RU89859U1 - FRAME-PANEL BUILDING - Google Patents

Abstract

1. Frame-panel building, containing external wall panels, hung on the columns of the frame, made with hanging elements on the side faces, characterized in that the wall panels are made with a shelf for supporting floor slabs formed on the inner side of the panel and placed in the alignment between the columns while the hanging elements of the panel are formed in the lateral ends of this shelf. ! 2. The building according to claim 1, characterized in that the hanging elements of the column are located on the geometric axis of the column in cross section. ! 3. The building according to claim 1, characterized in that the shelf is formed at a distance from the upper end of the panel corresponding to the thickness of the floor slab. ! 4. The building according to claim 1, characterized in that the shelf is made with a length shorter than the panel length by the column width and is located at a distance from the side ends of the panel corresponding to half the column width. ! 5. The building according to claim 1, characterized in that as the wall panels used three-layer wall panels on flexible connections with the middle layer of an effective insulation. ! 6. The building according to claim 5, characterized in that the inner and middle layers of the panel are made commensurate with the length of the shelf and brought into the target between the columns. ! 7. The building according to claim 1, characterized in that a centering protrusion is made in the upper end of the panel, and a reciprocal recess interacting with the centering protrusion of the underlying panel is made in the lower end of the panel. ! 8. The building according to claim 1, characterized in that the column hanging elements include a support console, while the wall panel hanging elements contain a through groove formed at the end of the shelf to accommodate the console and intersecting the groove per�

Description

The technical field to which the utility model relates.

The utility model relates to the field of construction of buildings and structures using prefabricated wall mounted curtain panels.

State of the art

A frame-panel construction system with a complete prefabricated load-bearing reinforced concrete frame includes columns, crossbars, panel exterior walls and panel ceilings. This system most satisfies the requirements of freedom of planning and redevelopment of premises, but has limited use in mass housing construction due to the high complexity and increased consumption of steel. The mentioned building system includes the well-known series of standardized prefabricated reinforced concrete products 1.020-1, intended for the construction of public and multi-storey industrial frame and panel buildings. It is known a building constructed using the aforementioned series, containing the columns of the frame and the outer fence of the hinged wall panels, fixed to the supporting elements of the columns at three points (see the book by T.G. Maklakov. Designs of civil buildings. M .: publishing house of the association of building Universities, 2004, pp. 64-69, Fig. 3.7 and 3.8). Hinged wall panels are non-load-bearing elements of the building, and facade bolts are installed to support the floor panels, which are installed on the supporting elements of the columns on the other side of the external fence.

A frame-panel multi-span building is known that contains columns, crossbars mounted between them and an external fence made of wall panels made with a shelf on the inside intended for supporting floor panels (see patent No. 2119195, IPC: Е04В 1/38, publ. 1999.04 .twenty). Due to the fact that the external wall panels provide for the installation of floor panels, precast elements such as facade crossbars are excluded in the building. However, the above-mentioned wall panels are load-bearing, and, perceiving the load from their own weight and the weight of the floor slabs, they transfer it to the building foundation, and not to the facade columns, which are also absent in this design, and their supporting functions are performed by the vertical edges of adjacent wall panels.

As the closest analogue for the proposed solution adopted the design shown in the patent for invention SU No. 1390326, IPC: EV 1/38, publ. 1988.04.23). According to the aforementioned patent, the frame-panel building includes columns of the frame and external wall panels hung on them. For hanging the panel, L-shaped elements are formed, incl. on the side faces of the column. The design of such a building assumes the presence of facade and internal crossbars installed on the supporting elements of the columns and made with shelves for supporting the floor slabs. The disadvantages of this building include the high complexity of installation and welding, due to the large number of prefabricated elements. In addition, the design of the hanging elements of the panel causes the complexity of the installation, suggesting an inclined location of the panel during hanging.

Utility Model Disclosure

The objective of the claimed utility model is to simplify the design of a prefabricated frame-panel building with hinged wall panels, increase the manufacturability of installation, reduce the complexity of assembly work.

The problem is solved in that in a frame-panel building containing external wall panels hung on the columns of the frame made with hanging elements on the side faces, according to the claimed utility model, wall panels are made with a shelf for supporting floor slabs formed on the inner side of the panel and placed in the alignment between the columns, while the hanging elements of the panel are formed in the lateral ends of this shelf.

The implementation of the wall panel with a horizontal shelf, designed to support the floor slabs, allowed to transfer part of the supporting functions to the external wall mounted wall panels and thereby exclude the facade girders, as separate prefabricated elements, from the building structure. Reducing the total number of prefabricated units allowed to significantly simplify and speed up the installation of the building, reduce the number of welding works.

At the same time, the implementation of the crossbar component as a whole with the wall panel made it possible to significantly reduce its size, in comparison with a single crossbar.

The dimensions of the beam-crossbar in the plane of application of loads from floor slabs, i.e. its thickness (height) is much less than its length between the supports, as a result of which the beam-crossbar is subject to deflection. To ensure sufficient rigidity and strength, increase the thickness and width of the crossbar, increase its reinforcement.

