RU15444U1 - LAYERED STRUCTURE AND PROTECTIVE HOUSING FROM IT - Google Patents

Description

LAYERED STRUCTURE AND PROTECTIVE HOUSING FROM IT

The utility model relates to means of protecting the internal volumes of buildings for various purposes from the effects of adverse environmental conditions, including high temperatures, shock loads, static pressure, etc., which usually occur in emergency situations, and can be used, for example, for the design of on-board equipment of vehicles (aircraft, locomotives, ships, cars), in particular, on-board storage devices (black boxes), as well as in the production of high the temperature of safes, cases, during the construction of refractory partitions of buildings, etc.

A device is known for protecting microelectronic equipment from overheating, in which the working volume of the sealed container is partially filled with dielectric liquid, circuit boards with semiconductor crystals are installed in the working volume in parallel planes above the level of the dielectric liquid, and the capacitor is made in the form of a hollow cover and hollow upper parts of the side walls a sealed container, and their cavities are interconnected and connected to the coolant supply and circulation system (see Patent RF N 2042294, H 05 K 7/20, H 01 L 25/04, 1995.). After the heaters are turned on, the dielectric liquid boils, its vapors condense on the walls of the condenser and a liquid film forms there, which flows down the vertical walls of the container, cooling the semiconductor crystals and partially evaporating on them. This method of protection against overheating is based on cooling the device due to condensation of the liquid on the walls of the working volume. However, to carry out this process, the coolant is supplied to the device using a pipeline. This significantly affects the dimensions of the device and complicates its design, and also requires the stationary installation of the container, which makes such thermal protection ineffective, for example, for use in vehicles.

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Known multilayer thermal insulation for apparatuses and pipelines according to the patent of the Russian Federation N 2016348, F 16 L 59/00, made in the form of a volumetric package of the base and alternating layers of discrete heat-insulating elements arranged in a layer in which the layers of the base are made of alternating layers of fiberglass, stitched pairwise parallel seams in intersecting directions, and metal foil, and the insulating elements are made of highly porous ceramic. However, such multilayer thermal insulation can provide thermal protection of equipment at a temperature of no higher than 200-700 ° C, which is completely insufficient for the emergency situations mentioned above.

There is also a method of protecting existing electronic equipment from environmental influences, namely, that the board with the specified equipment is installed in a case (housing) that contains at least two layers of tear-resistant plastic located on opposite sides of the metal barrier, after which the board is sealed inside the specified case. In this case, the casing is made in the form of a sandwich type construction, i.e. multilayer, in which each of the layers of plastic, in turn, contains the outer and inner layers, the first of which is made of polyethylene, and the second of polyamide or polyester, and the material of the metal barrier is selected from the group consisting of aluminum, tin and alloys including aluminum and / or tin (see RF application for invention N 96121569/09, H 05 K 5/06, 1999). However, the use of such a protective cover (case) cannot provide thermal protection of electronic components at elevated ambient temperatures, for example, up to 1100 ° C in emergency situations, since the material of the outer and inner layers (polyethylene, polyamide) has a melting point of no higher than 200 ° C, and the melting points of aluminum and tin are, respectively, 600 ° and 232 ° C, that is, the destruction of the specified cover will occur in the first minutes of the fire.

The closest in technical essence to the claimed is a device for environmental protection of on-board information storage devices MSRP-1296, MSRP-64-2 and MSRP-256 installed on aircraft (see, for example, Mikhailov OI and others. Aviation Instruments and flight-navigation systems (Leningrad, OLAGA, 1990, pp. 54-56), according to which an emergency information storage device (magnetic recording device) is installed in a heat-shielding device

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a container of a layered structure having three shells: heat-shock resistant, a shell that absorbs thermal energy, and heat-insulating. Both last shells are passive thermal protection, i.e. allow you to gradually reduce the temperature due to low thermal conductivity over a relatively short time.

The presence of these shells in a ball container ensures the safety of recording information when exposed to shock overload up to 1000 g and heat stroke up to 1100 ° C for 15 minutes. The temperature inside the container with this method of protection reaches 250 ° C. However, this method of protection is ineffective for solid-state on-board storage devices used in recent years for which this temperature is too high. In addition, the protective case for the information storage device must meet the requirements to withstand temperatures up to 1100 ° C for 30 minutes on 100% of its surface and shock loads up to 3400 g. The specified method using only passive thermal protection is also ineffective for preserving from the effects of high temperatures business papers and banknotes inside cases, safes and other volumes.

The utility model solves the problem of increasing the efficiency of protecting internal volumes of various purposes from environmental influences, especially from high temperatures, by using materials that ensure that the internal volume maintains a constant set temperature for a given time.

