RU2259512C1 - Explosion-proof lighting device - Google Patents

Abstract

FIELD: explosive atmospheres such as those in oil refining and chemical plants, coal mines, powder stores, vehicle service stations, and the like.

SUBSTANCE: proposed device has discharge lamp with lamp socket installed inside optically transparent shielding cap on heat-conducting holder which is in thermal contact with solid fixture in the form of flange made of similar material wherein mentioned cap is installed and sealed. Fixture is provided with labyrinth explosion channel providing communication between inner space of cap and surrounding medium and mounted together with holder on cover of lead-in box for device forming transfer chamber where free part of current-carrying conductors is disposed. Starting-and-regulating apparatus is mounted inside lead-in box and connected through mentioned current-carrying conductors passed through sealed holes in holder and lead-in box cover to lamp socket. Lamp-holder-and-socket assembly is made in the form of flanged sleeve installed with slide fit on side surface of intermediate circular member in axial threaded hole of fixture; mentioned member is threaded on periphery and set on mating thread in axial hole of fixture to form threaded labyrinth explosion channel.

EFFECT: enhanced explosion safety, reduced size and mass, improved lighting characteristics.

3 cl, 1 dwg

Description

The present invention relates to lighting engineering, in particular to explosion-proof lighting devices with high-intensity discharge lamps.

Such lighting devices have an explosion-proof fireproof design and a high degree of protection against environmental influences.

Lighting devices are intended for operation in open space and at facilities or in premises with difficult working conditions, including in oil refining and chemical plants, oil and gas production platforms, coal mines, etc., as well as for lighting powder storage facilities, oil loading ships, gas stations, shops and sections with explosive atmospheres.

Known explosion-proof light device [1], containing an explosion-proof shell, comprising a massive body with an explosion-proof lead-in box with a terminal block mounted on it and an optically transparent protective cap sealed in a mandrel, a discharge lamp with a cartridge installed in the housing, and an electromagnetic control device assembled into explosion-proof chamber outside the device.

The disadvantages of the analogue are due to the complexity and high material consumption of the structure due to the need to use an explosion-proof housing, an introductory box and a camera to accommodate a ballast.

Known explosion-proof light device [2], containing an explosion-proof shell in the form of a housing with an optically transparent protective cap sealed in an annular mandrel with a thread mounted on a reciprocal thread in the housing with the formation of a threaded explosion channel, and a discharge lamp of the DRL type with a cartridge installed in the shell and electromagnetic ballast, assembled in the back of the case. An explosion-proof input box with a terminal block and at least one stuffing box for connecting the device to an industrial mains is mounted on the outer surface of the housing. A reflector is installed inside the housing to produce a directed beam of radiation.

The disadvantages of the prototype are due to the high complexity and material consumption of the device due to the need to make a protective cap and housing of increased dimensions to accommodate a DRL lamp with an enlarged bulb, a cartridge and a ballast, as well as an input box mating with it. For this reason, the diameter of the open part of the casing and the mandrel with a protective cap cannot be reduced, which makes it difficult to reduce the ballast volume of the device and the diameter of the threaded labyrinth explosion channel, reaching 250 mm or more for various versions.

The latter circumstance complicates the design and complicates the maintenance of the device during operation, because It requires screwing a heavy mandrel with a protective cap over large diameter threads to replace the lamp. In addition, the light device has unsatisfactory lighting characteristics due to insufficient light output of the DRL lamp.

The aim of the invention is to increase the explosion safety, simplify the design and maintenance while reducing material consumption, as well as improving the lighting characteristics of the lighting device.

This goal is achieved in that in an explosion-proof light fixture containing an explosion-proof sheath with an optically transparent protective cap sealed in a mandrel, a discharge lamp with a luminous body, a cartridge, a ballast control unit and an explosion-proof entry box with at least one cable entry, a cover, a terminal by the block and wires of the current supply means, as well as the means of fastening the device to the object, the indicated lamp with a cartridge is installed inside the protective cap on the holder of heat-conducting material in thermal contact with a massive mandrel in the form of a flange of similar material with a protective cap mounted on it and equipped with a labyrinth explosion channel connecting the inner cavity of the protective cap with the environment, the holder and the mandrel mounted on the cover of the input box with the formation of the transition chamber to accommodate the free part of the wires of the current supply means, and the ballast is mounted inside the above input box and connected by the wires of the current supply means, etc. passing through a sealed aperture in the holder and cover the inlet box to the lampholder.

