RU188207U1 - EXPLOSION LIGHT - Google Patents

Abstract

The utility model relates to lighting engineering, in particular, to explosion-proof luminaires with semiconductor light sources and is intended for installation indoors or outdoors to illuminate areas that are explosive in mixtures of gases, vapors, dust and fibers, as well as for use in wet and dusty areas. The technical result consists in reducing the cost of manufacturing and in providing explosive facilities with optimal high-quality, energy-efficient lighting. Explosion-proof lamp contains a profiled housing composed of two parts: the bearing part of the housing and its cover, interconnected with a gap; the power supply is housed in a case coated with a heat-conducting dielectric coating and mounted on the inner surface of the cover of the shaped body, the optical system is equipped with a protective optically transparent element made in the form of a rigid dome-shaped shell, the base of which along the perimeter has an outer protrusion mounted on the outer surface of the supporting part of the shaped body using a metal flange. 6 c.p. f-ly, 3 ill.

Description

The inventive utility model relates to lighting engineering, in particular, to explosion-proof luminaires with semiconductor light sources and is intended for installation indoors or outdoors for lighting areas explosive by mixtures of gases, vapors, dust and fibers in accordance with GOST IEC 60079-10- 1-2011, GOST IEC 6007 9-10-2-2011, as well as for operation in wet and dusty areas.

State of the art

Known explosion-proof lamp with LEDs (RU 2475673 C1, IPC F21V 25/12, published 02/20/2013), which contains a housing of heat-conducting material with a first compartment in the form of a gap formed by a protective glass and a holder partially finned on the back side on which it is installed in thermal contact, a flat explosion-proof LED emitter in the form of a cluster with LEDs assembled in nodes of a rectangular coordinate grid on a board with an aluminum base. The second insulated compartment adjacent to the back of the holder with an electronic converter installed in it is made explosion-proof with dead-end or transit cable entries mating with the compartment through a protected thread forming labyrinth explosion channels connecting the internal volume of the compartment with the environment.

The analogue has a number of significant drawbacks, among which there is the great difficulty of providing the type of protection “d” “flameproof enclosure” of the compartment with the LED emitter, as well as the mutual heating of the LEDs and the power source located in a single housing with high thermal conductivity, which, under the conditions of restriction requirements maximum surface temperature, leads to the need to reduce the power of the luminaire or increase its overall dimensions to increase the heat sink area. It also reduces the resource and reliability of the power supply, since its contribution to heat generation is much lower than that of LEDs. Also, for the formation of light intensity curves according to GOST R 54350-2015, an analogue requires the use of additional secondary optics for each LED, and this makes it impossible to fill the optical compartment with a compound and reduces the level of explosion protection.

Known explosion-proof lamp (RU 136531 U1, IPC F21V 25/12, published 01/10/2014), comprising a housing, a shockproof light-transmitting screen on the front side, a light module, a power supply unit, characterized in that the housing is made of one-piece, consisting of two zones: zones of the light module in the form of a disk on which the light module board and an impact-resistant light-transmitting screen are fixed, fixed on the housing by means of fixing bolts on the flange, sealing the zone by pressing the seal with a groove along the counter ring a large girdle in the housing, and the zone of the power supply unit, made in the form of a rectangular niche projecting in the opposite direction in the center of the disk, the disk and the rectangular niche on the back side being combined by a set of transverse and longitudinal vertical ribs, and the light module contains at least one solid-state semiconductor source Sveta.

The main disadvantage of the analogue is that it can only be designed for a certain power. If a more powerful luminaire is needed, the development and manufacture of a new housing, accessories for its injection molding, accessories for casting a light-transmitting screen, reconfiguration of production and additional confirmation of compliance with the safety requirements of equipment for working in explosive atmospheres as a new product are required.

Another disadvantage of the analogue is the use of polycarbonate as a light transmission screen. Such a screen, even when UV stabilizers are added during the manufacturing process, is subject to a decrease in light transmission during operation (several percent per year), and is also not resistant to mechanical surface damage (mashing) when used in the presence of dust microparticles. Finally, the power supply in the analog is also located directly below the heat-emitting LED emitter, which leads to the consequences described above.

The technical result of the claimed utility model is the creation of a design that allows the production of a wide range of explosion-proof luminaires in terms of power, lighting performance at minimal cost for additional equipment, reconfiguration of production, without the need for additional confirmation of each model for compliance with the safety requirements of equipment for use in explosive atmospheres.

Utility Model Essence

A utility model can be characterized by the following set of features:

Explosion-proof lamp containing a profiled housing made of aluminum alloy; an optical unit located on the surface of the profiled body and comprising an LED matrix and a protective optically transparent element; power source; the current lead connecting the power source and the LED matrix, the profiled housing is composed of two parts and includes the carrying part of the housing and its cover, interconnected with a gap, the optical system is equipped with a protective optically transparent element made in the form of a rigid dome-shaped shell, the base of which around the perimeter an external protrusion mounted on the outer surface of the supporting part of the profiled body using a metal flange, while between the protrusion of the thin-walled dome and the body of the mouth A metal gasket has been renewed, and a gasket has been placed between the metal flange and the protrusion of the thin-walled dome, the power supply is housed in a case coated with a heat-conducting dielectric coating and fixed to the inner surface of the cover of the shaped body so that an air gap is formed between the surface of the coating and the bearing part of the body, and the current lead connected to the LED matrix through a sealed input made in the wall of the domed shell.

