RU2220076C1 - Device for protection of data recorder memory circuits in emergency - Google Patents

Abstract

FIELD: protective units for flying vehicles. SUBSTANCE: proposed protective device has inner and outer containers where heat-insulating and heat-absorbing materials are placed. Outer container contains thermal protective stack made from layer of swelling material, heat-insulating gasket and metal layer. During melting, metal layer removes swelling material to ensure cooling of inner container. EFFECT: enhanced efficiency; reduced mass and overall dimensions. 22 cl, 3 dwg

Description

 The invention relates to aviation and space technology, and more specifically to flight information recorders of space and aircraft. More precisely, the present invention relates to the design and materials of the so-called housing. "black boxes" of aircraft that withstand high mechanical loads and thermal effects during a fire that accompanies an accident, as well as to hulls that are resistant to emergency climatic influences arising, including when immersed in sea water to a great depth. The invention can also be used in other technical fields.

 The device is a structure filled with insulating materials.

 U.S. Patent 6,045,718, dated April 4, 2000, is known in which thermal insulation material is used to protect data loggers, which is a composition consisting of inorganic particles, endothermic compounds, an opaque filler, inorganic fiber and a binder, the material may contain hydrophobic and hydrophilic substances. The disadvantages of such a material include low strength and resistance to mechanical stress.

 Known containers for data loggers that are resistant to large mechanical stresses, including and shocks, high thermal effects resulting from a fire. Such containers are made of layers of steel, tin bronze and external soft metal, however, they are heavy [RF patent 2131828, MKI B 64 D 1/14]. Containers are also known in which endothermic substances that emit gases when heated are used to protect against thermal effects. In order to increase the mechanical strength, binders are introduced into the composition. The use of a binder reduces the protective thermal effect and to achieve the required temperature it is necessary to use a large amount of bicarbonate, which leads to an increase in size and weight [US patent 5932839].

 Closest to the technical nature of the proposed device is a device for protecting memory circuits of a data logger, consisting of external and internal containers. In the cavity between the containers is placed endothermic insulation material that releases steam. In the inner container there is also an endothermic substance that undergoes phase transformations and is able to flow into the external cavity. The design provides for plugs of fusible material, which under the action of high temperature melt, which allows the steam to go outside [US patent 5708565 from 01/13/1998 - prototype].

 In the prototype, these heat-shielding materials have relatively low heats of endothermic effects. The effective implementation of the inherent endothermic properties is determined, at the same time, by the unimpeded removal of the gaseous products of thermal decomposition and the liquid phase of the endothermic substances into the external container and, if necessary, out of the external container, which balances the pressure inside the structure. The materials mentioned do not have cushioning properties, and the need to ensure the specified hole sizes and the integrity of the data logger memory circuits under shock loads and piercing effects determines the need to use an external container with a large titanium wall thickness and, accordingly, with a large weight.

 An object of the present invention is to provide a device for protecting memory circuits of a data logger with multifunctional properties: increased resistance to mechanical pulsation, increased static strength and increased heat-shielding efficiency in fire conditions and, at the same time, relatively low weight and dimensions. In addition, the technical task is to ensure the sealing of the proposed protection device so that it does not allow damage to the memory circuits at great depths.

The essence of the invention lies in the fact that the device for protecting memory circuits of the data logger in emergency conditions contains an external and an internal container, a first internal cavity between the external and internal containers, a second internal cavity located in the internal container, the first and second compartments in the second internal cavity , hole in the outer container, hole in the inner container, through hole for the passage of the connecting wires of the memory circuits of the data logger passing through without an external container, and in the first internal cavity there is an insulating layer, the first heat-absorbing material is located in the first compartment, the second heat-absorbing material and data logger memory circuits are located in the second compartment, the external and internal containers are made of impact-resistant material (distinguishing features follow) , the device also contains a thermal protection package located between the insulating layer and the inner container, a partition between the first and second compartments, a fibrous strip, laid in the first compartment between the inner container and the first heat-absorbing material, the housing for memory circuits located in the inner container, the plug for the hole in the outer container, the means for sealing the through hole in the outer container, the outer container made of metal material having a melting point below temperature 1100 ^o С, the insulating layer is made of a material having shock-absorbing mechanical properties, the thermal protection package consists of layers laid from the insulating layer, in the following sequence: a layer of material intumescent when heated, a heat-insulating strip and a metal layer with a melting point from 400 to 660 ^o C.

