RU69131U1 - PANEL FOR BANK STORAGES, SAFES AND ARMORED DOORS (OPTIONS) - Google Patents

Abstract

The invention relates to special purpose building structures, in particular, panel designs for bank vaults, fireproof safes, armored doors, etc. products. In the first embodiment, the panel for bank vaults, safes and armored doors includes a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements of a strip, channel or corner in any combination thereof, reinforcing elements welded butt to the frame elements, and a concrete body . According to the invention, the concrete body is made of fiber-reinforced concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, while the reinforcing elements are installed perpendicular to the longitudinal axis of the panel with an offset to its inner side. In the second embodiment of the invention, the concrete body of the panel is also made of fiber-reinforced concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, while the transverse framing elements are made of strip, channel or corner in any their combination, and the longitudinal elements of the frame are made of channel. In a third embodiment of the invention, the longitudinal framing elements are made of a rectangular pipe. The invention allows to significantly reduce the metal consumption of panels for bank vaults, safes and armored doors while maintaining their resistance to burglary compared to analogues known from the prior art, so the implementation of the panel according to the first embodiment of the invention allows to reduce metal consumption of the structure by about 20 25% and reduce panel thickness by about 15% with the same cracking resistance class.

Description

The invention relates to special purpose building structures, in particular, panel designs for bank vaults, fireproof safes, armored doors, etc. products.

When developing enclosing structures for special structures, which in particular are bank vaults, exchange offices, storage facilities for museum valuables and securities, safes, etc., there is a problem of creating structures that are highly resistant to breaking, that is, preserving the strength and reliability in various extreme conditions for a certain normalized (depending on the cracking resistance class) time period. Such extreme conditions may be, for example, heat, shock, explosion and / or hacking from outside.

It is known from the prior art to enclose a protected storage room in the form of a monolithic concrete structure dispersedly reinforced with steel fibers, including reinforcing meshes whose cells are offset from each other (RU 2111319, IPC E 05 G 1/024, 05.20.1998). This enclosing structure provides the required class of resistance to breaking, however, the construction of monolithic structures is associated with great labor costs, which include installing formwork, installing in the place of reinforcement, filling it with concrete and compacting concrete using vibrators of various designs, which is very difficult when placing protective cabins or storage of values inside the finished buildings.

A well-known safe wall has double metal walls in which the reinforcement is made in the form of a metal mesh or lattice, and fiber concrete with a filler made of metal fiber randomly located in it (RU 2209287, IPC E 05 G 1/024, 07.27.2003). The safe wall of this design has high resistance to dynamic loads (shock), but at the same time it has high metal consumption.

Known wall of the safe containing fiber-reinforced concrete and reinforcement in the form of profiles (EP 1365096, IPC E 05 G 1/024, 09/01/2005). This design has a low metal consumption, however, it requires the manufacture of special profiles, which increases the complexity and cost of its manufacture. In addition, this design, like the design according to the patent RU 2209287, is intended only for safes and cannot be used to erect the walls of bank vaults without additional design studies, which will lead to an additional increase in the metal consumption and the complexity of manufacturing the structure.

Known panels for storages, safes and doors, containing external, internal and intermediate plates and damping insulation material (RU 2042029, IPC E 05 G 1/024, 08/20/1995). As you know, the construction of valuables from prefabricated panels is more technologically advanced than the monolithic method. However, such panels have a large mass due to the large size and increased percentage of reinforcement, so their movement in the confined space of the finished building presents significant difficulties.

The closest analogue of the present invention is a panel for bank vaults, safes and armored doors, including a metal wall, a metal frame made around the perimeter of the panel, and a concrete reinforced frame in which the longitudinal and transverse frame elements are made of strip,

channel or corner in any combination thereof, while the reinforcing cage contains at least two lattices, the longitudinal and transverse elements of which are welded butt to the framing elements (RU 2240416, IPC E 05 G 1/024, 20.11.2004). This design has high strength due to the spatial rigidity provided by the reinforcing cage, metal walls and framing, which ensures the required breaking resistance class. The disadvantage of this design is the high metal consumption and, consequently, the high cost of manufacture.