To do this, in a layered structure containing at least three layers in series, of which the outer layer is made of impact-resistant, the intermediate layer is made of dry refractory porous-fibrous material, and the inner layer is made of the same porous-fibrous material impregnated with a water-containing component, or from water-containing gel. In this case, the intermediate layer is made of thermal insulation material based on mineral fiber, and the inner layer is made of porous fiber material, impregnated with water or a water-containing gel. The outer layer of the layered structure is made of metal or composite material, and the inner layer on both sides is additionally provided with a protective sheath of polymer film material.

A protective casing of a layered structure comprising an external casing formed from an outer layer and at least two layers of thermal protection placed inside it, the outer casing being shockproof and fireproof, characterized in that the intermediate layer is made of dry refractory porous fiber material and the inner one the layer is made of the same porous-fibrous material impregnated with a water-containing component, or a water-containing gel. In this case, the intermediate layer is made of thermal insulation material based on mineral fiber, and the inner layer is made of porous fiber material, impregnated with water or a water-containing gel. The outer layer of the protective casing is made of metal, and the inner layer on both sides is additionally provided with a protective sheath of polymer film material.

The protective housing may be provided with an additional housing of a layered structure of a similar structure, placed inside the main body.

The essence of the utility model consists in the joint use of layers of refractory heat-insulating material that is dry and soaked in a water-containing component. Dry thermal insulation material due to low thermal conductivity allows you to gradually reduce the ambient temperature in an emergency to a certain value. Filled with water or an aqueous gel held in the pores of the material by capillary forces, this material serves as a kind of reservoir containing water, boiling of which, as you know, is accompanied by maintaining a constant temperature of 100 ° C. With a unidirectional heat flow acting on the protected object, the boiling of water in the material occurs in a thin layer, and not in the entire mass. In this case, the layer of material freed up after evaporation of the liquid begins to perform the function of additional thermal insulation, preventing the penetration of heat into the interior, thereby slowing down the boiling process and increasing the time to maintain a constant temperature necessary to maintain the protected object, in particular, on-board storage devices.

The utility model is illustrated by drawings, in which Fig. 1 shows a schematic layered structure for implementing a thermal protection method; figure 2 - construction of a protective housing of a layered structure for placement in it, for example, a solid-state on-board storage device.

A layered structure consisting of at least three successive layers is arranged around the inner volume 1, intended to accommodate the protected object, and is formed as a protective barrier 2 made of the outer layer 3 to protect against shock loads and direct fire, on the inner surface of which an intermediate layer 4 of dry refractory heat-insulating material is placed, providing primary (passive) thermal protection, and then the inner layer 5 of t of the insulation material, but impregnated with a water-containing component, and providing a secondary, so-called active thermal protection.

Depending on the scope and type of the protected object, the protective barrier 2 is formed in the form of a housing of the desired configuration and size, partition or wall.

The outer layer 3 of the layered structure is made of heat-resistant shockproof materials, for example, metals (titanium or its alloys, aluminum or its alloys, steel, etc.) or composite materials on a metal or non-metallic basis (reinforced glass, fiberglass, ceramics).

The intermediate layer 4 is made of a dry refractory porous-fibrous material, for example, a thermal insulation material based on mineral (mullite-siliceous) fiber according to the patent of the Russian Federation N 2127712, С 04 В 28/24, 1999, which has high refractory properties (as the studies showed, the material is not changes its properties to temperatures of 1300 ° C), low thermal conductivity and high porosity of the material, which is approximately 92% of the total volume. Other refractory porous-fibrous material, for example, highly porous ceramics, can also be used.

The inner layer 5 of the layered structure is placed on the inner side of the layer 4 and is formed from the same porous-fibrous material as layer 4, but saturated with a water-containing component to a moisture content of at least 80 - 85% of its volume (the percentage of moisture is determined by the process technology saturation of porous fiber material). As the water-containing component used water or water-containing gels obtained on the basis of water-soluble polymers of plant and animal origin, or synthetic, for example, based on a copolymer of acrylic acid allyl ether and pentaerythritol, or polyacrylamide.

To prevent premature evaporation of water, layer 5 is enclosed in a protective shell 6, on both sides it covers layer 5. Shell 6 can be made of a polymer film material, for example, polyethylene, which is the most heat-resistant of all hydrocarbon polymers, without additional coating or metallized . In the latter case, the shell 6 will also perform the function of a screen reflecting the heat flux.

As a manufacturing option, the layer 5 can also be formed directly from a water-containing gel of a thicker consistency, placed in a protective shell 6.

The protective housing, according to a utility model, comprises an external housing formed from an outer layer 3 of a layered structure, on the inner surface of which, for example, using refractory glue, an intermediate layer 4 made of dry refractory porous-fibrous material is placed one after the other, and an inner layer 5 of the same refractory porous-fibrous material, but saturated with a water-containing component and enclosed in a protective sheath 6 from a metallized plastic film or from a plastic film ithout coating. A sealed container 7 is installed on the inner side of layer 5, covering the protected volume on all sides, in which a solid-state on-board data storage chip or other recording device can be fixed. The container 7 allows you to protect the stored object from the influence of the process of vaporization.