 In another embodiment, the essence of the proposed device is that the insulating layer is a foam.

 In another embodiment, the essence of the proposed device is that the insulating layer is a foam.

 In another embodiment, the essence of the proposed device lies in the fact that the insulating layer is located on the layer of material intumescent when heated.

In another embodiment, the essence of the proposed device is that the outer container is made of aluminum alloy with tensile strength σ _B ≥500 MPA and yield strength tensile σ ₀₂ ≥450 MPA.

In another embodiment, the essence of the proposed device is that the outer container is made of aluminum alloy with a melting point in the range of 500-660 ^o C.

 In another embodiment, the essence of the proposed device is that the insulating gasket is a mat consisting of heat-resistant glass fibers.

 In another embodiment, the essence of the proposed device is that the material intumescent upon heating is a polysiloxane composition with a filler system.

 In another embodiment, the essence of the proposed device is that the metal layer has a hole coaxial with the hole in the inner container.

 In another embodiment, the essence of the proposed device lies in the fact that the hole in the inner container is closed by a fibrous spacer.

 In another embodiment, the essence of the proposed device lies in the fact that the fibrous lining is a loose fiber material made of heat-resistant polymer fibers.

 In another embodiment, the essence of the proposed device is that the fibrous strip is a needle-punched material of heat-resistant polymer fibers.

 In another embodiment, the essence of the proposed device is that the first heat-absorbing material is sodium bicarbonate.

 In another embodiment, the essence of the proposed device is that the second heat-absorbing material is aluminum hydroxide.

 In another embodiment, the essence of the proposed device is that the second heat-absorbing material covers the housing for memory circuits from all sides.

 In another embodiment, the essence of the proposed device is that the partition between the first and second compartments is made of fiberglass.

 In another embodiment, the essence of the proposed device is that the housing for memory circuits is filled with a mixture of polysiloxane sealant with a filler.

 In another embodiment, the essence of the proposed device is that the filler is a cork chip.

In another embodiment, the essence of the proposed device is that the plug for the hole in the outer container consists of a steel screw with an internal hole in it and a metal alloy washer with a melting point of 120 ^o C, and the washer closes the inner hole in the steel screw when the screw is screwed into the hole in the outer container.

In another embodiment, the essence of the proposed device is that it contains a plug for holes in the inner container and the metal layer made of a material with a melting point of 90 ^o C, and in the first and second compartments the first and second heat-absorbing materials are impregnated with water.

In another embodiment, the essence of the proposed device is that the inner container is made of metal with a melting point of more than 1100 ^o C.

 In another embodiment, the essence of the proposed device lies in the fact that the means for sealing the external container in the specified through hole is made in the form of a pressure seal, which is a threaded plug with a rubber seal.

The technical result of the present invention is to reduce thermal conductivity and increase the elastic properties of the device under conditions of prolonged exposure to temperatures up to 1100 ^o C and impact in accordance with the standard OST 1.01080-95. In addition, the proposed device is sealed.

 The invention will be clear from the following description. The description is illustrated by drawings, where in Fig. 1, a sectional view is shown of a device for protecting memory circuits of a data logger in emergency conditions, including the arrangement of protective layers in a structure.

 Figure 2 shows a table with examples of the proposed device, and figure 3 shows graphs of temperature changes in the housing for memory circuits depending on the design and heating time and subsequent free cooling of the protection device of the memory circuits of the data logger.