In the claimed design of the wall panel, including the crossbar part, the effective vertical load from the weight of the floor slabs is transferred from the shelf to the panel, which is characterized by significantly greater rigidity in the cross section (along the height of the panel) than the beam-crossbar.

Thus, the bearing capacity of the crossbar part with the shelf of the proposed wall panel significantly exceeds the bearing capacity of a similarly sized crossbar, which allowed to significantly reduce the dimensions of the said crossbar part while maintaining the calculated strength and bearing capacity. As a result of using the inventive hybrid panel instead of conventional hinged panels and communication beams in the building structure, there was a significant reduction in the consumption of concrete and steel, and the overall material consumption of the building decreased.

Moreover, due to the fact that the formation of the bearing crossbar is carried out simultaneously with the manufacture of the panel, it became possible to reduce the time and other costs associated with the production of prefabricated elements, and as a result, cheaper construction.

The prior art exterior wall panels with shelves for supporting floor slabs, see patent No. 1663159, publ. 07.15.91 g, or patent No. 1032140, publ. 07/30/83. However, in all decisions, the shelves are made on load-bearing external wall panels, which themselves absorb loads and transfer them to the building foundation.

In the claimed solution, the external wall panels are non-load-bearing elements of the building and only transfer loads to the columns of the frame docked with them. Placing the shelf in the alignment between adjacent columns and the implementation of the hanging elements in the lateral end parts of the shelf interacting with the hanging elements of the columns placed on the lateral faces of the latter allowed the load to be transferred from the weight of the wall panels and floor slabs to the columns of the frame with virtually no eccentricity. Columns are a centrally compressed element. In the presence of eccentricity, a shoulder appears, unevenly compressed and stretched concrete zones appear. To maintain strength in such cases, additional reinforcement is required, so the best option for transferring the load is transmission through the center of the column.

In order to completely eliminate eccentricity, the elements of hanging columns are placed on the geometric axes of the columns in cross section.

At the same time, this solution made it possible to introduce wall panels (or part of them) into the columns of the columns, which made it possible to increase the useful area of the building and increase the rigidity of the wall fencing, and also greatly facilitated the installation of the wall fencing, as during installation, the panel is brought into the target between the columns, which at the same time serve as guiding orienting elements.

The shelf is carried out at a distance from the upper end of the panel, corresponding to the thickness of the floor panel, which makes it possible to obtain an even floor covering of the overlying room.

The part of the panel located above the shelf is usually thickened, due to the supporting functions of the shelf.

In a preferred embodiment of the invention, the shelf is made with a length shorter than the panel by the width of the column, and is located at a distance from the side ends of the panel corresponding to half the width of the column. At the same time, part of the panel, by its thickness, is also advisable to perform in proportion to the shelf, which will allow it to be placed in the alignment of the columns. In this case, the “shortened” protruding outer parts of the wall panels to be joined cover the column from the side of the outer face, protecting it. This solution improves the thermal performance of the building. The spacing of the vertical seam from the outer and inner sides made it possible to obtain a “warm” vertical seam. Traditionally, for example, as in the prototype, the vertical seam of the panels is through. In the claimed solution, the vertical seam between the panels is carried out with a shift of the layers, which eliminates blowing and freezing at the joints of the panel and facilitates the process of sealing joints.

As wall panels, single-layer wall panels made of lightweight cellular concrete or three-layer wall panels with flexible connections to the middle layer of effective insulation, polystyrene foam or mineral wool can be used. Three-layer wall panels have enhanced heat and sound insulating characteristics, durability. In a particular case, the inner and middle layers of the panels are made commensurate with the length of the shelf and are arranged in an alignment between the columns, the outer layer pane protrudes beyond the limits of the columns, typically _^1/2 of a column width.

Column hanging elements include a support console. The wall panel mounting elements comprise a through groove formed at the end of the shelf, designed to accommodate the console, and a jumper crossing the groove, worn on top of the console. This solution allows for quick and non-alignment installation of wall panels.

A through groove can be formed by means of a embedded part made in the form of a hollow duct open from below and above, with the jumper formed by a U-shaped plate forming the front wall of the duct. To facilitate installation, the support console can be made removable.

The ability to carry out quick non-alignment mounting is also provided by performing a centering protrusion - a spike in the upper end of the panel, preferably in its central part. In the lower end of the panel, a reciprocal recess is made, interacting with the centering protrusion of the underlying panel. The connection of the panels on the principle of "tenon groove" greatly facilitates the installation of wall fencing.

Wall panels are additionally fixed to the column at least one more level in height of the panel.

Brief Description of the Drawings

Figure 1 - shows a fragment of a frame-panel building, a plan view;

Figure 2 - a fragment of figure 1, enlarged;

Figure 3 is a view a from figure 2, a view of the wall of the outer fencing from the inside of the building,

Figure 4 - shows a lightweight single-layer wall panel made in accordance with the claimed utility model,

Figure 5 is also a view In from figure 4,

Figure 6 - shows a three-layer wall panel made in accordance with the claimed utility model,

In Fig.7 - also, view C from Fig.6,

On Fig - fragment of figure 3, shows the connection node of the panel with the column, enlarged.

