RU2475673C1 - Explosion-proof light-emitting diode lamp - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: lamp has a housing made from heat-conducting material with a first compartment in form of a slot formed by protective glass and a holder, partially ribbed on the back side, on which a flat explosion-proof light-emitting diode emitter is placed in thermal contact, said emitter being in form of a cluster of light-emitting diodes assembled in nodes of a rectangular coordinate grid on a board with an aluminium base. A second insulated compartment adjoining the back side of the holder with an electronic transducer fitted therein is blast-tight and has dead-end and through cable inlets which are interfaced with the compartment on a secure thread which forms labyrinth explosion channels which link the inner volume of the compartment with the surrounding medium.

EFFECT: improved thermophysical parameters.

7 cl, 4 dwg

Description

The invention relates to lighting equipment, in particular to protected dust and water tight explosion-proof luminaires using LEDs of general industrial or military use emitting white light, including LEDs of violet, blue or blue radiation with conversion to white light using one or a mixture of phosphors.

Explosion-proof LED luminaires have a high degree of environmental protection and are intended for illumination of objects when used in open space and in industrial or warehouse premises, classified as explosive zones according to GOST 51330.9-99, in which the formation of explosive mixtures of gases, vapors, dust or fibers with air, for example, in oil refineries, oil and gas production platforms, chemical plants, etc., as well as for lighting powder depots, oil tanks GOVERNMENTAL ships engine rooms of ships and submarines, missile silos, bunkers and other sites.

Known explosion-proof light device on LEDs / 1 /, containing a compact LED emitter of explosion-proof design, assembled inside a protective cap mounted on the cover of a flameproof entry box of heat-conducting material, inside of which a power supply converter is made and connected to the specified emitter through channels made in the cover, made in the form of a removable monoblock, filled with an insulating heat-conducting compound.

The disadvantages of the analogue are associated with the difficulties of using powerful LEDs, due to the lack of cooling radiators, which limits the possibility of using it for lighting purposes.

Known protected light device on high-power LEDs / 2 /, which also has an explosion-proof design, containing a protected shell in the form of a housing of heat-conducting material with an optically transparent protective cap, mounted inside a compact LED emitter on high-power LEDs, assembled in thermal contact on flat petals, forming a hollow polyhedron-cooling radiator in thermal contact with one or more additional cooling radiators, one of which shares aschischennuyu sheath unit into two isolated compartments between them. One of them is made explosion-proof with the current-supply means installed in it and an electronic converter of the supply network assembled on a board filled with a heat-conducting compound.

The disadvantages of the analogue are due to the difficulties of increasing power by increasing the number of LEDs without increasing the dimensions of the flameproof compartment, as well as the deterioration of the heat exchange conditions of the LED emitter.

Known explosion-proof LED lamp / 3 /, made in a metal case with an outlet, covered with transparent polycarbonate with the LEDs assembled in it and having an insulated compartment, in which the power supply and control unit is installed, filled with an electrically insulating polymer compound, and a cable entry for connecting the lamp to the power supply network.

The disadvantages of the prototype are caused by the lack of cooling means for LEDs, which excludes the possibility of using an increased number of powerful LEDs in the lamp, due to their unsatisfactory heat exchange with the environment, and, as a result, low light flux.

The aim of the invention is to improve the thermophysical and lighting parameters of an explosion-proof lamp using high-power LEDs.

This goal is achieved by the fact that in an explosion-proof luminaire with LEDs containing a housing of heat-conducting material with a first compartment covered by an optically transparent protective glass and mounted on the holder with a flat LED emitter, and a second insulated compartment with an electronic converter of the mains connected to the specified emitter by means of a current supply, said first housing compartment is a slotted compartment formed by an optically transparent protective glass and flat a holder, at least partially finned, on the back side, on the front side of which a protected explosion-proof LED emitter is installed in thermal contact with the specified holder in the form of a cluster with LEDs assembled in nodes of a rectangular coordinate grid on a board with an aluminum base, and adjacent to the holder in the back of the housing part, the second insulated compartment is made flameproof with dead-end or transit cable entries mating with the compartment through a protected thread forming a labyrinth intovye explosion of channels connecting its internal volume with the environment.