The technical task of the present invention is to reduce the metal consumption of the panel while maintaining resistance to cracking.

The problem is solved in the panel for bank vaults, safes and armored doors, including a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements from a strip, channel or corner in any combination thereof, reinforcing elements, butt welded to the framing elements, and concrete a body in which, according to the invention, the concrete body is made of fiber-reinforced concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, and the reinforcing elements are perpendicular but the longitudinal axis of the panel with an offset to the inner side thereof. Reinforcing elements are installed in increments of 150-170 mm.

The panel may additionally contain one reinforcing element mounted longitudinally in the central part of the panel and rigidly connected with transverse reinforcing elements, for example by welding.

The execution of the panel according to the first embodiment of the invention allows, in comparison with the closest analogue (while maintaining the cracking resistance class), to reduce the metal consumption of the structure by about 20-25% and reduce the thickness of the panel by about 15%.

In a second embodiment of the invention, the panel includes a metal frame made along the perimeter of the panel in the form of longitudinal and

transverse elements from a strip, channel or corner, and a concrete body made of fiber concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, while the transverse framing elements are made of strip, channel or a corner in any combination thereof, and the longitudinal elements of the frame are made of a channel.

This design due to the shelves of the channel holding the concrete body along the edges of the panel, eliminates the longitudinal and transverse reinforcement, which further reduces its metal consumption. When performing longitudinal framing elements from a corner or strip, the presence of transverse or transverse and longitudinal (depending on the breaking resistance class) reinforcing elements is mandatory.

In a third embodiment of the invention, the panel includes a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements, and a concrete body made of fiber concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 10-50 mm moreover, the transverse framing elements are made of strip, channel or corner in any combination thereof, and the longitudinal framing elements are made of at least one pipe of rectangular cross section each, while in the wall of the pipe adjacent to the concrete body, This length of the openings.

The pitch of these holes is 50-170 mm, and the diameter of the holes or their width, if the holes are made in the form of slots, correspond to the length of the fiber or exceeds it.

The holes can be offset to the inside of the panel.

The execution of longitudinal elements from a rectangular pipe allows to reduce the metal consumption of the structure by about 50-60%, as well as its weight, since this pipe is thin-walled and therefore it is much lighter than the channel. The presence of holes in the wall of the pipe ensures its reliable fixation due to the fact that the selected dimensions

holes allow fiber concrete to fill the cavity of the pipe. The displacement of the holes to the inner side of the panel creates additional difficulties in case of unauthorized entry (breaking).

Part of the inner cavity of the pipe adjacent to the outer side of the panel, or the entire inner cavity of the pipe, may be filled with burning-resistant material, which can be used as wood or foam concrete. The presence of wood or foam concrete facilitates the construction and creates an additional obstacle to breaking, as it requires a tool change when breaking.

A part of the inner cavity of the pipe adjacent to the inner side of the panel may be filled with a burn-resistant material, the panel containing transverse elements rigidly connected with the longitudinal framing elements, and holes are made in the longitudinal framing elements on the inner side of the panel.

In this case, wood can be used as a burn-resistant material.

These transverse elements can be made of metal strip and are flush with the inside of the panel or in its body.

Each longitudinal element of the frame can be made of two pipes, placed one below the other and rigidly connected to each other, while in the wall of each pipe adjacent to the concrete body, holes are made along the entire length. This design allows the use of finished pipes of various sizes to obtain a panel of a given thickness, which significantly reduces the complexity of manufacturing.

The hole pitch is 50-170 mm, and the diameter of the holes or their width corresponds to the length of the fiber.

Pipes forming a longitudinal framing element can be displaced relative to each other with the formation of a protrusion on the side surface of the panel.

The presence of two pipes installed with an offset allows you to create a vestibule, in the case of using the panel as an armored door, or to obtain a panel with symmetrical or asymmetric protrusions on the side surfaces. The presence of protrusions on the side surfaces of the panel allows you to dock the panel without additional overlays, which reduces the metal consumption of the wall as a whole.

