RU60551U1 - FRAMELESS FRONT CONSTRUCTION - Google Patents

Abstract

Frameless facade construction, consisting of individual panels, elements, each of its elements consists of two vertical pillars, the upper horizontal part and the lower horizontal part of the frame and the seal and drainage installed between them. The upper horizontal part of the frame and one vertical rack of the element have shelves for connection, the main feature of this design is that the upper horizontal part of the frame and the vertical rack consist of main profiles and auxiliary profiles with shelves for connection. The connection of the main profiles with auxiliary profiles is carried out by fasteners. During installation, the upper horizontal part of the frame and the vertical racks of the element are connected to the lower horizontal part of the frame and the vertical racks of the upper element by insertion. The advantages of this utility model are that due to the fact that the auxiliary profile is a removable part of the main profile, it is possible to determine the place of connection-insertion of the element by three-dimensional fitting. When assembling the element by adjusting the position of the auxiliary profiles relative to the main profiles, they can be connected, which can satisfy different conditions, which allows you to fulfill various requirements to the appearance of the building, carry out the sealing of the facade system and drainage.

Description

Technical field

This utility model relates to the exterior structure of a building, namely, the design of a frameless facade system consisting of separate panels, which is used in high-rise buildings, including buildings with curved surfaces, which have strict requirements for thermal protection of the facade system.

About technology

For a frameless facade system consisting of separate panels, elements, processing and assembly of elements is carried out at the factory, so that you can effectively control the accuracy of part processing and the quality of assembly of elements. In addition, due to the fact that the connection of the elements is carried out by inserting, the accuracy of the installation of the elements is very high, the surface smoothness is good, the installation of elements at the construction site has become much easier and can be done in parallel with other works or sequentially with them. Thanks to such advantages as high precision machining, quick installation and short lead time frameless facade system, consisting of individual panels, elements is widely used in modern buildings. Currently, various buildings have appeared that have curved surfaces. For such buildings with a certain curvature, ordinary frameless facade systems consisting of elements cannot repeat their contours, drain, and provide sealing. In addition, when fitting panels-elements of an ordinary facade system in order to obtain the desired contour, the technology for processing glass and profiles is very complex, and, accordingly, the cost is also high. In most cases, there is only a theoretical possibility of implementation.

Utility Model Essence

The purpose of this utility model is to present a new design of a frameless facade system consisting of separate panels-elements, which meets all the requirements of buildings with curved surfaces, carries out sealing of the facade system, drainage and thermal insulation between profiles using new type of heat-insulating elements.

This goal is as follows. Each element consists of two vertical posts, the upper horizontal part and the lower horizontal part of the frame, seals installed between them and a drainage system. The upper horizontal part of the frame and one vertical rack of the element have shelves for connection, the main feature of this design is that the upper horizontal part of the frame and the vertical rack consist of main profiles and auxiliary profiles with shelves for connection. The connection of the main profiles with auxiliary profiles is carried out by fasteners. During installation, the vertical posts and the upper horizontal part of the element frame are connected to the vertical posts and the lower horizontal part of the frame of the upper element by insertion.

The advantages of this utility model are that due to the fact that the auxiliary profile is a removable part of the main profile, it is possible to determine the place of connection-insertion of the element by three-dimensional fitting. When assembling the element by adjusting the position of the auxiliary profiles relative to the main profiles, they can be connected, which can satisfy different conditions, which allows you to fulfill various requirements to the appearance of the building and carry out the sealing of the facade system and drainage.

Brief Description of the Drawings

Figure 1 is a breakdown of a frameless facade system consisting of individual elements of this utility model.

Figure 2 - section aa, indicated in figure 1.

Figure 3 - section bb, indicated in figure 1.

Figure 4 - section CC, indicated in figure 1.

5 is a diagram of the drainage structure of the seal of the present utility model.

6 is a diagram of the assembly of the facade system of a building having curved surfaces.

In the figures indicated: 1 - the main profile of the vertical strut of the right element, 4 - vertical strut of the left element. The main profile 1 and the auxiliary profile 2 form a vertical pillar of the right element. Due to the curvature of the building’s surface, the elements are offset from each other by different distances H in horizontal levels (that is, they are not in the same plane), using a three-dimensional fitting, you can get the location of the auxiliary profile 2 relative to

main profile 1 vertical stand. After connecting the auxiliary profile 2 with the main profile 1 of the vertical strut with screws 3, the auxiliary profile 2 is connected (by insertion) with the vertical strut of the adjacent element. Thus, the element is mounted horizontally.

