RU97146U1 - Hinged Ventilated Facade with Facing Layer of Brick - Google Patents

Abstract

 1. A hinged ventilated facade, characterized in that it contains a facing layer formed by brickwork, a warming layer and a device for fastening the facing layer, consisting of horizontal supporting elements made with the possibility of fastening on intermediate vertical elements, and fixing knots, while facing the layer is located on the supporting horizontal elements, each intermediate vertical element is made with the possibility of fastening to the surface to be faced, and between the side turned NOSTA and intermediate vertical elements disposed to insulate layer so as to form an air gap with the facing layer. ! 2. The facade according to claim 1, characterized in that the insulation layer is made of mineral wool boards. ! 3. The facade according to claim 1, characterized in that the intermediate vertical element is made with the possibility of fastening to the surface to be coated by means of supporting profiles. ! 4. The facade according to claim 3, characterized in that each intermediate vertical element and the supporting profile have a U-shaped profile in cross section. ! 5. The facade according to claim 4, characterized in that an adjustable clearance is formed between the intermediate vertical element and the supporting profile. ! 6. The facade according to claim 1, characterized in that each horizontal bearing element has the shape of a corner. ! 7. The facade according to claim 1, characterized in that each fixing node is made with the possibility of fastening through an insulating gasket to intermediate vertical elements and is a connecting corner made of masonry mesh.

Description

The utility model relates to the field of construction, in particular to the construction of multilayer outer walls of residential, public and industrial buildings, and can be used in the construction of new buildings / structures, reconstruction and overhaul of the outer walls of buildings for various purposes and floors with a height of up to 75 m.

The prior art external curtain wall of a multi-storey frame building, made without floor cutting of the outer layer of the wall and the insulation layer (RU 48338, 10.10.2005). The outer facing layer rests on each floor on the upper and lower horizontal belts of the steel truss, which is fixed by the two ends of the upper belt on the cantilever tables of the outer columns: at least at the upper surface of the reinforced concrete multi-hollow floor slab, and the lower truss belt is also fixed by two ends on the cantilever supports on columns and is a jumper for the outer layer of the wall, at least for two window openings, and the inner layer of the wall rests on a reinforced concrete multi-hollow slab floors and a reinforced concrete lintel is installed above each window opening. The height of the steel truss is calculated and accepted as a multiple of the number of spoon rows of bricks laid between the upper and lower trusses of the truss on the outer facing layer of the wall. The upper and lower belts of the steel truss are fixed on two columns with the possibility of compensating for the horizontal movement of their ends along the axis of the truss at ambient temperature differences.

Known external multilayer wall of the building, containing the outer layer of prefabricated panels, fixed by metal ties to the supporting structures of the building with the formation of horizontal and vertical air gaps between them, a ventilated air gap, an intermediate insulation and inner layers of individual elements and / or small pieces ( RU 2335606, 10.10.2008). The outer layer is in the form of a light decorative panel consisting of a metal frame made of bent sheet profiles with vertical Z, U-shaped and horizontal L-shaped elements, with decorative lining fixed to it, and on the inside of the panel lining - support bracket systems Г -shaped and a metal mesh of wire with a diameter of 2-6 mm with a cell of 150-200 mm parallel to the plane of the panel at a distance of 20-100 mm from the lining with the formation of a fixed ventilated air gap, closing captive to a metal supporting frame prefabricated throughout the building, connected to floor slabs or the building supporting frame with metal ties in increments equal to the pitch of the support brackets of the outer panel, each outer layer panel being installed relative to adjacent panels with gaps of 5-20 mm .

The closest analogue of the proposed utility model is a multilayer outer wall panel, including an outer facade layer formed by masonry, bearing the inner layer, the connections between them and the insulation layer. The bearing inner layer is made monolithic, and the masonry of the facade layer is made with lateral faces of the comb type and mounted on discretely positioned supporting elements rigidly fixed in the bearing inner layer (RU 11238, September 16, 1999).

