RU87780U1 - Explosion-proof LED luminaire - Google Patents

Abstract

1. Explosion-proof LED lamp, comprising an optical block on the LEDs mounted inside a transparent protective cap, a power supply converter connected by current supply elements to the LEDs of the specified block and placed in an explosion-proof input box with at least one cable entry, characterized in that A light-transmitting casting body is introduced, occupying the free volume inside the transparent protective cap. ! 2. The explosion-proof lamp according to claim 1, characterized in that the light-transmitting filling body contains spherical voids. ! 3. The explosion-proof lamp according to claim 1, characterized in that a motion sensor is introduced, connected by current supply elements to an inputted control unit, connected by current supply elements to a power supply converter.

Description

The utility model relates to lighting engineering, in particular, to protected light devices, and can be used for general lighting of objects in explosive atmospheres, for example, in underground mine workings.

Known luminescent mine lamp according to RU 48390, selected for analogue. This lamp contains a housing divided into two separate cameras. An input box with cable entry is located in one chamber, and a cartridge with a fluorescent lamp and a massive autotransformer in the other.

The disadvantages of this lamp are the small life of the fluorescent lamp compared to the LED and the time-consuming manufacturing of a massive autotransformer.

A known light device controlled by a motion sensor according to EP 1947912, selected as an analogue. This light fixture contains a lampholder and a fragile cap connected to it with a lamp and a motion sensor installed inside.

The disadvantage of this light fixture is that it cannot be used in an explosive atmosphere due to the presence of a fragile cap and the absence of an explosion-proof input box.

Known explosion-proof lighting device with LEDs according to RU 2251050, selected for the prototype. This explosion-proof light fixture contains an optical unit with LEDs, a power supply converter connected by current supply elements to the LEDs of the specified unit and placed in an explosion-proof input box with dead-end or transit cable entries. The optical unit, mounted inside a volumetric sealed transparent cap and rigidly fixed with the cover of the input box, contains polygonal boards with LEDs soldered to them, assembled axially on a rod that pulls them together. The light coming from the LEDs is refracted by the walls of the transparent cap. The operation of this light fixture does not depend on the presence of a person in the lighted room.

The disadvantage of this explosion-proof lighting device is the large ballast volume of air contained in the sealed cap. The pressure and temperature of said air rises sharply with a possible explosion, which can destroy the hood from the inside.

Another disadvantage of this light fixture is the lack of protection against blinding due to insufficient refraction of light by the walls of a transparent cap.

An additional disadvantage of the prototype is that this light fixture consumes electricity to illuminate the room even when this is not necessary, i.e. when there are no people in the room.

The purpose of the proposed utility model is to create a luminaire with improved explosion protection properties, protection from dazzle, as well as significantly saving energy.

This goal is achieved in that the explosion-proof lamp on the LEDs, like the prototype, contains an optical unit on the LEDs mounted inside a transparent protective cap, a power supply converter connected by current supply elements to the LEDs of the specified unit and placed in an explosion-proof input box with at least one cable entry. In contrast to the prototype, a light-transmitting casting body was introduced, occupying the free volume inside the transparent protective cap.

The goal is achieved by the fact that the light-transmitting filling body contains spherical voids.

Achieving the goal is also facilitated by the fact that a motion sensor is introduced, connected by elements of a current supply with an inserted control unit, connected by elements of a current supply with a converter of the supply network.

The essence of the utility model is illustrated by a drawing of an explosion-proof lamp with LEDs.

Explosion-proof LED lamp contains an optical unit, including a cylindrical cooling radiator 1 with radial cylindrical grooves 2 on the side surface and LEDs 3 mounted on the bottom 4 of each groove 2. A cooling radiator 1 made of a heat-conducting material, for example, aluminum alloy, is coaxially mounted inside a transparent protective cap 5 made of impact-resistant material, for example, polycarbonate, is rigidly fixed to the substrate 6 with screws 7 and fixed with a clamping nut 8.

