RU135670U1 - VENTILATED FACADE OF THE BUILDING - Google Patents

Abstract

1. A ventilated building facade, including a vertical profile frame and heat-insulating and facing plates fixed to it with the formation of a ventilation cavity, characterized in that the building facade frame consists of vertical profile elements made of fiberglass or basalt plastic, with a strength of at least 800 MPa and no thermal conductivity more than 0.5 W / m ∙ K, while the vertical profile element contains stiffeners in the plane of fixation to the wall of the building, in the plane of placement of heat-insulating plates and in plane STI facing mounting plit.2. The ventilated building facade according to claim 1, characterized in that the vertical profile frame element is molded. The ventilated building facade according to claim 1, characterized in that the vertical profile frame element is collapsible with the ability to align the facing surface vertically of the building facade. The ventilated building facade according to claim 1, characterized in that the vertical profile frame elements are interconnected by horizontal fiberglass or basalt plastic joints with the formation of cells for attaching heat-insulating plates.

Description

The utility model relates to the field of industrial and civil construction, namely to the construction of ventilated facades of buildings and structures.

A facade is known in which a facade bracket having a fixed part made in the form of a vertically arranged plate with a stop and a slider mounted on the cantilever end of the fixed part with the ability to move and fix on it, while a horizontal shelf is made on the cantilever end of the fixed part of the bracket, and the slider has a horizontal shelf interacting with a horizontal shelf of the fixed part of the bracket, and a vertical shelf interacting with a vertically located plate of the fixed part bracket bracket. To adjust the total length of the bracket in the vertical shelf of the slider, a cutout was made for the bolt, fixing the slider on the cantilever end of the fixed part. The bolted connection allows you to change the length of the extension of the bracket depending on the thickness of the insulation, the curvature of the walls, (see RF patent No. 69114, CL E04B 2/00, publ. 2007)

A disadvantage of the known bracket is the complexity of its design.

Closest to the proposed analogue is a system of a hinged ventilated building facade (see RF patent No. 93835 class. E04B 2/00, publ. 2006)

The system contains cladding panels and a frame consisting of a group of modules. Each module consists of at least one supporting and one elongated supporting brackets fixed to the wall, as well as a vertical rail designed for mounting cassette-type panels. The vertical guide is installed using the supporting and supporting brackets with the possibility of movement relative to them and fixing. At the ends of the sides of the vertical rail are lower shelves made with notches and with longitudinal grooves for the seal. Mounting rails mounted in a vertical rail with the possibility of longitudinal movement in it and fixing, contain a base and sidewalls perpendicular to it, with the possibility of installing a support pin between them and installed with the possibility of longitudinal movement and fixing

A disadvantage of the known design of the ventilated facade is the complexity of the design, and it is possible to make it only of metal, which has high thermal conductivity and forms heat-conducting bridges (cold bridges), in addition, metal structures require measures to protect them from corrosion.

The technical task of the utility model is to increase the operational characteristics of the facade system, increase the strength and chemical resistance of the structural elements of the facade.

The problem is solved in such a way that in the ventilated facade of the building, including the vertical profile frame and heat-insulating and facing plates fixed to it with the formation of a ventilation cavity, according to the utility model, the building facade frame consists of vertical profile elements made of fiberglass or basalt plastic with a strength of at least 800 MPa with a thermal conductivity of not more than 0.5 W / m ² K, wherein the profile element comprises a vertical stiffener fixation in the plane of the wall of the building, etc. oskosti placement of insulation boards and in the plane of fastening of facing plates. Moreover, the vertical profile element of the frame can be cast, or collapsible with the possibility of alignment of the facing surface vertically of the facade of the building. In addition, the vertical profile frame elements can be interconnected by horizontal ties made of fiberglass or basalt plastic with the formation of cells for attaching heat-insulating plates.

The proposed design of the ventilated facade differs from the known one in that the building facade frame consists of vertical profile elements made of fiberglass or basalt plastic with a strength of at least 800 MPa and a thermal conductivity of not more than 0.5 W / m ² K, while the vertical profile element contains stiffeners in the plane of fixation to the wall of the building, in the plane of placement of heat-insulating plates and in the plane of fastening of facing plates.