This goal is also achieved by the fact that in the second insulated compartment a stationary or removable flameproof cassette is installed with a sealed cover and with an electrode converter of the supply network and means of current supply assembled in the cassette and made in it with dead-end or transit cable entries that are interfaced with the cover of the cassette by a protected thread, forming explosion channels.

The goal is achieved by the fact that a stationary or removable flameproof cassette with a lid and / or an insulated explosion-proof compartment of the housing are electrically connected to the first compartment through openings coaxially made in the walls, mounted with a threaded nipple with sealed in its axial channel means of connecting the electronic converter to the cluster with LEDs.

The task is also solved by the fact that the electronic converter of the supply network assembled on the board is filled with a heat-conducting electrical insulating compound and is made with a built-in screwless terminal block, for example, of the WAGO type, connected to a cluster with LEDs and to a power supply cable.

In one embodiment of the explosion-proof luminaire, the goal is achieved by the fact that the insulated second compartment of the housing is made explosion-proof in the form of an extended tubular channel, hermetically sealed at opposite ends with covers, with dead-end or transit cable entries axially mounted on them, mating through a protected thread, forming a labyrinth explosion channels.

The goal is also achieved by the fact that the protective glass of the first compartment is made of optically transparent polymeric material, for example, polycarbonate in the form of a flat, repeating cluster relief, element with domes individually surrounding the emitter LEDs, and hermetically connected to the holder and / or cluster mainly at the periphery around the perimeter of one of them.

In another embodiment of the device, the task is also solved by the fact that the cluster of the LED emitter is made of blue or blue light emitting diodes, and the protective glass is coated with a layer of one or a mixture of several phosphors, for example, from yttrium-aluminum or gadolinium-aluminum garnets or mixtures thereof activated by cerium, dispersed in a binder based on, for example, an optically transparent organosilicon compound, converting the radiation of LEDs into white light and scattering it.

The most preferred embodiments of the device according to the invention are shown in the drawings.

Figure 1. Explosion-proof LED luminaire with integrated flameproof cassette. Side view, partially in section.

Figure 2. The same as in figure 1. Front view / front /, partially in section.

Figure 3. The same as in figure 1, with a protective glass made of a polymeric material with domes individually surrounding the LEDs. Side view, partially in section.

Figure 4. Explosion-proof LED luminaire with flameproof tube compartment with covers. Side view, partially in section.

The explosion-proof LED-based luminaire shown in FIGS. 1 and 2 comprises a housing 1 made of heat-conducting material, mainly based on aluminum alloys, made with two compartments 2 and 3 isolated from each other.

The outlet of the luminaire housing 1 is covered by an optically transparent protective glass 4, mainly heat-resistant annealed silicate glass or made of a polymeric material, for example, polycarbonate, forming the first slotted compartment 2 with the face of a flat holder 5 of a rectangular shape.

On the back side of the flat holder 5, cooling fins 6 are made, and on its front side in the slit compartment 2, an electrically protected explosion-proof LED emitter in the form of a cluster 7 on a board with an aluminum base is installed in thermal contact / it is possible to use other heat-conducting material / with LEDs 8 assembled /cm. figure 2 / in the nodes of the rectangular coordinate grid.

The thermal contact of the cluster 7 with the holder 5 is ensured by uniformly tightening them with screws 9.

The housing 1 and the holder 5 with cooling fins are made in the form of a single part made by extrusion, which ensures efficient conductive-convective heat transfer from the cluster LEDs 8 to the environment.

The second insulated compartment 3 adjacent to the holder 5 in the rear of the housing is made of extended, mainly rectangular cross-section, and is explosion-proof with a dead end 10 or transit cable entries / when an additional cable entry, similar to a dead end, is installed instead of plug 11, is not shown /.

The cable entry 10 and the plug 11 are made of heat-conductive aluminum alloy and mate with the cover 12 of the compartment 3 through a thread 14 and 15 / cm protected by an annular seal 13. also 4 /, forming a labyrinth explosion channels connecting the internal volume of the compartment with the environment. The length of each labyrinth channel is selected from the condition of ensuring the cooling of a stream of gases / explosion products / leaving the compartment into the surrounding space to a predetermined temperature not exceeding the ignition temperature of gases, vapors, dust or fibers mixed with air in the space surrounding the lamp.