The goal is achieved by the fact that the lamp holder with a cartridge is made in the form of a bead with a flange mounted by sliding fit on the side surface mounted in the axial hole of a massive mandrel in the form of a flange, an intermediate ring element with the formation of a labyrinth explosion channel.

The goal is also achieved by the fact that the holder in the form of a cup is sealed on an intermediate annular element made of heat-conducting material, with a thread on the periphery and set on the reciprocal thread in the axial hole of the mandrel with the formation of a threaded labyrinth explosion channel.

The problem is also solved by the fact that the mandrel in the form of a flange is mechanically connected through a seal to an additional cap flange covering the end part of the protective cap.

The goal is also achieved due to the fact that a metal halide lamp is used as a discharge lamp, in particular a ceramic metal halide lamp or a high pressure sodium lamp mounted together with the cartridge coaxially in a protective cap on the bottom of the holder in the form of a glass.

Achievement of the goal is also facilitated by the fact that the ballast is made on the basis of electronic components and has a frame-less design with a built-in screwless WAGO block; it is filled together with a part of the block with a heat-conducting electrical insulating compound, for example, Nomacon type.

The solution to this problem also contributes to the fact that the input box is equipped with at least one threaded labyrinth explosion channel made by thread in the area of the cable entry to the cable interface for connecting it to the supply network.

The goal is achieved by the fact that the input box has a cross-section in the form of a mandrel, mounted perpendicular to the optical axis of the device, coupled to the mandrel through an annular seal and mechanically fixed to it with tightening bolts.

Another means of achieving the objective of the invention is that an external diffusely or specularly redistributing optical radiation flux with a light center (or focus) combined with the luminous body of the lamp is mounted on a mandrel in the form of a flange.

And, finally, the task is solved by the fact that the means of fastening the device on the object are made in the form of a bracket mounted on the back of the input box.

The most preferred embodiment of the device according to the invention is shown in the drawings.

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

Figure 2. The same as in figure 1, a top view, partially in section (without reflector).

The explosion-proof light device shown in FIGS. 1 and 2 contains an explosion-proof casing formed by an optically transparent protective cap 1 with an end part having a flange 2 and a massive mandrel 3 in the form of a flange with a central hole covered by an intermediate ring element 4 and a lamp holder 5 6 s cartridge 7, ballast apparatus 8 and flameproof entry box 9 with a cover 10, one dead end or two transit cable entries 11, terminal block 12 (see figure 2), wires 13 of the current supply means, as well as Tools 14 for mounting the device at the facility.

A lamp 6 with a cartridge 7 is installed inside the protective cap 1 on the holder 5, made of a heat-conducting material based on aluminum alloy, mainly from silumin, which is in thermal contact with the massive mandrel 3 in the form of a flange of similar material. The mandrel 3 adjoins through the sealing compound 15 of the Elastosil type to the end part with the flange 2 of the protective cap 1 and is equipped with a labyrinth explosion channel, forming in the interface zone of the mandrel 3 with the annular element 4, the holder 5 and the cover 10 of the input box 9 connecting the internal cavity 16 protective cap 1 with the environment.

The lamp holder 5 with a cartridge has the shape of a glass with a flange 17 adjacent to the mandrel 3 with the formation of gaps 18, forming a labyrinth explosion channel of the device. The holder 5 and the mandrel 3 are mounted on the cover 10 of the input box 9 through an O-ring 19 of circular cross section, pushed out of the seat during the passage of explosion products from the inside.

Moreover, the said holder 5 and the cover 10 form a transition chamber 20 for accommodating the turns of the free part of the wires 13 of the current supply means connected to the cartridge 7 of the lamp 6 and to the terminal block 12 (see Fig. 2) of the control gear 8. The wires 13 pass through the holes in holder 5, as well as through insulating sleeves 21 in the openings of the cover 10 of the input box 9 and sealed in them by the aforementioned electrical insulating compound. The turns of the free part of the wires 13 are also located inside the input box 9.