Figure 3 shows a section of the connection-insert horizontal parts of the frames of the elements: 11 - the lower horizontal part of the frame of the element, 15 - the main profile of the upper part of the frame of the lower adjacent element. In order to compensate for displacements in the vertical direction for the horizontal upper parts of the element of this utility model, the same principle is applied as for vertical racks. Namely, after connecting with the main profile 15 of the upper horizontal part of the element frame with screws 3, the auxiliary profile 14 of the upper horizontal part of the element frame is connected by inserting the upper adjacent element with the lower horizontal part 11 of the frame in order to compensate for the displacement.

Sealing and drainage are as follows. Figure 2 and Figure 4 shows that at the junction of the auxiliary profile 2 of the vertical column with the vertical column 4, gaskets 5, 6 are installed, and foam filler is installed in the groove for additional sealing of the facade. In addition, in the gap between the two elements, a gasket 7 is installed.

To seal the horizontal part of the frame of the element of this utility model and drainage (see Fig. 3), gaskets 16, 10 are installed at the junction of the auxiliary profile 14 of the upper horizontal part of the frame with the lower horizontal part 11 of the frame of the upper adjacent element, and the gutter is installed foam filler 8. The sealing gasket 10 is a continuous gasket ebb and carries out the drain. In the gap between the two elements, a gasket 26 is installed, which provides repeated isolation from water. The gasket 26 is located on a continuous sealing gasket of the ebb 10, its length is equal to the width of the element. The gasket 26 has three water-insulating wings, on which drainage holes 17 are made at a certain distance from each other (Figure 5). Accordingly, on the front part of the auxiliary profile 14 of the upper horizontal part of the element frame, a drainage hole 18 is made (Fig. 5). The combination of a continuous sealing strip of the ebb 10 and a sealing strip 26 of multiple isolation from water allows for drainage in tiers.

The continuous seal of the ebb 10, the seal 26 of repeated isolation from water and the seal 16 together form space III and space IV. The continuous seal gasket 10 and

a multiple gasket seal 26 is isolated from most of the rainwater, but under the influence of wind a small amount of rainwater enters space III through space I (FIG. 2). The holes made on the wings of the sealing gasket of multiple insulation are not only drainage, but also pressure adjustment holes. Pressure adjustment holes adjust the pressure in space III so that it is equal to the pressure from the outside, which reduces the amount of water entering. The drainage holes are designed to remove water that has entered the space III through the holes 17 on the gasket of multiple insulation 26. In strong winds, rainwater can enter the space IV, and from here a small amount of water passes through the drainage holes 18 on the auxiliary profile 14 of the upper horizontal part of the frame element into the space III of the lower element, then removed through holes 17 on the gasket of multiple insulation 26 to the outside.

On the inner wall at the end of the auxiliary profile 14 of the upper horizontal part of the element frame, an insert-core 13 of the transverse movement and an abutment-core 12. An insert-core 13 of the transverse movement is attached to the auxiliary profile 14 of the upper horizontal part of the frame of the element with screws. The lower part of the abutment-core 12 is connected to the insert-core 13 of lateral movement by means of screws 27, its upper part is inserted into the cavity of the vertical strut of the upper adjacent element.

In this utility model, an insert-core of lateral movement with position adjustment and a stop-core 12 of limiting the displacement of the center of gravity of the element are used. The insert-core 13 of the transverse movement connects the left, right, upper and lower elements, performs the function of fixation, drainage and sealing. The transverse motion core insert 13 seals the connection point of the four elements on four sides. The transverse core insert 13 changes the direction of the water coming from the upper element, and the water is removed through the drainage holes 18 on the auxiliary profile 14 of the upper horizontal part of the element frame. The base of the stop-core 12 is attached to the insert-core 13 of the transverse movement, its upper part is inserted into the cavity of the main profile of the vertical strut of the upper element and fixes the element.

Figures 2 and 4 show that three-time sealing of the seam of the horizontal connection of the elements consists of sealing gaskets 7, 6, 5. The sealing gasket 7 already isolates from most of the rainwater, but under the influence of the wind load a small amount of water falls into space I, and the space I connected

with space III (Figure 3). Using the drainage holes 17 on the seal strip of multiple insulation 26, the air pressure in space I is equal to the air pressure outside, which reduces the ingress of rainwater. Rainwater that has got into space I under the influence of its own weight falls into space III, then it is removed through drainage holes 17 on the sealing gasket of multiple insulation 26. The vertical struts of the two elements and the gaskets 5, 6 form a cavity II, which is connected to the cavity IV. The water that has got into the space II flows into the space IV and is removed to the outside through the multi-tiered drainage system.

Due to the curvature of the building surface, the vertical racks of the elements can be tilted to the room, which is why water from space II flows into the room along the profile. In order to avoid this, a drainage device is provided in the connection cavity of the vertical column 4 and the auxiliary profile 2 of the vertical column (i.e., a gasket 28 is installed on the vertical column 4, the drain channel 29 is installed on the auxiliary profile 2 of the vertical column). Thus, it is possible to effectively avoid the flow of water from space II into the room and divert it into space IV.

