RU182079U1 - Fireproof casing for electronic and / or electrical equipment - Google Patents

Abstract

The utility model relates to fire fighting equipment, namely to a fireproof casing for placement of electronic and / or electrical equipment in it, and is used in the operation of electric actuators of shut-off and control valves (valves, valves, taps, etc.), in particular, those operating on objects of the gas and oil industry, where the probability of a fire is high. The fireproof casing for electronic and / or electrical equipment contains at least one air valve that allows air to enter the inner region of the casing through the ventilation channel of the air valve, at least one element is located in the ventilation channel, which, when heated, when the activation temperature is reached increases its volume and closes the ventilation duct; said element is a coating deposited on a metal plate with holes installed in the ventilation duct, an air valve is installed in the bottom of the casing, and the upper part of the casing is double with the possibility of passage between its inner and outer walls of the air stream. The proposed casing provides effective heat removal from electronic and / or electrical equipment. Moreover, the casing has high fire resistance and allows for year-round operation of the mentioned equipment in the open air.

Description

The utility model relates to fire fighting equipment, namely to a fireproof casing for placement of electronic and / or electrical equipment in it, and can be used in the operation of electric actuators of shut-off and control valves (gate valves, valves, taps, etc.), in particular, operating at gas and oil industry facilities, where a fire is likely.

Known fireproof casings for actuators of valves and fittings of the pipeline according to the patents of the Russian Federation 136725 (publ. 20.01.2014) and 2519984 (publ. 20.06.2014). The upper, lower and side walls of the casing are made of multilayer magnesite plates fixed to each other. The electric cable of the control unit and the working supply connections of the drive are passed through the holes in the bottom wall and sealed in it. The upper and side walls of the casing are internally lined with a steel grill, and the outside is lined with an aluminum coating 0.25-3 mm thick and painted with fire-retardant paint.

The disadvantage of the mentioned technical solutions is that they do not provide for heat removal from the electrical parts of the drive in the normal mode, in the absence of fire, i.e. there is no ventilation of the drive, which leads to its excessive heating and failure.

A device for thermal protection of electronic modules by removing heat from the device using heat-shielding mixtures according to US patent No. 5932839 (publ. 03.08.1999). The device comprises an outer casing, the inner surfaces of which form an inner cavity filled with a heat-shielding mixture in which electronic modules are placed, and an insulating thermal pad located between the inner surfaces and the heat-shielding mixture.

The disadvantage of this solution is the low reliability due to a short period of time, up to 160 s, during which the modules are protected from the effects of high ambient temperatures.

Known casing of an electronic device with air cooling according to the patent of the Russian Federation 2491662 (publ. 08/27/2013), containing a cooling system of the housing formed by the inlet, outlet openings, bottom cover, inner and outer left side, right side, rear walls, as well as double top a lid forming closed internal and external contours and made with the possibility of passage between the internal and external walls of the cooling air stream. The outlet openings are made on the front panel, the inner top cover is made in the form of a radiator, while the double partitions are installed with the possibility of passage between them of the cooling air flow between them, installed with the possibility of forming at least two main and one additional compartments, and inside each at least one heat-generating element is placed in the main compartment, made in the form of an electronic module with a heat sink, mounted by the contact surfaces of the heat sink on morning sidewall of the housing or partition and secured, with a snug fit to their inner surfaces and the end contact surface - to the inner surface of the top cover.

This technical solution provides heat dissipation inside the case of the electronic device, but does not protect it from external exposure to high temperatures.

Known protective casing for electronic equipment according to the patent of the Russian Federation 2516761 (publ. 05/20/2014). This metal casing is made double with the formation of a gap between the inner and outer shells surrounding the electronic equipment. The ventilation openings in these shells are evenly distributed over their surfaces and are arranged in a checkerboard pattern, i.e. ventilation openings of the inner and outer shells are blocked through the gap by the walls of the outer and inner shells, respectively. The outer surfaces of the shells are coated with a material, which, when heated, when the activation temperature is reached, increases its volume and blocks the ventilation openings. The casing design is able to withstand the effects of an open flame for 5 minutes, ensuring during this time the normal operation of electronic equipment.