Cable glands are designed to seal cables when connecting fixtures to cable networks. Transit cable entries allow you to refuse additional installation in the networks of intermediate explosion-proof junction boxes in networks of group connection of fixtures.

The second version of the explosion-proof lamp / see figure 3 / provides for the implementation of the protective glass of the housing of an optically transparent polymeric material, for example polycarbonate, in the form of a flat, repeating the relief of the cluster 7 element 16 with domes 17 individually surrounding the emitter LEDs 8 and hermetically connected to the holder 5 and / or cluster 7 mainly on the periphery of one of them, using, for example, an adhesive material such as elastosil 137-352 TU 6-02-1-037-91 or a suitable compound.

Thus, the technology is simplified and the reliability of sealing the compartment 2 of the lamp housing is increased.

In another embodiment, explosion-proof lamp / cm. figure 1, 2 and 3 / inside the insulated compartment 3 of the housing is installed in a sliding fit to ensure thermal contact with the walls of the compartment stationary or removable flameproof cassette 18, sealed through the gasket 19 by the cover 12.

The lid 12 is made in the form of a box mating the open part with the cassette 18 or directly with the end part of the compartment 3 / or the first embodiment shown in figure 1 /.

On the side walls of the cover 12 there is a dead end cable entry 10 and a plug 11, which can be replaced if necessary under operating conditions by a transit cable entry, mounted on a thread protected by an annular seal 14, which forms labyrinth explosion channels.

Inside the compartment 3 / cm. figure 1 / or cassette 18 with a cover 12 / see Figures 2 and 3 / assembled an electronic converter 20 of the mains with current supply means including a screwless terminal block 21, for example, of the WAGO type, current-carrying cables 22 and the ground screw 23.

Terminal block 21 can be mounted on the PCB 20 / cm. figure 1 / in compartment 3, in the cassette 18 or on the wall of the cover 12 of the specified cassette / see figure 2 /.

The electronic converter 20 of the supply network assembled on the board is filled with a thermally conductive insulating compound, for example, based on a ceramic-polymer thermally conductive dielectric compound of the Nomacon type and is made with an integrated screwless terminal block 21 connected to the cluster 7 with LEDs by means of current supply.

Fixed or removable flameproof cassette 18 with cover 12 and / or insulated compartment 3 of the flameproof enclosure / cm. also 3 / are electrically connected to the first compartment 2 through coaxially made holes in the walls, mounted on a protected thread with a nipple 24 sealed in its axial channel, for example, using the previously mentioned elastosil glue, by connecting an electronic converter to a cluster 7 with LEDs.

The nipple 24 may be made in the form of a bolt with an axial hole of aluminum alloy or polyamide.

In another embodiment of the explosion-proof lamp / cm. 4 / the insulated compartment of the housing is made explosion-proof in the form of an extended tubular channel 25 of predominantly rectangular cross-section, hermetically sealed at opposite ends with covers 26 and 27 with axially mounted dead ends 28 or transit cable entries mating through thread 29 protected by ring seals, forming a labyrinth explosion channels on the reciprocal thread of the housing compartment.

One of the transit cable entries can be replaced by a plug 30. Covers 26 and 27 are mounted directly on the ends of the compartment forming the tubular channel 25 through seals 31 and are bolted together with the indicated compartment of the lamp housing.

Inside the flameproof tube channel 25, a compound-filled monoblock of the electronic converter 32 of the supply network with an integrated screwless terminal block 33 is installed. An additional terminal block 34 for the transit connection of the lamp is also possible.

The Converter 32 is connected to the cluster 35 with LEDs by means of a current supply 36, sealed in the axial channel of the nipple 37, and also protected in the soldering zone on the cluster by a compound and an insulating pad 38.

The proposed design options for explosion-proof fixtures are made on high-power LEDs / 1-3 W / white light. However, to reduce the brilliance and provide more comfortable illumination of objects, for example, in production shops, it is possible to use a cluster of 7 or 35 LED emitters using blue or blue light emitting diodes at wavelengths of 450-470 nm, followed by changing part of the radiation spectrum using phosphors, for example, based on yttrium-aluminum garnet / Y ₃ Al ₅ O _12: Ce / or gadolinium-aluminum garnet / Gd ₃ Al ₅ O _12: Ce /, activated with cerium, and preferably mixtures thereof, allow to obtain white or warm white light vetodiodov in the spectral range of 530-580 nm with a high quantum yield of luminescence.