The turns of the free part of the wires 13 of the current supply means arranged in the transition chamber 20 provide the possibility of folding on the hinges 22 of the mandrel 3 with the optical unit assembled on it and thus opening the explosion-proof casing of the device to replace the lamp 6, and the turns of wires 13 located inside the input box 9 provide access to ballasts 8 during installation and operation.

The control gear 8 is made on the basis of electronic components and has a case-free design with a built-in screwless terminal block 12, for example, of the WAGO type, filled together with a part of the block with a heat-conducting electrical insulating compound, for example, of the Nomacon type, and installed inside the input box 9 with 13 means connected by wires current leads passing in the insulating bushings 21, sealed in the holes 23 of the holder, and the cover 10 of the input box 9, to the cartridge 7 of the lamp 6.

The holder 5, made in the form of a cup with a flange 17, is mounted through a seal 24 and has a sliding fit along the lateral surface 25 mounted in the axial hole of the massive mandrel 3 in the form of a flange of the intermediate annular element 4, with the formation of a labyrinth explosion channel 18 along planar and cylindrical slots. In this case, the annular element 4 is made of a heat-conducting material with a thread 26 on the periphery and fitted by a reciprocal thread (at least 5 turns) in the axial hole of the mandrel 3 with the formation of the main threaded labyrinth explosion channel 26, complementing the explosion channel 18 in planar and cylindrical slots.

To avoid "sticking" (locking) of the holder 5 in the ring element 4 during long-term operation, it is advisable to make the latter of stainless alloys, for example, of brass, which has a coefficient of linear expansion lower than silumin, eliminating the locking of the holder 5 in the ring element 4 when the working contact is sliding surfaces in a cold state (when the appliance is not working). The width of the slots of the explosion channel 18 is controlled by the depth of screwing the annular element 4 into the mandrel 3 and the gasket 24.

For reliable sealing and mechanical fastening of the protective cap 1 in the mandrel 3 in the form of a flange, the latter is connected through an annular seal 27 and the sealing compound 15 with an additional cap flange 28, covering the flanging 2 of the end part of the protective cap 1, and mechanically holding it on the mandrel 3 with screws 29 ( see figure 2).

As a discharge lamp 6, a metal halide lamp was used, in particular a ceramic metal halide lamp with a power of 30, 70 or 150 W, installed together with the cartridge 7 coaxially in the protective cap 1 on the bottom of the holder 5 in the form of a glass. A high pressure sodium lamp with a power of 30, 70 watts can also be used.

Introductory box 9 is equipped with at least one threaded labyrinth explosive channel 30, threaded in the interface zone with one or two cable entries 11 for connecting the power supply, installed through an annular sealing gasket 31 of circular cross section, pushed like a gasket 19 from the landing slot when it occurs explosion inside the box. The specified gasket provides the necessary degree of protection of the box 9 from the ingress of moisture and dust (environmental influences) under normal operating conditions.

The input box 9 has the cross-sectional shape of the mandrel 3 and the flange 28, is mounted perpendicular to the optical axis z of the device, is coupled to the mandrel 3 through an annular seal 19 and mechanically fixed to it by tightening screws 32, also sealing the cover 10 with the box 9 through the gasket 33.

The sealing of the box 9 and the mandrel 3 on the cover 10 can be performed by independent means of mechanical fastening.

To redistribute the light flux of the device in space, including to create an explosion-proof light fixture of the searchlight type, a reflector 34 with a light center (focus) F combined with the luminous body 35 of the lamp 6 is mounted on the mandrel 3 in the form of a flange .

Means of fastening the device at the object, it is advisable to perform in the form of a bracket 14 mounted on the rear of the input box 9. Mandrel 3 in the form of a flange that repeats the shape of the cover 10 of the input box 9, is installed on the body of the latter using two ring loops 22, providing folding (opening) mandrel 3 and / or cover 10 when replacing a lamp or ballast by unscrewing the screws 32 during installation and operation of the device.

Inside the input box 9 at high tide, a ground screw 34 is also installed.

The light device operates as follows.