The following notation is introduced in the drawing:
1 - external container;
2 - inner container;
3 - the first internal cavity;
4 - the second internal cavity;
5 - the first compartment;
6 - second compartment;
7 - memory circuit data logger;
8 - a through hole for the connecting wires of the memory circuits;
9 - a hole with a stopper in an external container;
10 - an insulating layer;
11 is a first heat absorbing material;
12 - second heat absorbing material;
13 - a mixture of silicone sealant with a filler;
14 - thermal protection package;
15 - a partition for separating the first compartment from the second;
16 - layer of intumescent material when heated;
17 - heat insulating gasket;
18 - metal layer;
19 - fibrous strip;
20 is a housing for data logger memory circuits;
21 - hole in the inner container and the metal layer;
22 - hole in the partition;
23 - means for sealing the outer container in the specified through hole.

The device for protecting memory circuits of the data logger in emergency conditions contains an external container 1, which is made of impact-resistant metal material with a melting point equal to or lower than 1100 ^o C. In a preferred embodiment, the external container 1 is made of high-strength aluminum alloy (for example, type D16 , B95, B96, etc.) with a melting point of 500-660 ^o C and with a tensile strength σ _B ≥500 MPA and a yield strength tensile σ ₀₂ ≥450 MPA. The wall thickness of the outer container 1 may be 8-15 mm.

 The inner container 2 is made of impact resistant material, for example, steel, titanium. The thickness of the inner container can be 1-5 mm.

 Between the outer 1 and inner 2 containers is the first inner cavity 3, in which the insulating layer 10 is located, having shock absorbing mechanical shock properties and low thermal conductivity. The thickness of the insulating layer may be 4-5 mm. The insulating layer 10 can be made, for example, of polyurethane foam, and the insulating layer is fixed in a compressed state of thickness, for example, using a polyamide film.

In the first internal cavity 3 there is also a thermal protection package 14, which consists of a layer 16 of material swelling when heated, a heat-insulating gasket 17 and a metal layer 18 with a melting point of 400 to 660 ^o C. The thermal protection package 14 with its metal layer 18 is adjacent to the outer surface of the inner container 2, and the intumescent layer 16 is adjacent to the insulating layer 10.

 The material swollen by heating of layer 16 is a polysiloxane composition with fillers, for example, of the following composition: dimethylsiloxane rubber, penetrite, melamine, tin diethyl dicaprylate, ammonium monofluorophosphoric acid (Copyright certificate 1799886, C 09 D 123/34, published March 7, 1993). The thickness of the layer 16 may be 3-4 mm

 The heat-insulating pad 17 is a mat consisting of heat-resistant glass fibers, for example silica fibers. The thickness of the gasket 17 may be 3-4 mm

The metal layer 18 is made of a material with a melting point of 400 to 660 ^° C. In a preferred embodiment of the invention, the layer 16 is made of an aluminum alloy with a melting point of 638 ^{° C.} (D-16 alloy) and has a thickness of 2-4 mm.

 The inner container 2 has a second inner cavity 4 in which the first compartment 5, the second compartment 6 and the housing 20 for memory circuits are located, the first compartment 5 being limited by the surface of the inner container 2 and the partition 15. The second compartment 6 is limited by the partition 15 and the housing 20 for circuits memory. The partition 15 is made, for example, of fiberglass with a thickness of 0.2-0.3 mm

In the first compartment 5 is the first heat-absorbing material 11 with a decomposition temperature of 250-300 ^{° C.} , which may be sodium bicarbonate.

 In the second compartment 6 there is a second heat-absorbing material 12 with a decomposition temperature not exceeding the maximum allowable operating temperature of the memory chips. Material 12 may be aluminum hydroxide. The thickness of the endothermic layers 11 and 12 is determined by the design requirements and the temperature-time parameters of the operation of the protection device (layer thickness 11, for example, 11-21 mm, and layer thickness 12, for example, 8-20 mm).