The essence of the utility model is illustrated by graphic materials, where in FIG. 1 shows the design of the lamp.

The luminaire housing consists of two profile elements: a heat sink profile 1-1 and a cover profile 1-12. The heat sink profile 1-1 has internal finned cavities-air ducts 1-14, which can improve the efficiency of heat dissipation, reduce the weight and dimensions of the lamp. The power source 1-11 is located on the bottom of the cover 1-12 of the housing so that between it and the heat sink profile 1-1 there is an air gap sufficient to eliminate the effect of mutual conductive heating.

Profiled body elements 1-1 and 1-12 are made of aluminum alloy. At least one explosion-proof optical assembly 2-3 (Fig. 2), consisting of a LED matrix 1-0 and a protective glass cover 1-2, and mounted on the surface of the profile 1-1 of the housing, is located on the heat-sink profile 1-1 of the housing by means of a metal flange 1-5 through a metal strip 1-3 and an additional gasket 1-4, for example, of silicone rubber, a power supply source 1-11, located on the bottom of the cover 1-12 of the housing 1-1 and connected to the LED matrix 1 -0 by means of a current lead 1-8. Explosion protection of type “d” of the optical unit is ensured by its design (Fig. 1) according to GOST IEC 60079-1-2011.

One part of the flameproof enclosure is formed by the wall of the housing 1-1, the second - a protective cap of borosilicate glass 1-2. The flameproof connection of the two parts of the shell is achieved using a metal strip 1-3, installed between the housing and the cap, providing the required minimum length of the flameproof joint and the gap. Outside the flameproof enclosure, an additional silicone rubber gasket 1-4 is installed, which provides protection against the ingress of dust and moisture into the enclosure, thus satisfying the requirements of “type of protection against dust ignition" t "". The cap is pressed against the housing by means of a metal flange 1-5 and screws 1-6. The current lead 1-8 is inserted into the shell through a metal frame 1-9 embedded in the shell wall, which is an inseparable whole with it, and sealed in the frame by means of a special organosilicon compound 1-10. Glass protective cap 1-2 has the thickness necessary for explosion protection and has special optical properties to form the required light intensity curve according to GOST R 54350-2015, which is achieved by choosing the curvature (both spherical and aspherical) of its outer and inner surfaces. Thus, there is no need to use additional optical elements. Explosion protection of type “m” of the power source 1-11 is ensured by the fact that the converter assembled on the printed circuit board is placed in an aluminum alloy housing and filled with a special heat-conducting organosilicon compound.

The primary power cable to the luminaire is connected in an explosion-proof junction box, which provides one of the types of protection “flameproof enclosure" d "" or "increased protection of type" e ", if necessary. The specified junction box can serve as a transit for group connection of fixtures, which simplifies the electrical installation of an explosion-proof lighting system.

Between themselves in a single whole cover 1-2 and the heat sink profile 1-1 of the housing are connected by means of end perforated covers 2-2 (Fig. 3) made of impact-resistant non-combustible polymer material. The task of obtaining a wide range of power and lighting characteristics of explosion-proof fixtures is solved by the fact that, depending on the required power, the required length of the heat-sink profile is selected (Fig. 2), on which two or more explosion-proof optical nodes 2-3 are located, identical in design, with glass protective caps having the necessary optical properties. The design of the lamp allows you to attach to it any necessary installation device 2-4 using special grooves 1-15 on the profile, which solves the problem of universal mounting.

Claims (14)

1. An explosion-proof luminaire comprising an aluminum alloy housing made up of two parts and including a bearing portion of the housing and its lid; an optical unit including an LED matrix and a protective optically transparent element made in the form of a rigid dome-shaped shell, the base of which has an outer protrusion around the perimeter, while a metal gasket is installed between the protrusion of the dome-shaped shell and the bearing part of the housing; power source; a conductor connecting the power source and the LED matrix, characterized in that: the bearing part of the housing and its cover are profiled and interconnected to form an air gap; the optical unit is placed on the outer surface of the supporting part of the profiled body and secured with a metal flange, while a metal spacer is installed between the protrusion of the domed shell and the surface of the body, and a gasket is placed between the metal flange and the protrusion of the thin-walled dome, the power supply is placed in a case coated with a heat-conducting dielectric coating and fixed on the inner surface of the cover of the shaped body so that an air gap is formed between the surface of the coating and the bearing part of the body. 2. Explosion-proof lamp according to claim 1, characterized in that the current lead is connected to the LED matrix through a sealed entry made in the wall of the domed shell. 3. The explosion-proof lamp according to claim 2, characterized in that the current lead is inserted into the shell through a metal frame embedded in the wall, which forms an indivisible whole with it, and is sealed in the frame by means of an organosilicon compound. 4. Explosion-proof lamp according to claim 1, characterized in that the heat sink profile has internal finned air ducts, which can improve the efficiency of heat dissipation, reduce the weight and dimensions of the lamp. 5. An explosion-proof lamp according to claim 1, characterized in that the power supply is filled with a heat-conducting organosilicon compound. 6. The explosion-proof lamp according to claim 1, characterized in that the thin-walled dome has the thickness necessary for explosion protection and has optical properties to form the required light intensity curve, which is achieved by choosing the curvature of its outer and inner surfaces. 7. Explosion-proof lamp according to claim 1, characterized in that it contains two or more optical nodes located on the surface of an elongated heat-sink shaped body.

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