping of the inner frame 4 can be offset from one another in a vertical plane. The lower strapping of the inner frame 4 is located on the ceiling 22, and the lower strapping of the outer frame 6 can be located on the support board 23, which in turn is rigidly attached through the waterproofing layer to the foundation 24 with an anchor or similar method. This eliminates the problem of freezing of the lower harnesses in the basement overlap area.

According to FIG. 2b, the outer and inner frames have a common lower strapping 25, which, when mounting the wall multilayer structure, is rigidly attached to the foundation 24 through the waterproofing layer with an anchor or similar method.

One of the main advantages of a wall multilayer structure is the elimination of freezing in the area of interfloor or attic due to the fact that when erecting superior wall structures, the lower trim of the inner frame 4 is located on the interfloor or attic floor, and the lower trim of the outer frame 6 is located on the upper trim of the lower wall multilayer construction. In this case, the overlap is supported by the upper strands of the inner frame of the subordinate wall structure and is blocked by the heat-insulating material 8 of the outer frame. This eliminates the freezing of harnesses in the area of interfloor or attic floors.

An advantage of this wall construction is also that the elements of the corner assembly 26 (Fig. 3) of the wall connection of the multilayer structures are arranged in such a way that freezing in the corner joints is prevented when laying the heat-insulating material 8. Thus, an energy-efficient node of the corner element is obtained, which, unlike the classical corner node, does not freeze completely at the junction of the frame racks with each other.

The vertical elements of the window assembly 27 and the assembly 28 (Fig. 3) of the window lintel form a window quarter, which is not unimportant when installing PVC window blocks in compliance with the rules and recommendations for installing window structures. This allows you to minimize heat loss in window openings.

The advantage of the proposed wall multilayer structure is that when erecting buildings in different climatic zones from -50 ° to + 50 °, the width of the structure can change in accordance with the requirements for the thermal conductivity of building envelopes in this region by increasing the cross-section of the beam of the outer and inner frames individually , and in combination, as illustrated by the drawings shown in FIG. 6.

The proposed wall multilayer structure can be pre-assembled at the plant for the production of elements in the form of modules from wall multilayer structures or individual wall multilayer structures, which are as a multiple of the sheet material used, which is illustrated by the drawings in FIG. 4 and FIG. 5. Also, this wall multilayer construction can be easily assembled on a construction site without the use of any additional equipment and special equipment.

In FIG. 6 shows views of a horizontal section of a section of a wall multilayer structure with a change in the width of the wall structure. The designation of the elements is similar to that introduced in FIG. 2c.

The method of assembling a wall multilayer structure directly at the construction site is as follows:

Initially, the building frame is erected, including the external frame 2, the intermediate frame 3 and the internal frame 1. The wall structure can be assembled from individual elements both in a horizontal position and then installed in the design position, as well as from individual elements and units made in advance, in a vertical position. All elements and nodes of the frames 1, 2 and 3 are fastened together using a nail connection or a similar method.

Already on the existing foundation 25 and attached to it an antiseptic support board 23, the overlap 22 is mounted (figure 2). On the supporting board 23 and on the overlap 22, the lower bindings of the outer 6 and inner 4 frames are mounted; angular elements 26 are mounted vertically and fixed (Fig. 3); are installed vertically and fixed nodes that form the window 27 and doorways (not specified); are installed vertically and fixed the nodes of the connection of external walls with internal partitions (if any); installation of the upper strapping 7 of the outer frame and the upper strapping 5 of the inner frame, which can be performed as an assembly with the element 3 of the intermediate frame, as well as individual elements to facilitate installation; mounted vertically and fixed racks 19 of the inner frame; spacers 20 are mounted and fixed; the elements 3 of the intermediate frame are mounted and fixed to the posts 19 of the inner frame; mounted vertically and fixed racks 17 of the outer frame; spacers are mounted and fixed 18.

To ensure reliable connection of wall structures to each other in corner joints and at junctions of internal partitions, an additional strapping of the external 29 and internal 30 frames is installed, with 31 overlapping joints of the lower upper strapping 7 of the external and 5 internal frames being installed, which is illustrated by the image in FIG. 1, as well as, frames of internal partitions.