A disadvantage of the known solutions is the high complexity, heat loss in winter and overheating of the building.

The problem to which the proposed utility model is directed is to create a hinged ventilated facade with a facing layer of brick, which would eliminate the above disadvantages.

The technical result achieved by the implementation of this utility model / is:

- in reducing heat loss in the winter and overheating of the building, and consequently, the energy consumption for air conditioning in the summer;

- the presence of an air gap allows to avoid the loss of internal condensate on the insulation, because the moistened layers dry quickly due to constant ventilation, without limiting the thermal protection of the building;

- to increase the level of sound insulation of the building;

- to avoid the need to eliminate errors in the coated surfaces (deviations from the vertical, defects in the base, etc.);

- reducing the complexity of the work due to the ability to work at different altitudes simultaneously.

The specified technical result is achieved in a hinged ventilated facade containing a facing layer formed by brickwork, a warming layer and a device for fastening the facing layer, consisting of horizontal supporting elements made with the possibility of fastening on intermediate vertical elements, and fixing units, while facing the layer is located on the supporting horizontal elements, each intermediate vertical element is made with the possibility of attachment to the surface to be faced, and between the surface to be coated and intermediate vertical elements there is a warming layer with the possibility of forming an air gap with the facing layer.

The insulation layer is made of mineral wool boards.

The intermediate vertical element is made with the possibility of fastening to the surface to be coated by means of supporting profiles.

Each intermediate vertical element and the supporting profile has a U-shaped profile in cross section.

An adjustable gap is formed between the intermediate vertical element and the support profile.

Each horizontal bearing element has the shape of a corner.

Each fixing unit is made with the possibility of fastening through an insulating gasket to intermediate vertical elements and is a connecting corner made of masonry mesh.

The essence of the utility model is illustrated by drawings, where in Fig.1 shows a General view of a hinged ventilated facade in isometry; figure 2 is a side view of a hinged ventilated facade; figure 3 is a top view of a hinged ventilated facade; figure 4 - shows the connection of the supporting horizontal element with an intermediate vertical element; figure 5 - shows the connection of the locking node with an intermediate vertical element; figure 6 - hinged ventilated facade with a warming layer.

Design features of the hinged ventilated facade:

- Facing of building facades with brick according to the “ventilated facade” method;

- The bearing wall of the building is insulated from the outside with mineral wool plates;

- Intermediate vertical elements (vertical guides) are fastened to the wall by means of supporting profiles (brackets);

- On the bearing horizontal elements (horizontal guides) installed with a step of 1 m, brickwork is made in 1/2 brick using mortar;

- An air gap is made between the insulation layer and the facing layer;

- After every 4-5 rows of brick masonry, fixing knots are installed (connecting corners from the masonry net);

- Under the layer of masonry between two horizontal supporting elements, an expansion joint is arranged.

The hinged ventilated facade comprises a facing layer 5 formed by brickwork, a warming layer 20 and a device for attaching the facing layer.

A device for attaching a brick facing layer comprises a support profile 1 (Fig. 1) fixed to the facing surface 2, intermediate vertical elements 3 connected to the supporting horizontal elements 4, and fixing nodes 9 connected to the intermediate vertical elements 3 and to the facing layer 5 made of bricks.

Each horizontal supporting element 4 has a vertical support shelf 19 and a support shelf 6 lying in a plane perpendicular to the surface to be coated 2 and the 1st row of brick lining.

Each supporting profile 1 and the intermediate vertical element 3 in cross section by a horizontal plane has a U-shaped profile. The shelf 16 of the support profile 1 is fixed to the surface to be coated 2 by means of an anchor 11, and the shelves 17 of the intermediate vertical element 3 are facing the brick facing layer 5, while an adjustable gap 7 is formed between the shelves 16 and 17 to compensate for the unevenness of the surface 2.