The disadvantage of a protective casing for electronic equipment is that the presence of a large number of ventilation holes in the inner and outer shells of the upper part makes it impossible to use it in the open air, because It does not protect against the effects of precipitation and the negative effects of such exposure, for example, icing.

Another disadvantage is that convection flows inside the protective casing are not organized, which leads to insufficient heat removal in normal operation.

For the closest analogue, a metal case (25) with an electrical component (30) located inside it was selected according to the application WO 2013/160070 (published on October 31, 2013). In the metal housing (25) there is an opening (40) into which a fire damper (50) is inserted. The air valve (50) includes a metal tube (60), through the internal cavity (ventilation channel) of which the supply and exhaust ventilation of the internal area of the housing (25) is provided. An element (150) with at least one opening (170) is located in the internal cavity (ventilation channel) of the tube (60). The element (150) is made of material, which, when heated, when the activation temperature is reached, increases its volume and at the same time closes the hole (170), thereby closing the air valve. On the outside of the housing (25), the air valve tube (60) is closed by a cover (210) with the possibility of air passing through the channel openings (180). The air inside the cover (210) deviates 180 °. In this case, the tube (60) is horizontally oriented in space.

The supply air passes into the air valve sequentially through the open ends of the cover (210), channel openings (180), cover (210), the internal cavity (ventilation channel) of the tube (60) and through the hole (170) of the element (150) enters the inner area enclosures (25). The air flow from the housing (25) leaves the specified path in the reverse order.

The cessation of the fire inside the housing is facilitated by the closure of the opening (170) in the absence of other openings in the specified housing (25).

The disadvantage of this solution is that the air inflow and exhaust take place along the same path at the same time, as a result of which the flows of the removed and incoming air mix, which generally impairs the ventilation efficiency of the electrical component (30).

In addition, the ventilation efficiency is reduced due to the fact that the air, when passing through the air valve, moves along a curved path and changes its direction by 90 ° several times.

Another disadvantage is the complexity of the design of parts of the air valve (see Fig. 2, 3), requiring high precision manufacturing and assembly.

The technical result, which the utility model aims to achieve, is to ensure the operability of electronic and electrical equipment located in the casing, regardless of external temperature conditions.

The technical result is achieved in that the fireproof casing for electronic and electrical equipment, as well as the closest analogue, contains at least one air valve that allows air to flow into the inner region of the casing through the ventilation channel of the air valve, and at least one in the ventilation channel an element which, when heated, when the activation temperature is reached, increases its volume and closes the ventilation duct.

Unlike the closest analogue, the said element is a coating deposited on a metal plate with holes installed in the ventilation duct, an air valve is installed in the bottom of the casing, and the upper part of the casing is double with the possibility of air flow between its internal and external walls.

The essence of the utility model is illustrated by the following drawings: FIG. 1 - fireproof casing; FIG. 2 - air valve.

The fireproof casing (Fig. 1) contains an air valve 1 located at the bottom of the bottom 2, the upper part 3 and the middle part 4. The bottom 2, upper 3 and middle 4 parts are made of metal. An air valve 1 is installed in the bottom 2. The upper part 3 is double with the formation of an air gap 7 between its outer wall 5 and the inner wall 6. Electronic and / or electrical equipment 9, for example, an electric drive, is placed in the inner region 8 of the fire protection casing. The middle part 4 is located between the bottom 2 and the upper part 3 and is rigidly connected to the bottom 2 and the inner wall 6 of the upper part 3. The outer wall 5 is made without holes, preferably with the edges directed downward from the center, to provide protection from atmospheric precipitation. The inner region 8 is communicated with the space of the gap 7 through the ventilation holes 10 in the inner wall 6. The space of the gap 7 with its open ends communicates with the surrounding atmosphere.