Next is the installation of the floor; the rafter system is installed and the roofing material is laid. If necessary, the construction of subsequent floors, the installation of frame elements is carried out in the above sequence.

The next step is the installation of heat-insulating material 8 of the intermediate frame 3, installed in the spacer between the bars of the intermediate frame 3; the heat-insulating material of the outer frame 8 is installed in the cells of the outer frame 2 in the strut between the posts 17 and the struts 18; installation of a hydro-windproof membrane 9; to the uprights 17 and spacers 18 of the outer frame 2 using a nail connection or in a similar way, a vertical counter bar 10 can be attached; mounted and fixed, using a nail connection or in a similar way, the outer skin 12; the heat-insulating material 8 of the inner frame 1 is installed in the cells of the inner frame 1 in the strut between the struts 19 and the struts 20; installation of vapor barrier material 13 with mandatory sizing at the joints of the vapor barrier material 13, as well as along the border with window and door openings; to the uprights 19 and struts 20 of the inner frame 1, a horizontal counter bar 14 can be attached using a nail connection or a similar method; communications 21 may be mounted in the resulting air gap 15; mounted and fixed using a nail connection or in a similar way, the inner lining 16.

The assembly of wall panels in production is as follows:

The frame is assembled, heat-insulating material is laid, a hydro-wind-proof membrane and vapor-insulating material are mounted, lining is made on the inner and outer sides of the wall multilayer panel.

In this energy-efficient wall construction, in addition to the plate heat-insulating material, the environmentally friendly filler ECOVATA can be used. The method of application of this filler is illustrated in the drawing in FIG. 4, where the vertical and horizontal sections of the structure are displayed. In this case, by eliminating materials such as a windproof membrane, a vapor barrier and counter bars, the cost of manufacturing wall structures is reduced. The assembly of wall structures can be carried out both directly at the construction site and in production conditions. Moreover, wall panels can be assembled without filling with insulating material, which significantly reduces their weight. Filling with ECOVATA insulation material is carried out directly on the construction site after the building is fully assembled, through the provided technological holes 32 located in the upper part of the structure, which is illustrated in FIG. 5.

Thus, in total, a triple energy-efficient spatial wooden frame with offset and spaced vertical and horizontal wooden ties, firmly connected to each other by nail or other means. Thermal insulation material laid in layers in the cells overlaps all the wooden elements. This eliminates heat loss and significantly reduces energy costs during house operation.

This wall construction is characterized in that at low production costs, it allows to achieve high thermal performance and increase the bearing capacity of the external walling. Thus, the energy efficiency of the building as a whole is increased, which, when used in mass in low-rise construction, will save the country's energy resources as a whole.

Claims (3)

1. Wall multilayer construction, characterized in that it contains external and internal cladding, interconnected external, internal and intermediate frames, heat-insulating material located between the frames, while the external frame is a combination of vertical wooden racks, lower and upper bindings of the outer frame and horizontal struts, the inner frame is a combination of vertical wooden racks, lower and upper harnesses of the inner frame and horizontal races a defect, the intermediate frame is a connection of horizontal bars located between the vertical posts of the external and internal frames distributed in a vertical plane and placed in the space between the struts of the external frame and the struts of the internal frame, the vertical posts of the external and internal frames are installed with an offset in the horizontal plane relative to each other each other and are located at an equidistant distance along the axis of the wall structure, the upper strapping of the vertical posts the outer and inner frames are offset relative to each other in a vertical plane, the struts of the inner frame are also offset in a vertical plane relative to the struts of the outer frame. 2. The wall structure according to claim 1, characterized in that the wall multilayer structure further comprises a vapor barrier material located between the inner skin and the inner frame of the structure, a hydroprotective membrane located between the outer skin and the outer frame, a vertical counter bar located between the hydroprotective membrane and outer casing with the formation of a ventilation gap, a horizontal counter bar located between the vapor barrier material and the inner ivkoy with the formation of the air gap for the construction of communications. 3. The wall structure according to claim 2, characterized in that the communications are pipelines and / or electric cables.

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