When connecting the device to an industrial network at terminal block 12 (see Fig. 2), the ballast generates high-voltage pulse packets (not more than 2.5 kV) for igniting lamp 6 and converts the voltage of the industrial network (220 V, 50 Hz) to the necessary supply voltage and discharge current in the lamp when it enters steady state.

When this lamp 6 generates optical radiation, which can be redistributed in space using the reflector 34.

The advantages of the proposed explosion-proof device are that due to the proposed design option, the dimensions and weight are minimized while optimizing the conditions of heat transfer, increasing explosion safety and improving lighting performance. The device is convenient in operation.

Explosion protection is increased by minimizing the ballast volumes in the explosion-proof enclosure and in the input chamber of the supply network, as well as through the use of a combined explosion channel, including a threaded labyrinth channel and a channel along the planar and cylindrical slots formed by the explosion-proof enclosure units.

Lighting characteristics of the device are improved through the use of high-performance discharge lamps with high light output.

Literature.

1. Auth. St. USSR No. 1158820, class P 21 V 25/12. Publ. B.I. No.20 on 05/30/85

2. "Explosive lamps and accessories." Directory-Catalog 2002 Ed. Technosvet CJSC, St. Petersburg, 199178, V.O., 8th line, d. 78, p. 9.

Claims (10)

1. An explosion-proof light device containing an explosion-proof casing with an optically transparent protective cap sealed in a mandrel, a discharge lamp with a luminous body, a cartridge, a start-up control device and an explosion-proof input box with at least one cable entry, a cover, a terminal block and wires for current supply devices , as well as means for fixing the device to the object, characterized in that the lamp with a cartridge is installed inside the protective cap on the holder of heat-conducting material in heat contact with a massive mandrel in the form of a flange of similar material, with a protective cap mounted on it and equipped with a labyrinth explosion channel connecting the inner cavity of the protective cap with the environment, the holder and the mandrel mounted on the cover of the input box with the formation of the transition chamber to accommodate a free parts of the wires of the current supply means, and the control and starting device is mounted inside the above input box and connected by wires of the current supply means passing through the sealants nnye holes in the holder and cover the inlet box to the lampholder. 2. Explosion-proof light device according to claim 1, characterized in that the lamp holder with a cartridge is made in the form of a bead with a flange mounted by sliding fit along the side surface of a massive mandrel mounted in the axial hole in the form of a flange of an intermediate annular element with the formation of a labyrinth explosion channel. 3. Explosion-proof light device according to claim 1, characterized in that the holder in the form of a glass with a flange is sealed on an intermediate ring element made of heat-conducting material with a thread on the periphery and planted by a reciprocal thread in the axial hole of the mandrel with the formation of a threaded labyrinth explosion channel . 4. An explosion-proof light device according to claim 1, characterized in that the mandrel in the form of a flange is mechanically connected through a seal to an additional cap flange covering the end part of the protective cap. 5. The explosion-proof light device according to claim 1, characterized in that a metal halide lamp, in particular a ceramic metal halide lamp or a high pressure sodium lamp, mounted together with the cartridge coaxially in a protective cap on the bottom of the holder in the form of a glass, is used as a discharge lamp. 6. Explosion-proof lighting device according to claim 1, characterized in that the control and starting device is based on electronic components and has a frameless design with a built-in screwless WAGO block, is filled with a part of the block with a heat-conducting electrical insulating compound, for example, Nomacon type. 7. Explosion-proof light device according to claim 1, characterized in that the input box is equipped with at least one threaded labyrinth explosion channel made by thread in the interface area of the cable entry for connecting the power supply network. 8. The explosion-proof lighting device according to claim 1, characterized in that the input box has a cross-section in the form of a mandrel, is mounted perpendicular to the optical axis of the device, is coupled to the mandrel through an annular seal and mechanically fixed to it by tightening screws. 9. An explosion-proof light device according to claim 1, characterized in that an external diffusely or specularly redistributing optical radiation flux with a light center (or focus) combined with the luminous body of the lamp is mounted on a mandrel in the form of a flange. 10. The explosion-proof light device according to claim 1, characterized in that the means of fastening the device at the object are made in the form of a bracket mounted on the back of the input box.

Images