In this case / cm. 4 / the inner surface of the protective glass 39 is covered with a layer 40 of one or a mixture of the aforementioned phosphors in the form of a powder dispersed in a binder based on, for example, an optically transparent organosilicon compound that converts and mixes part of the blue or blue light emitting diodes from the light emitting phosphors and scattering this radiation .

For installation on objects during operation, all the considered luminaire options are made with swivel or corner suspensions.

Explosion-proof luminaires according to the invention, for example, based on a cluster with 36 LEDs of the MX-6 series with a power of ~ 1 W from CREE warm-white radiation, provide a luminous flux of at least 3000 lm with a diffusion angle of ~ 120 ° with a color temperature of 3700-4300 K at power consumption ~ 50 W and a mass of not more than 4 kg.

The luminaires have significantly improved lighting and thermophysical parameters with reduced overall dimensions, provide 4-5-fold savings in the consumed electric energy, and a significantly higher lifespan of continuous operation compared to explosion-proof luminaires on incandescent and discharge lamps.

Literature

1. Patent for IZ RF №2251050, class. F21V 25/12, prior. December 17, 2003

2. Patent for IZ RF №2392538, cl. F21V 13/14, prior. 11/21/2008

3. Paul. RF model No. 101149, class F21V 15/00, prior. 08/30/2010 r.

Claims (7)

1. Explosion-proof LED lamp, comprising a housing of heat-conducting material with a first compartment covered by an optically transparent protective glass and mounted on a holder with a flat LED emitter, and a second insulated compartment with an electronic converter of the mains connected to the specified emitter by means of current supply, characterized in that said first housing compartment is a slotted compartment formed by an optically transparent protective glass and a flat holder, at the extreme it is partially finned on the back side, on the front side of which a protected explosion-proof LED emitter is installed in thermal contact with the specified holder in the form of a cluster with LEDs assembled in nodes of a rectangular coordinate network on a board with an aluminum base, and the second one adjacent to the holder in the back of the case the insulated compartment is made explosion-proof with dead-end or transit cable entries mating with the compartment along a protected thread forming a labyrinth explosion channel Connecting its internal volume with the environment. 2. The explosion-proof lamp according to claim 1, characterized in that in the second insulated compartment of the casing there is a stationary or removable flameproof cassette with a sealed cover and with an electronic power supply transducer assembled in the cassette and current-carrying means and made in it by dead-end or transit cable entries, interfaced with a cassette lid on a protected thread forming explosion channels. 3. The explosion-proof lamp according to claim 1, characterized in that the stationary or removable flameproof cassette with a lid and / or an insulated explosion-proof compartment of the housing are electrically connected to the first compartment through openings coaxially made in the walls, a nipple sealed with a protected thread and sealed in its axial channel means of connecting an electronic converter to a cluster with LEDs. 4. The explosion-proof lamp according to claim 1, characterized in that the electronic converter of the supply network assembled on the board is filled with a heat-conducting electrical insulating compound and is made with a built-in screwless terminal block, for example, of the WAGO type, connected to a cluster with LEDs and to a power supply cable. 5. The explosion-proof lamp according to claim 1, characterized in that the insulated second compartment of the housing is made flameproof in the form of an extended tubular channel sealed at the opposite ends with covers, with dead-end or transit cable entries axially mounted on them, mating through a protected thread, forming a labyrinth explosion channels. 6. The explosion-proof lamp according to claim 1, characterized in that the protective glass of the first compartment is made of optically transparent polymeric material, for example, polycarbonate in the form of a flat, repeating relief cluster, element with domes individually surrounding the emitter LEDs, and hermetically connected to the holder and / or a cluster, predominantly at the periphery around the perimeter of one of them. 7. The explosion-proof lamp according to claim 1, characterized in that the cluster of the LED emitter is made of blue or blue light emitting diodes, and the protective glass is coated with a layer of one or a mixture of several phosphors, for example, from yttrium-aluminum or gadolinium-aluminum, garnets or mixtures thereof activated by cerium, dispersed in a binder based on, for example, an optically transparent organosilicon compound, converting the radiation of LEDs into white light and scattering it.

Images