RU2251050C1 - Illumination explosion-proof device on base of light emitting diodes - Google Patents

Abstract

FIELD: illumination engineering, namely rejecting (red, blue) or lighting (white) illumination devices used in open space or rooms containing explosion-hazard mixtures of vapor, dust or fibers with air, particularly for light barriers of industrial tubes, illuminating gun powder storehouses, tank ships, shafts and so on.

SUBSTANCE: device includes explosion proof optical unit 1 on base of light emitting diodes 2; transparent hood 3; mains converter and explosion impermeable inlet box 7 with hinged lid. Optical unit is arranged inside hood 3 on mandrel in the form of flange 4. Screws are used for mounting optical unit in lid 6 whose shape corresponds to that of flange 4. Detachable mains converter is arranged in inlet box and it is connected with optical unit 1 on printed circuit boards. Electric current supply leads of light emitting diodes are soldered to printed circuit boards and protected by means of electrically insulating compound. Each light emitting diode or group of such diodes are shunted by means of Zener diodes 28. Inlet box has explosion ducts 18 along threaded joint sealed with gasket.

EFFECT: simplified design, enhanced operational and illuminating parameters of device.

7 cl, 2 dwg

Description

The present invention relates to lighting engineering, in particular to protected and explosion-proof light devices using LEDs, for example, to protected and explosion-proof light-signal lights of circular view on LEDs emitting in red, red-orange, blue and other spectral ranges, or to lighting explosion-proof devices, emitting white light.

Explosion-proof LED lighting devices have a high degree of environmental protection and are designed for operation in open space and in production or storage rooms in which explosive mixtures of gases, vapors, dust or fibers with air may occur, for example, for light-shielding industrial pipes of nuclear power plants , refineries, oil and gas production platforms, etc., as well as for lighting powder depots, oil vessels, gas stations second, underground mining, workshops and production sites with a potentially explosive atmosphere.

Protected light devices using LEDs can also have traditional applications as light-signaling lights or lighting devices for operation in open space and in rooms with severe climatic conditions.

Known explosion-proof lamp (1), containing a flameproof enclosure including a housing with an explosion-proof lead-in box with a terminal block mounted on it, an optically transparent protective cap sealed in an annular mandrel with an internal light source, as well as conversion equipment for supplying a light source located outside shell of the lamp and the input box. The latter is mounted on the lamp housing through a sealing sleeve with holes for the passage of live wires.

The disadvantages of the analogue are associated with the difficulties of using it as a signal light generated by red, blue, and other radiation, as well as the low durability of the light source, the bulkiness and high cost of the housing, the input box and the conversion equipment for the light source.

Known light-emitting diode device on the LEDs (2), containing a housing paired with a protective cap with a support element and a holder in the form of a round disk, which is an electrical insulating printed circuit board oriented perpendicular to the optical axis of the device on which the LEDs are soldered. Elements of the power supply converter are located in the device case.

The light-signaling device does not provide the required explosion safety, has a low degree of protection against environmental influences, and unsatisfactory mechanical strength.

An explosion-proof light device based on LEDs (3) is known, comprising an explosion-proof casing including a housing and an optically transparent protective cap sealed in a mandrel with an inside lamp mounted on LEDs with a power supply converter, as well as an explosion-proof input box with a terminal block mounted on the housing and sealed removable cover, equipped with dead-end or transit cable entries for connection to an industrial network.

The disadvantages of the prototype are due to the complexity of the design, requiring the use of a bulky case with increased wall thickness that can withstand the destructive effect of an explosion from the inside, a protective cap with a wall thickness of 10-15 mm, having a luminous flux of 15-20%, an elongated labyrinth explosion channel, due to the large ballast volumes inside the lamp, etc.

In addition, the implementation of the lamp on the LEDs in a single design with the converter of the supply network reduces its life due to the fact that the life of the electronic elements of the converter is three to four times lower than the life of the LEDs (60-100 thousand hours).

The aim of the invention is to simplify the design, improve operational, lighting parameters of the lighting device.