The technical result consists in simplifying the fastening of heat-insulating and facing plates and increasing the operational properties of the structure, the strength of the structural elements of the facade, reducing the heat loss of the building through the external walls due to the low coefficient of thermal conductivity of the components of the facade, eliminating cold bridges and, accordingly, optimizing steam exchange through the external walls of the building, increasing corrosion resistance facade elements.

Fiberglass profile characteristics for a ventilated facade. The tensile strength of the fiberglass profile is 800-900 MPa. The thermal conductivity coefficient of the fiberglass (basalt-plastic) profile is 0.3-0.5 W / m * K. Fiberglass (basalt-plastic) profile is resistant to moisture, acids, alkalis. The operating temperature of the fiberglass (basalt-plastic) profile is -50- + 100 ° C. The density of the fiberglass (basalt-plastic) profile is 1.8-2.0 g / cm ³ . Water absorption of a fiberglass (basalt-plastic) profile of 0.2%. Flammability of fiberglass (basalt-plastic) profile B1.

The vertical profile of the frame can be made cast, for example by pultrusion. The profile of the frame can be made collapsible to enable alignment of the facade to the height of the wall.

The frame elements can be interconnected by horizontal ties of fiberglass or basalt plastic, for example in the form of a corner, with the formation of cells for attaching heat-insulating plates to increase rigidity and simplify installation.

Figure 1 presents a vertical section of the ventilated facade of the building; figure 2 is a horizontal section of the profile of the frame; figure 3 is the same as in figure 2 an embodiment of the collapsible.

The ventilated facade of the building consists of an external wall 1, a frame profile 2 attached to it, heat-insulating plates 3, cladding plates 4. The vertical profile element has stiffening ribs to the entire height of the building in the plane of fixation to the wall of building 5, in the plane of placement of heat-insulating plates in the plane of attachment facing plates 7. Vertical profile frame elements can be interconnected by horizontal ties 8.

Installation of a ventilated facade is as follows.

The edge 5 of the vertical profile element is attached to the outer wall of the building 1 with dowels and screws, for example, they shoot the dowel with nails. The vertical profile element is mounted on the wall with a gap corresponding to the size of the facing material 4. The vertical profile element is manufactured according to TU 2296-034-13377864-2004 or others.

Starting from the bottom, adjacent vertical profile elements are connected by horizontal ties of composite material 8, which is attached to the rib 6, forming a support for the heat-insulating material 3.

In the rectangular section formed by the horizontal bond and adjacent vertical profile elements, a sheet of heat-insulating material (mineral wool plates TU 5762-003-08621635-98, etc.) is inserted with a thickness equal to the distance between the ribs 5 and 6. From above, the heat-insulating material is sealed with the following horizontal bond and so on to the top of the facade.

The facing material 4 according to TU 5772-001-77732794-2006 or others is fastened with screws to the ribs 7 of the vertical profile element.

To align the facade vertically, you can use a collapsible vertical profile (see figure 3). The ribs 6 are moved relative to the ribs 5 and, after alignment, are screwed to the vertical profile element.

Claims (4)

1. A ventilated building facade, including a vertical profile frame and heat-insulating and facing plates fixed to it with the formation of a ventilation cavity, characterized in that the building facade frame consists of vertical profile elements made of fiberglass or basalt plastic, with a strength of at least 800 MPa and no thermal conductivity more than 0.5 W / m ∙ K, while the vertical profile element contains stiffeners in the plane of fixation to the wall of the building, in the plane of placement of heat-insulating plates and in plane STI fixing of tiles. 2. The ventilated facade of the building according to claim 1, characterized in that the vertical profile frame element is molded. 3. The ventilated building facade according to claim 1, characterized in that the vertical profile frame element is collapsible with the ability to align the facing surface vertically of the building facade. 4. The ventilated facade of the building according to claim 1, characterized in that the vertical profile frame elements are interconnected by horizontal ties of fiberglass or basalt plastic with the formation of cells for attaching heat-insulating plates.

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