To increase the efficiency of thermal protection, the protective casing can be additionally equipped with a second layered structure located inside the first and having a similar structure, i.e. comprising an outer layer 8 made, for example, of stainless steel, in the form of an intermediate container, and a layer 9 of dry heat-insulating material and an inner layer 10 of water-saturated heat-insulating material located inside the protective shell 11 located inside it. In this case, the sealed container 7 is installed inside the second layered structure.

At the time of the emergency, the external housing 3 of the device protects the object enclosed inside it from mechanical damage and shock loads. At the same time, it is exposed to fire, the temperature of which can reach more than 1100 ° C on 100% of its surface. Speed and

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The heating temperature of the housing in this case depends on its mass and the material from which it is made. With further exposure to the heat flux, the layer 4 of the dry heat-insulating material is gradually heated due to its low thermal conductivity. At the same time, the temperature of layer 5 of water-saturated heat-insulating material rises to a critical temperature at which the process of vaporization begins, the temperature in the active layer is set to 100 ° C and remains stable until the entire liquid phase is consumed. The layer of material released after evaporation of the liquid begins to perform the function of thermal insulation, preventing the penetration of heat into the body. If the thermal effect continues, through the heated outer layer 8 of the second layered structure, the layer 9 of dry heat-insulating material begins to warm up, and when its temperature reaches a critical level, the process of vaporization in the inner layer 10 of water-saturated heat-insulating material begins similarly to the same process in the first layered structure. The use of a multilayer structure, i.e. the repetition of the passive and active layers, allows for a uniform course of the evaporation process.

Thus, the claimed thermal protection using a layered structure of a certain structure, including successively placed layers of porous fiber material, dry and impregnated with a water-containing component, provides an increase in the efficiency of protecting internal volumes of various purposes from high temperatures for a specified time, allowing to eliminate the emergency. A protective housing made of a layered structure, intended for use mainly on various vehicles, allows you to most effectively protect on-board storage devices from the effects of adverse environmental conditions (fire, shock loads and static overloads) and thereby save the data recorded in them as much as possible. A timely identification of the moment and cause of an emergency in transport will prevent the recurrence of accidents related to technical malfunctions, which will increase transport safety and give an economic effect due to the conservation of material resources. In addition, such a protective case can be used to preserve securities in case of fire, since the temperature inside the protected volume is significantly lower than the combustion temperature

paper. To implement thermal protection, environmentally friendly non-combustible materials are used, which will allow in case of fire in buildings and structures not only to prevent the penetration of fire into adjacent rooms, but also to save human lives.

Claims (15)

1. A layered structure containing at least three layers in series, of which the outer layer is made of impact-resistant, characterized in that the intermediate layer is made of dry refractory porous fiber material, and the inner layer of the same porous fiber material impregnated water-containing component, or from a water-containing gel.  2. The layered structure according to claim 1, characterized in that the intermediate layer is made of thermal insulation material based on mineral fibers.  3. The layered structure according to claim 1, characterized in that the inner layer is made of a porous fiber material impregnated with water.  4. The layered structure according to claim 1, characterized in that the inner layer is made of a porous-fibrous material impregnated with a water-containing gel.  5. The layered structure according to claim 1, characterized in that the outer layer is made of heat-resistant metals or composite materials.  6. The layered structure according to claim 1, characterized in that the inner layer on both sides is further provided with a protective sheath.  7. The layered structure according to claims 1 to 6, characterized in that the protective sheath is made of a polymer film material.  8. A protective casing of a layered structure, comprising an outer casing formed from the outer layer and at least two layers of thermal protection placed inside it, the outer casing being made of impact-resistant and fireproof, characterized in that the intermediate layer is made of dry refractory porous-fibrous material, and the inner layer is made of the same porous-fibrous material impregnated with a water-containing component, or a water-containing gel.  9. The protective housing according to claim 8, characterized in that the intermediate layer is made of refractory material based on mineral fibers.  10. The protective housing according to claim 8, characterized in that the inner layer is made of a porous fiber material impregnated with water.  11. The protective housing according to claim 8, characterized in that the inner layer is made of a porous-fibrous material impregnated with a water-containing gel.  12. The protective housing according to claim 8, characterized in that the outer layer is made of heat-resistant metals or composite materials.  13. The protective housing according to claim 8, characterized in that the inner layer on both sides is further provided with a protective shell.  14. The protective housing according to claims 8 and 13, characterized in that the protective shell is made of a polymer film material. 15. The protective housing according to claim 8, characterized in that it is provided with an additional housing of a layered structure of a similar structure, located inside the main body.