This goal is achieved by the fact that the explosion-proof light device on the LEDs, containing an optical block on the LEDs with current-carrying leads, installed inside the optically transparent protective cap sealed in the mandrel, a power supply converter connected by current-supply elements to the indicated block, and an explosion-proof input box with a sealed cover and dead-end or transit cable entries and terminal block for connecting the device to an industrial network, as well as means for fixing the device to the object, the indicated optical unit on the LEDs has an explosion-proof design and is installed inside the protective cap on a mandrel in the form of a flange with fastening means on the mating cover of the flameproof entry box inside which is placed and connected to the aforementioned optical unit by current supply elements through one or more channels of the power supply converter.

The goal is achieved by the fact that the explosion-proof optical unit on the LEDs is made in the form of one, two or more electrical insulating (printed) circuit boards with the current-carrying leads of the LEDs soldered to them and protected by an electrical insulating compound, connected by series or parallel-series circuits to each other and protected elements of the current supply through the sealed channels in the panel mounted on the flange and in the cover of the input box to the terminal block and to the pi converter melting network.

The goal is also achieved by the fact that each LED or a chain of several series-connected LEDs of an explosion-proof optical unit is shunted by zener diodes assembled on at least one of the boards of the indicated unit or on an insulating panel mounted on a flange and protected by an electrical insulating compound.

The task is also achieved by the fact that the mandrel in the form of a flange with a protective cap assembled on it and an explosion-proof optical unit on the LEDs is coupled and pulled together by means of fastening through a seal with a flange-shaped flat cover of the flameproof entry box.

Achievement of the goal is also facilitated by the fact that the power supply converter installed inside the flameproof entry box is made in the form of a removable electronic unit with a board filled with a heat-conducting electrical insulating compound, for example, such as Nomacon, and is connected to an explosion-proof optical unit using LEDs and to an industrial network at the terminal block.

The problem is also solved by the fact that the flameproof entry box is equipped with explosion channels made through a gasket sealed with a threaded labyrinth in the interface zone with a dead end and / or transit cable entry.

The goal is also achieved by the fact that the fastening means of the device at the facility are mounted directly on the flameproof entry box.

A preferred embodiment of the device according to the invention is shown in the drawings:

Figure 1. Explosion-proof light fixture with LEDs, side view, partially in section.

Figure 2. The same as in figure 1, a top view, partially in section.

The explosion-proof light device based on LEDs shown in FIGS. 1 and 2 comprises an explosion-proof optical unit 1 on LEDs 2 mounted inside an optically transparent cap 3 on a mandrel having the shape of a flange 4 with fastening means, for example, screws 5, on a cover connected to it in an explosion-proof opening box 7. Inside the input box 7, an electronic converter 9 of the supply network is connected to the bracket 8 and connected to the WAGO 10 screwless terminal block by elements of the current supply 11 to the explosion-proof outside the box asnomu optical unit 1. The current supply elements 11 are passed through a sealed passage 12 formed in the lid 6, and the checkpoint grommet 13 mounted therein.

The explosion-proof inlet box 7 and the cover 6 connected with it through the rubber seal 14 are made of a heat-conducting material based on aluminum alloys, for example, silumin, with a wall thickness of 4-7 mm, which withstand the pressure of the heated explosion products.

The input box 7 is also equipped with a ground screw and a dead end cable entry 15, as well as a plug 16, instead of which a transit cable entry similar to the input 15 can be installed (not shown in Fig.). Cable entries are used to connect a three-wire current-carrying cable to the mains input box.

The cable entry 15 and the plug 16 are installed through the annular rubber seals 17 on the reciprocal thread in the housing of the input box 7, which functions as a labyrinth explosion channel 18. The area of their connection with the housing of the box 7 can be further strengthened by nuts 19 and 20 (see figure 1 and 2, respectively).

The total length of the thread of the explosion channel 18 (the interface between the blind or transit cable entry about the body of the input box) is determined by the total length of the thread in the hole in the wall of the input box and an additional nut 19 or 20 made of the same material as the box 7.