 The memory circuit 7 of the data logger is enclosed in a housing 20, which can be made of, for example, aluminum alloy D-16 or AMC with a thickness of 0.5 mm or a composite polymer based on glass or polymer fibers. The housing is filled, for example, with a polysiloxane sealant 13 mixed with cork chips.

The hole 21 in the inner container 2 and the metal layer 18 with a diameter of, for example, 1-3 mm is closed by a fibrous strip 19 of, for example, loose-fiber or needle-punched material made of heat-resistant polymer fibers with a temperature of destruction of more than 250-300 ^o C.

The hole 9 in the outer container 1 with a diameter of, for example, 4-5 mm is closed by a stopper, which ensures the tightness of the internal volume. The cork may contain a steel screw with a hole and a washer made of a material with a melting point of 120 ^o C, which closes the hole in the screw when the screw is screwed into the hole in the outer container 1 (not shown)
The proposed device for protecting the memory circuits of the data logger has a through hole 8 for connecting wires of the memory circuits passing through the external container 1 and other elements of the device to the memory circuits 7. The through hole 8 is sealed by means 23 for sealing the outer container 1. The means 23 for sealing the openings are itself, for example, a pressure seal, a screw plug with a rubber seal (for example, the company Bopla, Germany).

 The proposed device may be in the form of a cylinder, cube or ball, which is determined by the design, technological and economic requirements.

 The proposed device for protecting memory circuits of the data logger in emergency conditions works in its preferred embodiment as follows.

 The proposed device consists of an external container 1 made of high-strength aluminum alloy (type D16, B95, B96, etc.), and an internal container 2 made of metal alloys or metal composite materials. High-strength aluminum outer container 1 provides resistance to shock loads of about 3400g, local piercing by a steel rod and static load, protection from climatic factors, including when immersed in water to a great depth and is lightweight. The inner container 2 is a container for endothermic heat-absorbing layers 11 and 12 and has a sufficiently high strength, which also provides protection from shock.

 To achieve the declared technical result in the design of the proposed device, first of all, a thermal protection package 14 is used together with an insulating layer 10. The insulating layer 10 in the form of, for example, polyurethane foam has, in contrast to the prototype, in addition to heat-insulating, shock-absorbing properties.

 The structure of the package 14 together with the insulating layer 10 determines the greatest feasibility of the basic functional properties embedded in each of the materials.

The polyurethane foam of the insulating layer 10 has a dual function: it absorbs impact energy upon impact, reducing its impact on the inner container. Polyurethane foam is also a heat insulating material. As polyurethane foam can be used gas-filled polyurethane elastic materials with cushioning properties. Polyurethane foams have a low thermal conductivity of 0.06 W / m ^o C, deformability under compression of 50 percent or more. For example, polyurethane foam PPU-EO-100 can be used. In practice, various conditions for heating the container may occur. In the event of an accident, the heating source - the fire zone - can be located at different distances from the container, and the temperature acting on the container can vary from 80 to 1100 ^o C. In the temperature range of 80-120 ^o С, polyurethane foam provides effective protection due to low thermal conductivity , at higher temperatures, the destruction of polyurethane foam. Gaseous volatile products are removed from the container through the opening 9 (due to the melting of the cork, the opening opens) and the free space provides good thermal insulation. When heating the external aluminum container 1 to 530-600 ^o With its melting and transition to the liquid phase. In this case, a large amount of input heat is spent on heating and phase transformation (latent heat of fusion of aluminum is about 10.5 kJ / mol).

Under the polyurethane foam of the insulating layer 10 is a layer of intumescent material 16 of the thermal protection package 14. The intumescent material 16, when exposed to a temperature of 180-250 ^° C, forms a foam layer 25-30 mm thick or more, occupying the space freed up after the destruction of the insulating layer 10. The foam layer has low thermal conductivity and provides good thermal insulation of the inner container. Coatings of the Unitherm type (Germany), polysiloxane compositions with a filler system, etc. can be used as intumescent materials. Materials are applied to glass sheets of the KL-11 type.