In this case, the support profile 1 is mounted on the surface 2 exposed to the cladding, by means of an anchor 11 (anchor bolt with nut). The fastening of the intermediate vertical element 3 on the supporting profile 1 is carried out by means of rivets 10 or bolts 14. Each supporting horizontal element 4 is fixed on the shelf 17 of the intermediate vertical element 3 by means of bolts 14 (Fig. 4).

The fixing unit 9 is a connecting corner of a masonry net, having a shelf 8 lying in a plane perpendicular to the surface to be coated 2 and a layer of mortar mixture 12 with which the shelf 8 is engaged.

Each connecting corner through the shelf 18 is mounted on the shelf 17 of the intermediate vertical element 3 with bolts with nuts 14 and washers 15. Between the shelf 18 of the connecting corner and the shelf 17 of the intermediate vertical element 3, an insulating gasket 13 is installed (Fig. 5).

Installation of a ventilated facade is carried out with scaffolding and a hand-held power tool (perforator, drill, rivet), a bricklayer tool are used. Work is done at different altitudes simultaneously.

On the surface 2 (wall surface) exposed to the lining, support profiles 1 are mounted by means of anchor bolts with nuts 11 located at a predetermined distance from each other vertically and horizontally. After that, at least two supporting profiles 1 vertically insert an intermediate vertical element 3 of limited length, due to the need for gaps to compensate for its thermal expansion. The intermediate vertical element 3 is included in the cavity of one of the supporting profiles 1, limited by its side walls and the shelf 16. The intermediate vertical element 3 is inserted with a slight effort into the supporting profile 1. Regardless of the relief of the surface 2 exposed to the lining, the supporting flanges 17 of all intermediate vertical elements 3 are installed in one vertical plane by adjusting the gap 7. Then the intermediate vertical element 3 and the supporting profile 1 are connected by fasteners, for example, rivets 10. Following this establishes the horizontal supporting elements 4 by the supporting vertical shelves 19 on the supporting shelves 17, of the intermediate vertical elements 3 and is fixed by means of fasteners - for example, bolts 14. After that, on the shelf 6 of the horizontal horizontal element 4, brickwork of the facing layer 5 on the mortar mixture 12 begins. After a certain number of rows of masonry, connecting corners are placed. Its shelf 8 is placed in the mortar layer 12, and the connecting angle shelf 18 is connected to the supporting shelves 17 of the intermediate vertical element 3 through an insulating gasket 13 by, for example, a bolt with a nut 14 and a washer 15. Further, the laying of the facing layer 5 continues until the next horizontal bearing element 4. The distance between two horizontal supporting elements 4 is selected by the calculation of bearing loads. Between the last row of masonry and the next horizontal bearing element 4 there is left a gapless gap for temperature-strain compensation.

Claims (7)

1. A hinged ventilated facade, characterized in that it contains a facing layer formed by brickwork, a warming layer and a device for fastening the facing layer, consisting of horizontal supporting elements made with the possibility of fastening on intermediate vertical elements, and fixing knots, while facing the layer is located on the supporting horizontal elements, each intermediate vertical element is made with the possibility of fastening to the surface to be faced, and between the side turned NOSTA and intermediate vertical elements disposed to insulate layer so as to form an air gap with the facing layer. 2. The facade according to claim 1, characterized in that the insulation layer is made of mineral wool boards. 3. The facade according to claim 1, characterized in that the intermediate vertical element is made with the possibility of fastening to the surface to be coated by means of supporting profiles. 4. The facade according to claim 3, characterized in that each intermediate vertical element and the supporting profile have a U-shaped profile in cross section. 5. The facade according to claim 4, characterized in that an adjustable clearance is formed between the intermediate vertical element and the supporting profile. 6. The facade according to claim 1, characterized in that each horizontal bearing element has the shape of a corner. 7. The facade according to claim 1, characterized in that each fixing node is made with the possibility of fastening through an insulating gasket to intermediate vertical elements and is a connecting corner made of masonry mesh.