RU53699U1 - MULTILAYER PROTECTIVE PANEL - Google Patents

Abstract

This utility model relates to the design of bank safeguards to ensure safety when using means of influence on a bank object of protection.

The multilayer structure of the protective panel consists of alternating layers of metal and inorganic material of high hardness and wear resistance, interconnected by adhesives based on the organic composition and metal channels located along its perimeter. In addition, the multilayer structure can be enhanced by the application of transverse reinforcing elements.

Effect: increase the resistance of the protective panel against impact-cutting effects.

Description

This utility model relates to the design of bank safeguards to ensure safety when using means of influence on a bank object of protection. These include: (bank protective) barrier: Bulletproof, bank protective means firmly fixed at the installation site, designed to ensure the safety of bank personnel, security personnel and preventing free passage, (bank protective) fencing: Burglary resistant, bulletproof bank protective means designed to prevent unauthorized access to the territory of the bank and to ensure the safety of the bank object of protection, (bank protective) barrier: Design element and banking protective equipment, which, depending on the functional purpose, provides resistance to burglary, bulletproof, fireproofing or possesses these properties in combination, (bank protective) door: A bank protective means that is resistant to regulated means of exposure and allows opening and closing of the opening in a bank protective barrier , (bank security) blinds: Burglar-resistant, bulletproof banking security device containing devices for controlling the movement of polo tna along the opening in the barrier and designed to ensure the safety of the bank object of protection, (bank) protective booth: Bulletproof and (or) burglar-resistant bank protective device, which includes a door and a transmission unit having the necessary technical equipment and intended for to ensure the safety of personnel, operations with banking values, safe: Resistant to breaking and (or) fireproof banking protective equipment with a base area inside for a maximum of 2 m ² , intended for storing bank valuables, bank (protective) stand: Bulletproof bank protective equipment containing a transfer unit, designed to ensure the safety of personnel and transactions with bank valuables, bank valuables: Resistant to breaking, fireproof banking a protective agent with a base area of more than 2 m ² inside, designed to store bank values. In accordance with clause 3.13 of GOST R 50862-96 burglary resistance: the ability of a safe or vault to withstand hacking, expressed using quantitative characteristics. In other words, this parameter reflects the ability of the banking

Resist protective equipment against various tools: hand, electric, thermal, welding, etc. for a certain time. Along with the characteristics of bank protective equipment, some of them, such as a bank protective barrier, a bank protective booth, etc., must have some resistance to breaking, should provide protection against firearms: from a Makarov PM pistol, TT Tokarev pistol, AKM Kalashnikov assault rifle and other

Bank safeguards are widely known as structures that combine metal and wood-based materials. For example: a multilayer structure of steel sheets and plywood sheets that can be glued to each other or mechanically attached to each other. Such designs are widely used as bank security products with a certain resistance to cracking. For example, the specific gravity of the panel of the second class of resistance to evil in accordance with GOST R 50862-96 (Safes and storages of values requirements and test methods for resistance to breaking and fire resistance) and GOST R 51113-97 (bank protective means for cracking resistance and testing methods) made of steel and wood is about 120-130 kg. / square meter and a thickness of about 50 mm. For the destruction of panels of this structure, mainly thermal cutting, manual and manual electric tools are successively applied. A steel sheet is cut with an acetylene-oxygen cutter, then plywood is cut with an electric tool and fragments of the panel are removed with a hand tool. This circumstance is a great disadvantage of the protective functions of such structures.

The objective of this utility model is to increase the resistance of the protective panel against impact-cutting impacts.

The basis of the design of this, utility model is a multilayer composite structure (Figure 1), where 1 - metal layers, 2 - layers of organic materials, 3 - layers of inorganic materials, 4 - metal channel. The design includes metallic, inorganic and organic materials. As metals (1), low-carbon steel sheets, stainless steel sheets, aluminum or its alloy sheets, copper sheets or sheets based on copper alloys can be used.

As organic materials (2), adhesive compositions based on polyurethane, epoxy, acrylic, and silicone compositions can be used.

As inorganic materials (3), sheets of glass (including triplex), liquid-glass mixtures (compositions based on quartz sand, liquid glass, cured with carbon dioxide) can be used.

Sealing and strengthening of the structure is performed by metal channel (4). The channel data prevents the delamination of the panel under force.

In order to increase the burglar-resistant parameters, the composite structure can be strengthened by applying transverse reinforcing elements (see Figure 2, where 5 are reinforcing elements). These elements provide additional hardening and fixation of the layers relative to each other.

As reinforcing elements (5), rivets, electrical rivets, threaded joints, dowels and nails can be used.

The advantages of the proposed design of the utility model are that it has improved cracking resistance, high bullet resistance and low specific gravity relative to analogues.

For example, consider the following construction of a utility model:

A low-carbon steel sheet is used as the metal layer (1), a polyurethane composition is used as organic materials (2), and an inorganic glass sheet is used as inorganic material (3). The advantages of this model are expressed in the following.

In that case, if you try to cut the outer steel sheet with an acetylene-oxygen cutting tool, the cutting process will be substantially (3-4 times longer with respect to cutting an un glued sheet, or a steel sheet bonded to wood-based material. To intensify the thermal cutting process, preliminary destruction of glass with a hand tool (hammers, sledgehammers, etc.), which requires additional time.

The cut out fragment of the steel sheet due to the use of the organic adhesive composition has high adhesion to the panel. To remove it requires the use of a manual lever tool such as scrap.

Before thermal cutting of the second steel sheet, it is required to clean its surface from the polyurethane composition and glass fragments using a hand tool such as chisels and a percussion hand tool such as hammers.

Next, thermal cutting of the steel sheet, removal of the cut out fragment, surface cleaning from the polyurethane composition and glass fragments, and thermal cutting of the third steel sheet are performed. In the event that the design used

transverse reinforcing elements, there is a need to destroy and remove these elements using various tools, which increases the time and work on the hacking panel.

If you use a different scheme and destroy the panel using an electric cutting grinding tool, the time is longer than using a thermal cutting tool. This is because there are no abrasive wheels that cut steel and glass well. The difference in the physicomechanical properties of these materials leads to the need for sequential cutting of steel with circles for cutting steels, and glass with circles for cutting glass (mainly diamond). The use of glass in the construction leads to a decrease in specific gravity. The weight reduction is due to the fact that the glass has a specific gravity of 2.5 grams / centimeter cubic, and steel 7.81 grams / centimeter cubic.

Due to this combination of materials with heterogeneous properties, it is possible to obtain panels of the second class of resistance to cracking (GOST R 51113-97) and the second class of protection for bullet resistance (GOST R 51112-97) with a thickness of about 12 mm. with a specific gravity of about 50 kg / square meter.

Claims (2)

1. A multilayer protective panel, characterized in that its multilayer structure consists of alternating layers of metal and inorganic material of high hardness and wear resistance, interconnected by adhesives based on an organic composition and metal channels located around its perimeter. 2. The protective panel according to claim 1, characterized in that the multilayer structure is reinforced by the application of transverse reinforcing elements.