RU2560444C2 - Heat protective armour layered system - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to the means of protecting equipment against high temperatures, radiation, destructive force and concerns heat protective armour layered system. The system comprises interconnected frame, strengthened, heat insulating and additionally composite layers. The strengthened layers are made from ceramic material based on carbides, mainly boron, or titanium, or silicon, or their borides, or aluminium oxide, or mixtures thereof. The frame layers are made from metals or alloys based on titanium, aluminium, iron. The heat insulating layer is made from inorganic compounds from the group of silicides or silicates, and an additional cushion layer of UHMWPE. All the system layers are interconnected by a high-temperature organosilicon or silicate adhesive. The layered system is limited across the outer surface with layers of composite material on the basis of woven carbon or silicon-containing fibres, the layers being interconnected by the said adhesive.

EFFECT: ensuring simultaneous protection of a facility against both heat flow, radiation and a destructive force due to increasing the mechanical strength of the system and heat and radiation protection parameters.

1 tbl, 1 dwg, 1 ex

Description

The present invention relates to the field of means for protecting equipment from exposure to high temperatures (including open flame) and radiation, a damaging factor and can be used in the chemical, nuclear and other fields of science and technology.

Known protective layered system containing strength, heat-insulating layers made of materials, respectively (RF patent No. 2194683, C04B 35/573, publ. 09.01.2001, BI No. 1/2001).

The disadvantages of the analogue include the lack of the ability to provide protection simultaneously from high-temperature heat flux (or open flame) and from damaging mechanical factor, because the materials used in the known system do not meet the requirements of increased mechanical and thermal strength required for objects of increased sensitivity to these factors.

As the closest to the claimed known protective layered system (RF patent No. 2355991, IPC F41H 5/04, publ. December 27, 2008).

The disadvantages of the prototype include the lack of the ability to provide protection simultaneously from heat flux, radiation exposure and from damaging mechanical factor.

The task of the authors of the invention is to develop the design of a heat-resistant laminated system that meets the requirements of increased radiation protection and heat resistance, imposed on objects of increased sensitivity to these factors (containers with flammable materials and liquids, explosive materials).

A new technical result achieved by using the proposed protective layered system is to provide the ability to protect the protected object from exposure at the same time from heat flux, radiation exposure and from the destructive element by increasing the damping properties of the system and the radiation and thermal protection indicators.

These tasks and new technical results are achieved by the fact that, in contrast to the known heat-resistant laminated system containing interconnected frame, hardened and heat-insulating layers, in accordance with the proposed heat-resistant laminated system, it contains hardened ceramic materials, mainly boron, in the form of hardened layers , or titanium, or silicon, or aluminum oxide, or mixtures thereof, as a frame layer, metals or alloys based on titanium, aluminum, iron, and as eploizoliruyuschego layer - inorganic compounds from the group of silicates and silicides or further cushion layer of high molecular weight polyethylene, all layers of the system are interconnected by high-temperature silicone or silicate adhesive layered system is limited by the entire outer surface a layer of carbon fabric or glass fabric impregnated with said adhesive.

The proposed heat-resistant system is illustrated as follows.

Initially, the inner layers adjacent to the object of protection are prepared, which are characterized by the lowest thermal conductivity, for which they are cut from solid pieces of solid composites (composites based on liquid glass, fillers from glass fiber, basalt sheet, carbon fiber, etc.), and an additional shock-absorbing layer of high molecular weight polyethylene, which are installed in the gap between the object of protection and the inner surface of the main metal body.

Then, an adhesive composition is applied to the main metal body, carbon fabric is applied and curing is carried out. Then put another layer of adhesive composition, on which armored ceramic tiles are installed. These operations are repeated until the required dimensions are achieved. Layers of fabric impregnated with adhesive are applied to the resulting assembly with an interference fit, after which the entire system is cured. Outside, the assembly is limited by a protective casing of composite material.

A protective casing made of a composite material consisting of alternating metal-carbon fabric layers is collected separately, then the resulting assembly and the protected object are placed.

As a protected object (Fig. 1.1), sensitive to high temperatures, damaging factors (mechanical moving objects or shrapnel elements) and open fire, a polymer material was tested, characterized by increased fire and explosion hazard, which is placed in a protective casing aggressive agents - water, acids, alkalis, sea water, etc.

In the protective casing with respect to the object, there is a shock-absorbing layer (lining), a thermal protection layer made of heat-insulating material (such as carbon felt, silica fiber, fiberglass, etc.), then a metal layer (aluminum alloy, titanium as a mechanically strong frame layer) alloys), on which layers of the composite are layered (their number is selected depending on the task), which is carbon fabric layers impregnated with adhesive on a silicate binder (TPK glue), followed by a layer of cer omy.

The effectiveness of the use of such a combination of layers to improve physical and mechanical properties was confirmed by experiments.

These layers to obtain the finished layered system are connected with an adhesive, which is used as a boron-containing composition, in the form of a package is placed in a mold and subjected to hot pressing.

The heat-resistant bronze laminated system, assembled in the above manner, is the most optimal in terms of the manifestation of the protective function in tests for radiation exposure and the influence of a damaging factor. This is due to the fact that the deforming load acting on the composite casing is extinguished during the transition from layer to layer, sequentially distributed in them towards the protected object in accordance with the functionality of each layer.