The invention is illustrated by examples of its implementation with reference to the accompanying drawings, which show the following.

Figure 1 - panel, made according to the first embodiment of the invention, a top view (fiber concrete is not shown).

Figure 2 is the same, section aa.

Figure 3 is the same, section bB.

4 is a panel made according to the second variant of the invention, a cross section.

5 is a cross-sectional view of a panel made in accordance with a third embodiment of the invention.

6 is a frame element in the form of a pipe, a perspective view.

7 is the same, with holes in the form of slots.

Fig - panel with longitudinal elements of two pipes, a cross section.

Fig.9 is the same with a symmetric displacement of the pipes.

Figure 10 is the same with asymmetric displacement of the pipes.

11 is a panel in which a part of the inner cavity of the pipe adjacent to the inner side of the panel is filled with burning material, a cross section.

12 is the same with transverse elements flush with the inner surface of the panel.

Fig - the same, with transverse elements located in the concrete body of the panel.

In the first embodiment (Figs. 1-3), the panel for bank vaults, safes and armored doors includes a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements from strip 1, channel 2 or corner 3 in any combination, reinforcing elements 4, 5, butt-welded to the framing elements at points 6, and a concrete body. The concrete body of the panel in all variants is made of fiber-reinforced concrete 7, containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm. Reinforcing elements 4 are made of reinforcing bars and are installed with a pitch of 150-170 mm perpendicular to the longitudinal axis of the panel with an offset to its inner side 8. The choice of concrete class and fiber parameters depend on a given cracking resistance class and specific conditions of the storage construction.

The panel may contain one reinforcing element 5 mounted longitudinally in the Central part of the panel and rigidly connected with the transverse reinforcing elements 4.

The panel made according to the second embodiment (figure 4) includes a metal frame made around the perimeter of the panel in the form of longitudinal and transverse elements from a strip, channel or corner, and a similar concrete body. In this case, the transverse framing elements are made of strip, channel or corner in any combination thereof, and the longitudinal framing elements are made of channel 2.

In the third embodiment (FIGS. 5-10), the panel includes a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements, and a concrete body. In this embodiment, the transverse framing elements are made of strip, channel or corner in any combination thereof, and each longitudinal framing element is made of rectangular pipe 9.

The part of the inner cavity of the pipe 9 adjacent to the outer side 10 of the panel may be filled with burning material 11,

for example a tree. The entire internal cavity of the pipe 9 can be filled with wood or foam concrete (not shown).

In the wall of the pipe 9 adjacent to the concrete body, either round holes 12 or rectangular holes (in the form of slots) 13 are made along the entire length.

The step b of the holes 12, 13 is 50-170 mm, and the diameter d of the holes or the width 1 correspond to the length of the fiber. The size of the holes 12, 13 is chosen equal to the length of the fiber or slightly larger so that the fiber concrete 7 can fill the inner cavity of the pipe 9 during molding of the panel. The holes 12, 13 can be shifted to the inner side 8 of the panel, as shown in FIG. 5.

Each longitudinal element of the frame can be made of two pipes 9, placed one below the other and welded together. In the wall of each pipe 9 adjacent to the concrete body, holes 12, 13, similar to those described above, are made along the entire length.

Pipes 9, forming a longitudinal element of the frame, can be offset relative to each other symmetrically (Fig.9) or asymmetrically (Fig.10) with the formation of a protrusion on the side surface of the panel. The presence of the protrusion allows you to dock the panels with each other without additional overlays.

The part of the inner cavity of the pipe 9 adjacent to the inner side 8 of the panel may be filled with burning material 11 (Figs. 11-13), the panel containing transverse elements 14, which are rigidly connected with the longitudinal elements of the frame, and in the longitudinal elements of the frame with the inside of the panel has holes 15 for securing the panels to each other by means of plates and screws (not shown).