A pre-foamed, cold-cured polymer light-transmitting material, for example, Pentelast-712 grade A compound, is poured into the cavity of the cap 5. As a result, the free volume inside the cap 5 is occupied by a light-transmitting filling body 9 containing spherical voids 10 of air bubbles.

The LEDs 3, preferably four for each groove 2, are fastened with screws 11 to the bottom 4 of the groove 2 of the radiator 1 and are connected by current lead elements 12 located in the groove 13 with the electronic converter 14 of the supply network.

The metal sleeve 15 spans two parts around the periphery:

on the one hand - cap 5, on the other hand - the input box 16.

The cap 5 from the side opposite to the dome 17 is held in the sleeve 15 by an annular element 18 sealed with sealing gaskets 19.

Inside the input box 16 are installed connected by current supply elements (not shown in FIG.) An electronic control unit 20 and an electronic converter 14 of the supply network. In the domed part of the protective cap 5 there is a radio wave motion sensor 21 rigidly fixed to the base 22 of the cylindrical cooling radiator 1 and connected by current lead elements 23 located in the groove 24 to the control unit 20.

The mating surfaces of the coupling 15 and the input box 16 form an annular explosion channel 25. A metal cover 26 surrounds the input box G6 around the periphery with the formation of an annular explosion channel 27. Each explosion channel 25, 27, which provides a possible output of a heated and high air pressure, from the outside is protected by an annular seal 28 of circular cross-section, ensuring the tightness of the input box 16 under normal operating conditions and displaced by the air leaving the explosion.

The input box 16 is equipped with a ground screw 29 and a cable entry 30 for connecting to the power supply converter 14 through the terminal block 31 of the current-carrying cable of the power supply network, sealed with a sealing gasket 32.

The protection of the elements of the control unit 20, the converter 14 of the supply network and the soldering points of the electrical connections (not shown in FIG.) By a heat-conducting electrical insulating compound, for example, of the Pentelast-714 type, eliminates the formation of a spark when contact breaks in the soldering zone.

When connected to the mains, the lamp operates in standby mode to save energy. When a large object, such as a person, is moving, the radio wave motion sensor 21 sends a message to the control unit 20, which sends a control signal to the converter 14 of the supply network for an instantaneous transition from the standby mode of energy saving to the operating mode for supplying power to the LEDs 3. In the absence of movement of a large object of the radio wave the motion sensor 21 sends a reporting signal to the control unit 20, which sends a transition control signal (delayed in time, for example p, 4 minutes) from the operating mode of power supply to LEDs 3 to the standby mode of energy saving. The light coming from the LEDs 3 is refracted at the interfaces between the surfaces of the casting body 9 and the spherical air voids 10.

The introduction of a light-transmitting filling body, occupying the free volume inside the transparent protective cap, prevents the destruction of the cap from the inside with a possible explosion, which improves the explosion-proof properties of the lamp.

The spherical voids contained in the light-transmitting filling body refract the light coming from the LEDs, which protects against blinding.

The introduction of a motion sensor connected by current supply elements to the introduced control unit, connected by current supply elements with a power supply converter, allows the lamp to turn on automatically in the presence of a person and turn off when a person leaves the working area. This contributes to significant energy savings.

Claims (3)

1. Explosion-proof LED lamp, comprising an optical block on the LEDs mounted inside a transparent protective cap, a power supply converter connected by current supply elements to the LEDs of the specified block and placed in an explosion-proof input box with at least one cable entry, characterized in that A light-transmitting casting body is introduced, occupying the free volume inside the transparent protective cap. 2. The explosion-proof lamp according to claim 1, characterized in that the light-transmitting filling body contains spherical voids. 3. The explosion-proof lamp according to claim 1, characterized in that a motion sensor is introduced, connected by current supply elements to an inputted control unit, connected by current supply elements to a power supply converter.