The optical unit 1 on the LEDs 2 (a lamp on the LEDs can also be used) is explosion-proof and contains one, two or more electrical insulating (printed) boards 21, 22 and 23 with the LEDs 2 soldered on them.

The boards 21 and 22 are made round or in the form of regular polygons and are assembled axially on the pulling rod 24, which is located on the longitudinal axis z of block 1. These boards are installed parallel to each other at a distance of 8-15 mm from each other through an annular spacer 25.

The boards 23 are made in the form of polygons and are mounted on the board 22 in the meridional planes of the upper hemisphere intersecting the rod 24 with the same angular distance from each other.

LEDs 2 are soldered along the perimeter of parallel printed circuit boards 21 and 22 and on the sides (ribs) facing the upper hemisphere of the polygonal printed circuit boards 23. The current-carrying leads and soldering points (not shown in Fig.) Of the LEDs 2 on the printed circuit boards are protected by an electrical insulation compound, for example heat-conducting electrical insulating compound 26 of the type "Nomacon" or a suitable electrical insulating varnish, eliminating the formation of a spark when contact breaks in the soldering zone.

The LEDs 2, soldered by current-carrying conclusions on the boards 21 and 22, as well as on the boards 23, are connected to each other in series or in parallel-serial chains, and are also connected to the current lead elements 11, output from the converter 9 through the terminal block 10 (shown by the arrow "a" figure 2) to the lower printed circuit board 21. Elements of the current supply 11 pass through an insulating sleeve 13, conjugated with the channel in the panel 27 mounted on the flange 4.

When the LEDs 2 of the explosion-proof optical unit 1 are connected in parallel-series, the elements of the current supply to the LED chains 2 from the supply network converter 9 can be output to the lower board 21 through two or more channels (not shown in Fig.) In the panel 27 of the optical unit 1 and cover 6 of the input box 7.

To ensure the operability of the optical unit 1 in the event of the failure of one or more LEDs 2, each of them or a chain of series-connected LEDs is shunted by zener diodes 28 (or a zener diode with series-connected ballast resistance), which are assembled on at least one of the boards of the optical unit 1 (mainly on the bottom plate 21) or on the insulating panel 27 installed on the flange 4. Zener diodes 28, ballast resistances and their soldering zones to the LEDs protect the electrical 26-insulating compound.

An explosion-proof optical unit 1 assembled and sealed in a mandrel in the form of a flange 4 with a protective cap 3 on LEDs is coupled and tightened with countersunk screws 5 through a rubber seal 29 with a cover 6 repeating the shape of the flange 4, mounted on the hinges 30 on the flameproof entry box 7.

To remove the optical unit 1 with the cover 6 and thereby open the flameproof entry box 7 is only possible when unscrewing the screws 5 with figured heads with a special secret key.

Installed inside the input box 7, the electronic converter 9 of the supply network is made in the form of a removable electronic unit 9 with a board 31, filled with a heat-conducting electrical insulating compound 32, for example, type "Nomacon". The Converter 9 is connected to an explosion-proof optical unit 1 on the LEDs (shown by the arrow "δ" in figure 2) and to the industrial network on a 4 or 6 position terminal block 10, thereby ensuring not only high reliability connecting it to the industrial network , but also a quick replacement of the converter 9 in the event of its failure.

Despite the hermetic design of the input box 7, it is equipped with explosion channels 18 made in a threaded labyrinth in the interface zone with the dead end 15 of the cable entry and the plug 16 or cable inlet, respectively. Each channel 18 from the outside of the box 7 is protected by a circular rubber O-ring 17, ensuring the tightness of the box 7 under normal operating conditions and displaced from the sealing zone of the channel 18 with a possible explosion and increased pressure of heated gases inside the input box 7, thereby ensuring a high degree of environmental protection and explosion protection of the input box 7 due to conductive cooling of hot gases when passing through a threaded maze 18.

Simplification of the design of the explosion-proof lighting device allows you to mount the means of fastening it on the object in the form of a corner 33 (shown in figure 2) directly on the flameproof entry box 7, allowing the device to be mounted on any mounting profiles, on horizontal and vertical surfaces or on tube consoles.