Using Figure 5, you can get acquainted with the principle of drainage of this design. Water 19, falling under the influence of wind load into the cavity formed by the connection-insert with the gasket 7, under the influence of its own weight falls on the upper surface of the continuous sealing gasket of the tide 10 and is removed outside. Water 20 entering the space I, falls under the influence of its own weight into the space III and, together with the water 21 directly falling into the space III, is drained out through the drain holes 17 on the sealing gasket 26. A small amount of water 22 entering the space 11 falls into space IV and through the drainage holes 18 at the end of the auxiliary profile of the upper horizontal part of the element frame enters the space I of the lower element. Thus, the entire system is reliably sealed and the facade is watertight.

The continuous sealing strip of the ebb 10 carries out a phased drainage of the frameless facade system of high-rise buildings, consisting of individual panels, which meets the deformation requirements of the main structure under different conditions.

On the vertical racks and the upper and lower horizontal parts of the frame of the element of this facade system, a heat-insulating element 9 is installed, which consists of two parts, one part has two grooves for the gasket, in the gutter you can

install many layers of gaskets, the other part has an air-insulating rib. After assembly, two cavities are formed inside the heat-insulating element 9, which significantly improves the heat-insulating properties of the heat-insulating element 9. The advantages of this heat-insulating element 9 are the reliability and strength of the structure, as well as a simplified processing process.

Figure 6 shows that in this utility model, when installing the elements vertically, it is ensured that the package 23, consisting of the lower horizontal part of the frame of the element and the auxiliary profile of the upper horizontal part of the frame of the lower element, repeats the theoretical curve of the building, that is, the two ends 24 of this package 23 is on a theoretical curve. However, after installation, the main profile 15 of the horizontal upper part of the frame of the element will not be on the theoretical curve of the building. Therefore, when assembling the elements, the midpoint 25 of the main profile 15 of the upper horizontal part of the element frame should be on the theoretical curve, and there is an angular deviation of the main profile 15 of the upper horizontal part of the element frame from the theoretical curve relative to the midpoint 25. When connecting the lower horizontal part 11 of the frame of the upper element with the upper horizontal part of the frame of the lower element, in order to ensure that the package 23 is on a theoretical curve, adjusting the positions of the main profile 15 and a powerful profile of the upper horizontal part 14 of the element frame we compensate for the angular deviation from the theoretical curve. By three-dimensional adjustment, the position of the main profile 15 and the auxiliary profile 14 of the upper horizontal part of the element frame relative to each other is obtained and fixed with screws. Next, an insert-connection is made with the lower horizontal part of the frame of the upper element, thus performing the installation of elements vertically.

Claims (7)

1. Frameless facade design, consisting of separate panels, elements, in which each of its elements consists of two vertical racks, the upper horizontal part and the lower horizontal part of the frame, seals installed between them and the drainage system, the upper horizontal part of the frame and the vertical element stand have shelves for connection, and the upper horizontal part of the frame and the vertical stand consist of main profiles and auxiliary profiles with shelves for connection, connecting the main profiles with auxiliary lnymi profiles carried fastening elements, the upper horizontal frame piece and vertical rack member connected to the lower horizontal frame part and the uprights of the upper member by insertion. 2. The construction according to claim 1, characterized in that at the end inside the auxiliary profile of the upper horizontal part of the element frame there is an insert-core of the transverse movement and an abutment core, the insert-core of the transverse movement attached to the auxiliary profile of the upper horizontal part of the frame with fastening elements and connects to the auxiliary profile of the upper horizontal part of the frame of the horizontally adjacent element by insertion, and the lower part of the stop-core is attached to the transverse core-insert th movement, its upper portion is inserted into the cavity of the upper strut member. 3. The construction according to claim 1, characterized in that at the junction of the upper horizontal part and the lower horizontal part of the element frame, a continuous gasket is provided, with the possibility of drainage. 4. The construction according to claim 1, characterized in that between the lower horizontal part of the frame of the upper element and the upper horizontal part of the frame of the lower element, a gasket is provided for multiple isolation from water, having at least two wings, and the length of which is equal to the width of the element. 5. The construction according to claim 1, characterized in that in the uprights of the upper horizontal part and the lower horizontal part of the element frame, heat-insulating elements are installed, consisting of two parts, one of which has a groove under the gasket, and the other has a rib for isolation from air . 6. The construction according to claim 1, characterized in that in the grooves for the connection-insertion of the uprights, the upper horizontal and lower horizontal parts of the element frame, a foam filler is installed. 7. The construction according to claim 1, characterized in that in the cavity formed by the connection-insert a drainage system is provided, which includes a sealing gasket for isolation from water, mounted on the inner wall of the vertical rack on one side and a drainage groove mounted on the inside the wall of the upright on the other hand.