As a heat-insulating strip 17, flexible heat-insulating materials from basalt or glass fibers in the form of mats, loose-fibrous or quilted materials are used. These materials have low thermal conductivity at the level of 0.04-0.09 W / m ^o C and an operating temperature of 90 / 1000-1100 ^o C. The fastening of the insulating layers is carried out using flexible heat-resistant adhesives, in particular adhesive-sealant brand Elastosil, VGO-1, as well as mechanical bandages. The use of heat-insulating gaskets 17 contributes to the rapid heating of the intumescent material 16 and the increased thickness of the foam layer.

 With further heating, as the inner layers of the device warm up, the metal layer 18 of the heat protection package 14 melts (a certain amount of heat is absorbed) and the intumescent layer 16, which is deposited on the metal layer 18, is removed along with the gasket 18. It is necessary to remove the foam layer of the intumescent material after heating 16 so that after 30 minutes (as required by the standards) the effects of the heat coming from outside from the flame provide fast heat transfer to the surrounding device, the heat medium accumulated in the inner container 2 during the active phase of the heating device flame. Otherwise, the heat accumulated in the inner container 2 will contribute to the heating of the data logger memory circuits above the permissible temperature after the exposure to the flame during the cooling phase of the device.

 For the manufacture of the inner container 2, various high-strength materials are used: steel and titanium alloys. The choice of structural materials is determined by the effectiveness of the thermal protection package and the strength properties of the external container. The inner container 2 and the metal layer 18 in the preferred embodiment have not one, but several drainage holes 21, designed to exit the gaseous products released from the first and second heat absorbing endothermic materials 11 and 12, which fill its internal volume. In order to filter gases and the solid component, the openings 21 are closed from the inside of the container 2 by a highly porous fiber spacer 19 in the form of needle-punched material or felt made of heat-resistant synthetic fibers, for example, arimide, terlon, etc.

 The first compartment 5 of the second inner cavity 4 is filled with the first heat-absorbing material 11 — bicarbonate (sodium, potassium, etc.), and the second compartment 6 is filled with the second heat-absorbing material 12 — aluminum hydroxide. These materials decompose when exposed to heat, absorbing heat and generating gaseous products in the form of carbon dioxide and water vapor. The external first compartment 5 is separated from the second compartment 6 by a partition 15. A layered arrangement provides the optimum temperature in each compartment for the indicated materials and the most complete realization of the endothermic properties.

The first and second heat-absorbing materials 11 and 12 can be moistened with water, which increases their ability to absorb heat. In this case, the openings 21 in the inner container 2 and the metal layer 18 are closed with a stopper (not shown) made of a material with a melting point of 90 ^° C. When the inner container is heated to a temperature of 90 ^° C, the openings 21 open for steam to escape from the first and second compartments where water impregnating the materials 11 and 12 and the decomposition products of these materials will evaporate.

 In the central part of the inner container 2, a housing 20 is installed, filled with sealant, with cork chips to provide hydro and thermal insulation, as well as vibration absorption of the memory circuits 7 of the data logger.

In FIG. 2 shows examples (1, 2, and 3) of specific structural solutions for the implementation of the device according to this invention. Examples 1, 2 and 3 differ in the diameters of the outer container and the volumes of heat-absorbing materials associated with them and the thicknesses of other heat-shielding components. The graphs of figure 3 shows that with an increase in the diameter of the external container (from example 1 to example 3) and a corresponding increase in the volume of heat-absorbing materials (sodium bicarbonate and aluminum hydroxide), the thermal regime of the memory circuits improves and the residence time of the memory circuits in the stable high (but acceptable, 95-98 ^o C) temperature.