Explosion-proof lighting device operates as follows.

When the device is connected to an industrial AC 220 V, 50-60 Hz network, the electronic converter 9 provides a constant or pulsating current (20-70 mA for the LEDs of the considered option of the optical unit 1 at a given voltage on it or on a separate chain of LEDs. Optical LEDs generated radiation in the selected range of wavelengths of the spectrum (for example, in red - at a wavelength of ~ 630 nm) forms the desired light distribution curve with a given light intensity and uniform distribution of light in the selected s directions.

Low temperatures on the surface of the protective cap 3 and the structural elements of the device (on the flange 4, inlet box 7), exceeding the ambient temperature by no more than 15-20 °, the presence of the required explosion channels, as well as the exclusion of possible sparking processes ensure the safety of the use of explosion-proof light devices in hazardous areas of various categories and groups of explosive mixtures.

The advantage of the proposed device arises from a significant simplification of the design, eliminating the use of bulky body units, protective caps of increased thickness, elongated explosion channels made on a large diameter of the mating nodes. This reduces installation and operating costs (by reducing the overall dimensions and high life of the LEDs), improves lighting parameters by reducing losses in the protective caps and high light output of the LEDs in the selected spectral range.

Literature:

1. Auth. St. USSR No. 1158820, class F 21 V 25/02, publ. Bull. No. 20, 05/30/85

2. Pat. USA 16227679, cl. F 21 S 13/14, Publ. 05.03.2001 g.

3. St. on the floor. model No. 30926, class F 21 V 25/02, F 21 S 13/10, Publ. Bull. No. 19, 07/10/2003

Claims (7)

1. Explosion-proof LED light fixture, comprising an optical unit on LEDs with current-carrying leads, mounted inside an optically transparent protective cap sealed in a mandrel, a power supply converter connected by current supply elements to the indicated unit, and an explosion-proof lead-in box with a sealed cover, dead-end or transit cable the inputs and the terminal block installed in the indicated box for connecting the device to the industrial network, as well as means for fixing the device to an object, characterized in that the optical unit on the LEDs is explosion-proof and is installed inside the protective cap on a mandrel in the form of a flange with fastening means on the mating cover of the flameproof entry box, inside of which the power supply elements are placed and connected to the above optical unit through one or more channels power supply converter. 2. Explosion-proof light device on the LEDs according to claim 1, characterized in that the explosion-proof optical unit on the LEDs is made in the form of one, two or more electrical insulating (printed) circuit boards with the conductive leads of the LEDs connected to them and protected by an electrical insulation compound, connected in series or parallel-consecutive chains between each other and the protected elements of the current lead brought out through the sealed channels in the panel mounted on the flange and in the cover Attachments to the terminal block and to the power supply converter. 3. Explosion-proof lighting device according to claims 1 and 2, characterized in that each LED or a chain of several series-connected LEDs of an explosion-proof optical unit is shunted by zener diodes assembled on at least one of the boards of the indicated unit or on an insulating panel mounted on the flange and protected by an electrical insulating compound. 4. The explosion-proof light device according to claim 1, characterized in that the mandrel in the form of a flange with a protective cap and an explosion-proof optical unit mounted on LEDs is coupled and pulled together by means of fastening through a seal with a flange-shaped flat cover of the flameproof entry box. 5. Explosion-proof light device according to claim 1, characterized in that the power supply converter installed inside the flameproof input box is made in the form of a removable electronic unit with a board filled with a heat-conducting electrical insulating compound, for example, “Nomacon” type and connected to an explosion-proof optical unit with LEDs and to the industrial network at the terminal block. 6. Explosion-proof lighting device according to claim 1, characterized in that the flameproof entry box is equipped with explosion channels made of a threaded labyrinth sealed by a gasket in the interface zone with a dead end and / or transit cable entry. 7. Explosion-proof light device according to claim 1, characterized in that the means for attaching the device to the object are mounted directly on the flameproof entry box.

Images