It was established by experimental studies that the deforming factor in the direction of its influence on the protected first meets the metal (frame) layer of the system, behind which the above layers are placed - ceramic (hardened) and heat-insulating layers, which also manifest themselves as damping layers. The indicated layers in the composition of the heat-protective system operate in different directions at the same time. In this case, the metal layer shields the inner layers from the deforming effect of the damaging factor, and perceives the first mechanical damage, including loads during loading and unloading, during operation. The ceramic layer together with a composite layer of heat-resistant fibrous material (basalt fibers, glass fibers) and high-temperature glue TPK protects the object under prolonged exposure to high temperatures (from 30 minutes to 1 hour) and together with the inner layers provide a temperature drop to the level of acceptable, non-critical for an object characterized by increased fire and explosion hazard.

The system of layers of the protective casing provides both protection from the thermal factor (open flame and high temperature) and from the mechanical damaging factor - for example, a fast-flying fragment or a metal indenter. The increase in the mechanical strength of the protective system is ensured by the presence of both a metal and a ceramic layer, reliably interconnected by a high-temperature and mechanically strong layer of composite adhesive. At the same time, materials as a skeleton layer selected from the group of metals such as aluminum, titanium, iron or their alloys optimally meet the high requirements for mechanical strength. And from ceramic materials, compounds based on carbides, mainly boron, or titanium, or silicon, or their borides, or nitrides, or aluminum oxide are optimally shown. In this case, the property of increased resistance of the layered system to both open flame and elevated temperatures is manifested. the melting temperature of these materials is much higher than the temperature conditions of operation of the protected object.

In FIG. 1 shows a cross section of a layered casing with a protection object placed in it 1, 2 - heat-insulating layers, 3 - reinforcing metal layer, 4, 6 - composite (carbon fabric), 5 - ceramic layer, 7 - outer frame layer. The reinforcing metal and ceramic layers jointly manifest themselves functionally as absorbers of the kinetic energy of the mechanical destructive factor (indenter), and the frame layer is functionally the holder of the layered frame assembly.

In addition, the use of composite layers in the composition of the proposed armored laminated system instead of the heavy-weight strength layers present in the prototype, significantly reduces the weight of the finished product.

An additional technical result - an increase in heat-shielding properties - is ensured by the fact that both powdered and fibrous materials based on silicates and silicides are characterized by increased porosity and the presence of an air component, which contributes to a significant reduction in their thermal conductivity.

An additional technical result of increasing the assembly strength of the protective system is provided by the use of a high-temperature adhesive - TPK glue, which interconnects all layers in the composite, thereby increasing the reliability of the assembly of the layer system and, in general, its high heat resistance. This significantly increases the mechanical strength and thermal strength when exposed to temperature peaks (1000 ° C)

In the prototype, a combination of high heat resistance and radiation protection was not noted due to the lack of the required combination of thermo and radiation protective layers and an agent for their connection. On this basis, the advantages of the proposed armored system is higher than that of the prototype.

Thus, the use of the proposed heat-resistant layered system provides the ability to protect the protected object from exposure simultaneously from the heat flux and from the destructive factor by increasing the radiation protection of the system, thermal protection indicators while simultaneously maintaining the mechanical strength of the finished product.

The possibility of industrial implementation of the invention is confirmed by the following examples.

Example 1

Experimentally, the proposed heat-resistant laminated system was obtained according to the following technological scheme (Fig. 1), which shows the sequence of operations.

Initially, a protective casing is assembled, made of a composite material consisting of layers, into which the protected object is then placed.

As a protected object (1) that is sensitive to high temperatures, damaging mechanical factors and open fire, we took an object (part) from a flammable polymer, which is placed in a protective laminated casing of the system.

In the protective casing, the first layer with respect to the object of protection is made of a heat-insulating material - Carbopon carbon felt, then a metal layer based on aluminum alloy is installed on this layer as a mechanically strong layer, onto which 3 layers of a composite representing carbon fiber layers are layered, impregnated with adhesive on a silicate binder (in the conditions of the example, TPK-2 adhesive), followed by a ceramic layer in the form of a tile (in the conditions of this example, silicon carbide tiles). Heat-resistant adhesive TPK-2 is applied to the tiles, on which carbon fabric is wound with a specified tension (TGN-2 M fabric brand, TU) impregnated with high-temperature adhesive (silicate-based adhesive - TPK-2 brand). Then, a binder is introduced into the space between the object and the casing, which in the conditions of this example is cured simultaneously with the protected object placed inside. The protective casing, made in the above manner, is sent to the control tests, the data for which are summarized in table 1.

The tests were carried out in the laboratory under the influence of a striking element of small arms in combination with open fire, during which the resulting design withstood the test for 10 minutes.

As experiments have shown, the use of the proposed heat-resistant system provides the ability to protect the protected object from exposure at the same time from the heat flux, radiation exposure and from the destructive factor by increasing the mechanical strength of the system and improving thermal protection while reducing the weight of the finished product.

Claims (1)

A heat-resistant laminar system containing installed in a protective casing and interconnected frame, hardened and heat-insulating layers, characterized in that as hardened layers it contains ceramic material based on carbides, mainly boron, or titanium, or silicon, or aluminum oxide, or mixtures thereof, metals or alloys based on titanium, aluminum, iron as a frame layer, and fibrous materials based on inorganic compounds from the group of silicides as a heat-insulating layer of silicates and an additional shock-absorbing layer of ultra-high molecular weight polyethylene, all layers of the system are interconnected by a high-temperature organosilicon or silicate adhesive, the layered system is bounded on the entire outer surface by layers of carbon fabric or fiberglass impregnated with the specified adhesive, and is enclosed in a housing made of composite material.

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