 The invention is industrially feasible, because in the manufacture of the device, substances and materials manufactured by the industry and mastered technological processes are used.

Claims (22)

1. A device for protecting memory circuits of a data logger in emergency conditions, comprising an external and an internal container, a first internal cavity between the external and internal containers, a second internal cavity located in the internal container, the first and second compartments in the second internal cavity, an opening in the external container , a hole in the inner container, a through hole for passing the connecting wires of the memory circuits of the data logger passing through the outer container, and in the first inner polo The insulating layer is located, the first heat-absorbing material is located in the first compartment, the second heat-absorbing material and the data logger memory circuits are located in the second compartment, the outer and inner containers are made of impact-resistant material, characterized in that it contains a thermal insulation package located between the insulating layer and the inner container, a partition between the first and second compartments, a fibrous spacer located in the first compartment between the inner container and the first heat-absorbing mat a case, a housing for memory circuits located in the inner container, a stopper for the hole in the outer container, means for sealing the through hole in the outer container, the outer container made of metal material having a melting point below 1100 ° C, the insulating layer is made of material having shock-absorbing properties of a mechanical shock, the thermal protection package consists of layers laid, starting from the insulating layer, in the following sequence: a layer that swells when heated rial, heat-insulating gasket and metal layer with a melting point from 400 to 660 ° C. 2. The device according to claim 1, characterized in that the insulating layer is a foam. 3. The device according to claim 1, characterized in that the insulating layer is a polyurethane foam. 4. The device according to claim 1, characterized in that the insulating layer is located on the layer of material intumescent when heated. 5. The device according to claim 1, characterized in that the outer container is made of aluminum alloy with a tensile strength σ _of ≥ 500 MPa and a tensile strength of σ ₀₂ ≥ 450 MPa. 6. The device according to claim 5, characterized in that the outer container is made of aluminum alloy with a melting point of 500-660 ° C. 7. The device according to claim 1, characterized in that the heat-insulating strip is a mat consisting of basalt or heat-resistant glass fibers. 8. The device according to claim 1, characterized in that the material intumescent upon heating is a polysiloxane composition with fillers. 9. The device according to claim 1, characterized in that the metal layer has a hole coaxial with the hole in the inner container. 10. The device according to claim 1, characterized in that the hole in the inner container is closed by a fibrous spacer. 11. The device according to claim 1, characterized in that the fibrous strip is a loose-fiber material made of heat-resistant polymer fibers. 12. The device according to claim 1, characterized in that the fibrous pad is a needle-punched material of heat-resistant polymer fibers. 13. The device according to claim 1, characterized in that the first heat-absorbing material is sodium bicarbonate. 14. The device according to claim 1, characterized in that the second heat-absorbing material is aluminum hydroxide. 15. The device according to claim 1, characterized in that the second heat-absorbing material covers the housing for memory circuits from all sides. 16. The device according to claim 1, characterized in that the partition between the first and second compartments is made of fiberglass. 17. The device according to claim 1, characterized in that the housing for memory circuits is filled with a mixture of polysiloxane sealant with a filler. 18. The device according to 17, characterized in that the filler is a cork chip. 19. The device according to claim 1, characterized in that the plug for the hole in the outer container consists of a steel screw with an internal hole in it and a metal alloy washer with a melting point of 120 ° C, and the washer closes the inner hole in the steel screw when the screw screwed into a hole in the outer container. 20. The device according to claim 1, characterized in that it contains a plug for holes in the inner container and the metal layer made of a material with a melting point of 90 ° C, and in the first and second compartments the first and second heat-absorbing materials are impregnated with water. 21. The device according to claim 1, characterized in that the inner container is made of metal with a melting point of more than 1100 ° C. 22. The device according to claim 1, characterized in that the means for sealing the external container in the specified through hole is made in the form of a pressure seal, which is a threaded plug with a rubber seal.

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