Figure 9 - schematically shows the installation of the wall panel.

Utility Model Implementation

The frame-panel building (see Figs. 1-3) contains columns 1 of the frame and external wall panels 2 mounted on them, made with a horizontal shelf 3 formed on the inside of the panel 2 and placed in the alignment between adjacent columns 1. On the shelf 3 based on one end of the floor slab 4, supported by the other end on the internal crossbars 5. The shelf 3 is located at a distance from the upper end of the panel 2, corresponding to the thickness h of the floor slabs 4.

As wall panels 2 can be used single-layer wall panels made of lightweight cellular concrete (see Fig. 4, 5), or three-layer wall panels with flexible connections, for example, expanded clay concrete with effective insulation made of polystyrene foam or mineral wool (see Fig. 6 , 7). The inner carrier layer 6 and the middle layer 7 of the insulation are made commensurate with the shelf 3 and brought into the target of the columns 1. In the upper end of the panel 2, a centering protrusion 8 is made, and in the lower end there is a reciprocal recess 9 interacting with the centering protrusion 8 of the underlying panel 2. The upper part 10 located above the shelf 3 is made thickened. The connection node of the panel 2 with the column 1 is shown in Fig. 8. On the side faces of 11 columns 1 mounted embedded parts with a L-shaped support console 12, which can be made removable. The hanging elements are formed in the lateral ends of the flange 3 of the wall panel 2 and include a through groove 13 formed by the embedded part in the form of a hollow duct 14 open from the bottom and top with the front wall in the form of a U-shaped plate 15.

The formation of wall mounted wall panels with a shelf for supporting floor slabs is carried out on conventional equipment by known methods in a specially made formwork, which ensures the formation of the shelf. First, in the formwork (form) with the reinforcing structure fixed in it, the inner layer with the shelf is formed, then the insulation layer is poured and the outer facade layer is formed last, which can be subjected to additional decoration (billing).

Installation of frame-panel building is as follows.

The wall panel 2 is horizontally inserted (see Fig. 9) into the target between adjacent columns 1 of the frame. In this case, the panel 2 is strictly oriented relative to the columns 1, the side surfaces 11 of which limit the possible deviations of the panels. The panel 2 is lowered to the stop of the jumper 15 in the console 12 of the column, while the latter freely enters the organized groove 13.

Thus, the panel 2 is freely mounted on the console 12 of adjacent columns 1. In this case, the correct installation of the panel and its vertical arrangement is also ensured by combining the recess 9 located at the lower end of the panel 2 with the spike 8 of the underlying panel. Thus, the panel is set at three points. After hanging the nodes of the connection (hanging) monopolize.

The panel 2 is additionally fixed, at least one more level in the height of the panel, by welding the embedded parts 16 of the panel 2 to the reciprocal embedded parts 17 of the columns 1.

The design of the hanging elements allows for quick and non-aligning installation of panels, which also saves the time of construction of the building as a whole.

Claims (12)

1. Frame-panel building, containing external wall panels, hung on the columns of the frame, made with hanging elements on the side faces, characterized in that the wall panels are made with a shelf for supporting floor slabs formed on the inner side of the panel and placed in the alignment between the columns while the hanging elements of the panel are formed in the lateral ends of this shelf. 2. The building according to claim 1, characterized in that the hanging elements of the column are located on the geometric axis of the column in cross section. 3. The building according to claim 1, characterized in that the shelf is formed at a distance from the upper end of the panel corresponding to the thickness of the floor slab. 4. The building according to claim 1, characterized in that the shelf is made with a length shorter than the panel length by the column width and is located at a distance from the side ends of the panel corresponding to half the column width. 5. The building according to claim 1, characterized in that as the wall panels used three-layer wall panels on flexible connections with the middle layer of an effective insulation. 6. The building according to claim 5, characterized in that the inner and middle layers of the panel are made commensurate with the length of the shelf and brought into the target between the columns. 7. The building according to claim 1, characterized in that a centering protrusion is made in the upper end of the panel, and a reciprocal recess interacting with the centering protrusion of the underlying panel is made in the lower end of the panel. 8. The building according to claim 1, characterized in that the hanging elements of the column include a support console, while the hanging elements of the wall panel comprise a through groove formed at the end of the shelf to accommodate the console, and a jumper crossing the groove worn on top of the console. 9. The building of claim 8, characterized in that the through groove is formed by means of a embedded part made in the form of a hollow duct open from below and from above, and the bridge is formed by a U-shaped plate forming the front wall of the duct. 10. The building of claim 8, characterized in that the console is removable. 11. The building according to claim 1, characterized in that the wall panel is additionally fixed to the column, at least one more level in height of the panel. 12. The building according to claim 1, characterized in that the part of the panel located above the shelf is made thickened.