In this case, wood or foam concrete may be used as a burn-resistant material 11.

These transverse elements 14 can be made of metal strip and are flush with the inner side 8 of the panel or in the concrete body of the panel.

The invention allows to significantly reduce the metal consumption of panels for bank vaults, safes and armored doors while maintaining their resistance to hacking in comparison with analogues known from the prior art.

Claims (21)

1. The panel for bank vaults, safes and armored doors, including a metal frame made around the perimeter of the panel in the form of longitudinal and transverse elements from a strip, channel or corner in any combination thereof, reinforcing elements welded butt to the frame elements, and a concrete body, characterized in that the concrete body is made of fiber-reinforced concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, while the reinforcing elements are installed perpendicular to the longitudinal axis of the panel with offset view to her inner side. 2. The panel according to claim 1, characterized in that the reinforcing elements are installed in increments of 150-170 mm. 3. The panel according to claim 1 or 2, characterized in that one reinforcing element is installed longitudinally in the Central part of the panel and is rigidly connected with the transverse reinforcing elements. 4. The panel for bank vaults, safes and armored doors, including a metal frame made along the perimeter of the panel in the form of longitudinal and transverse elements from a strip, channel or corner, and a concrete body, characterized in that the concrete body is made of fiber-reinforced concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 200-10 mm, while the transverse framing elements are made of strip, channel or corner in any combination thereof, and the longitudinal framing elements are made of channel. 5. The panel for bank vaults, safes and armored doors, including a metal frame made around the perimeter of the panel in the form of longitudinal and transverse elements, and a concrete body, characterized in that the concrete body is made of fiber concrete containing concrete of class B60-B90 and metal fiber with a diameter of 0.2-1 mm and a length of 10-50 mm, the transverse framing elements are made of strip, channel or corner in any combination thereof, and the longitudinal framing elements are made of at least one pipe of rectangular cross section each. 6. The panel according to claim 5, characterized in that in the wall of the pipe adjacent to the concrete body, holes are made along the entire length. 7. The panel according to claim 6, characterized in that the hole pitch is 50-170 mm, and the diameter of the holes or their width corresponds to the length of the fiber. 8. The panel according to claim 6 or 7, characterized in that said holes are offset to the inside of the panel. 9. The panel according to claim 6, characterized in that the part of the inner cavity of the pipe adjacent to the outer side of the panel is filled with burning material. 10. The panel according to claim 9, characterized in that a tree is used as a material resistant to burning. 11. The panel according to claim 6, characterized in that the part of the inner cavity of the pipe adjacent to the inner side of the panel is filled with burning material, while it contains transverse elements rigidly connected with the longitudinal elements of the frame, and in the longitudinal elements of the frame with the inner the sides of the panel are made holes. 12. The panel according to claim 11, characterized in that a tree is used as a material resistant to burning. 13. The panel according to claim 11, characterized in that said transverse elements are made of strip and are flush with the inside of the panel. 14. The panel according to claim 11, characterized in that said transverse elements are made of strip and are located in the panel body. 15. The panel according to claim 5, characterized in that the inner cavity of the pipe is filled with a material resistant to burning, while it contains transverse elements rigidly connected with the longitudinal elements of the frame. 16. The panel according to clause 15, characterized in that as a material resistant to burning, wood or foam concrete is used. 17. The panel of claim 15, wherein said transverse elements are made of strip and are flush with the inside of the panel. 18. The panel of claim 15, wherein said transverse elements are made of strip and are located in the body of the panel. 19. The panel according to claim 5, characterized in that each longitudinal element of the frame is made of two pipes, placed one below the other and rigidly connected to each other, while in the wall of each pipe adjacent to the concrete body, holes are made along the entire length. 20. The panel according to claim 19, characterized in that the hole pitch is 50-170 mm, and the diameter of the holes or their width corresponds to the length of the fiber. 21. The panel according to claim 19 or 20, characterized in that the pipes forming the longitudinal framing element are offset from each other with the formation of a protrusion on the side surface of the panel.