The air valve 1 (Fig. 2) includes a metal tube 11, across the ventilation channel 12 of which a plate 13 with holes 17 is rigidly mounted. A plate 14 of material is applied to the plate 13 of at least one side, which, when heated, when the temperature reaches activation increases its volume and blocks the ventilation channel 12 by blocking the holes 17 in the plate 14. The metal tube 11 can be attached to the bottom 2 using a flange connection. The ventilation duct 12 is paired with an opening in the bottom 2. A coating 15 may be applied to the inner surface of the tube 11 with the effect of expansion under the influence of high temperature, which further contributes to the overlap of the ventilation duct 12. At least one metal mesh can be installed across the ventilation duct 12. or a grating 16 for retaining and sealing an increasing volume of coating 14 when exposed to an activation temperature. The holes 17 of the plate 13 are made in such sizes as to ensure their complete overlap with the increased in volume (expanded or foamed) coating 14 during exposure to high temperature.

It is possible to install at least one door 17 (Fig. 1) in the desired location of the casing, for example, for monitoring and controlling electronic and / or electrical equipment 9. Thermal insulation is attached to the bottom 2, upper 3 and middle 4 parts from the side of the inner region 8 of the casing 18 (Fig. 1) from any fire-resistant material, for example, from basalt, to enhance the fire resistance of the casing. The thermal insulation 18 of the bottom 2 has holes in the place of interfacing with the ventilation duct 12 and pipe fittings (not shown in FIG.).

In the normal mode, in the absence of fire, air enters the inner region 8 through the ventilation channel 12 (arrows A in Fig. 1), passing through the holes 17 in the plate 13. During operation of the electronic and / or electrical equipment 9, the air inside the casing is heated, rises between the walls of the casing and electronic and / or electrical equipment 9 (see arrows B in Fig. 1) and is discharged through the ventilation holes 10 of the inner wall 6 and the open ends 11 of the gap 7 (arrows B in Fig. 1).

When exposed to the flame casing, the coating 14 of the plate 13 and the coating of the inner wall 6 swell and increase in volume, which leads to the overlap of the ventilation duct 12 and ventilation holes 10, respectively. As a result, high-temperature effects on the electronic and / or electrical equipment 9 are prevented, while maintaining its operability . The experiments showed that the equipment 9, when exposed to the flame casing, remained operable for at least 30 minutes.

The simplicity of the design of the air valve 1 is due to the fact that the metal tube 11 and the plate 13 with holes do not require special equipment for their manufacture and can be made from standard workpieces by minimizing them and then coating them.

Due to the fact that the air valve 1 is installed in the bottom 2 of the casing, and the upper part 3 of the casing is double with the possibility of passing between its inner 6 and outer 5 walls of the air flow, organized channels for the directed movement of air from the bottom 2 to the upper part 3 with it unobstructed entry and exit, which ultimately allows more efficient cooling of electronic and / or electrical equipment with convection air.

To increase the fire resistance of the casing contributes to the insulation layer 16 from the inner region 8 of the casing.

Thus, the proposed casing provides efficient heat removal from electronic and / or electrical equipment. Moreover, the casing has high fire resistance and allows for year-round operation of the mentioned equipment in the open air.

Claims (5)

1. A fireproof casing for electronic and electrical equipment, comprising an air valve that allows air to enter the interior of the casing through the ventilation channel of the air valve, an element located in the ventilation channel, which, when heated, when the activation temperature is reached, increases its volume and closes the ventilation channel characterized in that the said element is a coating deposited on a metal plate installed in the ventilation duct with an opening With holes, the air valve is installed in the bottom of the casing, and the upper part of the casing is double with the possibility of passing between its internal and external walls of the air stream. 2. Fireproof casing according to claim 1, characterized in that the inner wall of the upper part of the casing has ventilation holes, and a coating of material is applied to the inner wall in the region of the ventilation holes, which, when heated, when the activation temperature is reached, increases its volume and covers the ventilation holes . 3. Fireproof casing according to claim 1, characterized in that the casing on the inside is provided with a coating of heat-insulating material. 4. Fireproof casing according to claim 1, characterized in that in the ventilation channel across its bore can additionally be installed a metal mesh or metal grille. 5. Fireproof casing according to claim 1, characterized in that the inner surface of the ventilation duct is coated with a material that, when heated, when the activation temperature is reached, increases its volume and helps to block the ventilation duct.

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