RU173797U1 - LED lamp - Google Patents

Abstract

The utility model relates to the electrical industry, specifically to electric lighting devices, and can be used for lighting various rooms and objects, as well as street lighting. Provides increased lighting efficiency by increasing the area of illumination and ensuring effective heat dissipation directly from the zone of intense heating of the housing. The device includes at least one housing 1 made in the form of an elongated hollow profile of heat-conducting material. Housing 1 has an upper cavity 2 closed in cross section with a power supply 3 installed in it and a lower longitudinal cavity 4. The lower longitudinal cavity 4 is formed by a central shelf 5 and adjoining two side inclined walls 6 with end grooves 7. A protective transparent screen 8 is installed in the end grooves 7. A central LED module 9 is installed on the central shelf 5. Housing 1 sleep lower lateral female coupling elements 10, cooling ribs 11, with their ends provided on the upper side coupling elements 12 and the upper fastening elements 13, adapted to secure the fixture to a support. The central shelf 5 has a central longitudinal hollow protrusion 14. It is made in the area where the central LED module 9 is located. LED modules 15 are installed on the side inclined walls 6 in the lower longitudinal cavity 2. The side inclined walls 6 have longitudinally placed hollow protrusions 16 made in a pair installation of LED modules 15. On one pair of longitudinal hollow protrusions, cooling fins 11 with upper lateral connecting elements 12 are placed, and other pairs of longitudinal protrusions 16 are provided with additional ribs 17 s cooling ZP 12 f-ly, 2 ill.

Description

The utility model relates to the electrical industry, specifically to electric lighting devices, and can be used for lighting office, administrative, public, technical premises, both as the main one, as well as emergency and emergency lighting for workplaces, rooms, passages, walkways, paths evacuation and emergency exits, lighting of workshops, warehouses, hangars, sports complexes and other industrial facilities, as well as street lighting.

Known LED lamp containing a housing of heat-conducting material, closed by a panel of translucent material, in which a printed circuit board with LEDs and a control unit are installed, while the inner surface of the housing base on which the printed circuit board with LEDs is mounted is made convex, the outer surface of the housing is made finned, and LEDs are combined in two at least branches of series-connected LEDs distributed over the inner surface of the base of the housing in a checkerboard pattern (see, for example, RU 98532, publ. 20.10.2010). The disadvantage of this device is the complexity of the assembly, which requires exact pairing of the convex inner surface of the housing and a concave printed circuit board with LEDs. If the pairing is inaccurate, heat dissipation from the printed circuit board to the housing will be disrupted, which will lead to an increase in the operating temperature of the LEDs and will drastically reduce the reliability of the LED lamp.

A LED lamp is known from the prior art, comprising a housing in the form of an elongated hollow profile of heat-conducting material with two longitudinal partitions forming a middle compartment, in the upper part of which a power supply is located, and two side compartments mounted on the lower side of the housing in its central part, at least one board with LEDs, as well as lids fixed to the end sides of the housing in the form of a transverse section of the housing, holes are made in the form of their transverse sections, on the underside of the case, under at least one board with LEDs, a protective screen is made of optically transparent material, and each of the sides of the case is made with at least one exposure (see, for example, RU 139896, publ. 04/27/2014). This device has inherent disadvantages associated with poor protection from environmental influences. This is due to the fact that the housing is made with through voids on the sides of the housing, into which precipitation, dust and dirt particles are possible, which complicates heat transfer and, as a result, reduces its efficiency and reduces the operating life.

From the current level of technology, a LED lamp mounted on a support is known, adopted for the closest analogue and including at least one housing made in the form of an elongated hollow profile made of heat-conducting material, having an upper cavity closed in cross section with a power supply installed in it and formed central shelf and adjacent to it two side inclined walls with end grooves in which a protective transparent screen is installed, the lower longitudinal cavity with the central LED module installed in it on the central shelf, while the casing is equipped with lower side docking elements, cooling fins with upper side docking elements made at their ends, as well as upper fastening elements made with the possibility of fixing the lamp on a support (see, e.g. , RU 104281, publ. 05/10/2011). The disadvantage of this technical solution is the small angle of illumination, and, as a result, the small area of illumination, which can be increased only by using additional modules.

High-quality lighting is more dependent on its effectiveness, which consists of a number of factors. First of all, this is the area of the illuminated surface, which should be sufficient for the purpose of applying lighting. Another important factor is the intensity of its glow. Unlike other light sources, LEDs are sensitive to high temperatures. When the LED overheats, the luminous flux falls, the color temperature changes, and the service life can be reduced by several times. For example, at a transition temperature of 150 ° C, the light intensity of LEDs can drop by 40%. Efficient heat dissipation from the lighting device contributes to its efficient operation.

The task to which this technical solution is directed is to create a durable LED lamp that provides high-quality lighting.

The problem is solved due to the fact that in the LED lamp mounted on a support and including at least one housing made in the form of an elongated hollow profile made of heat-conducting material, having an upper cavity closed in cross section with a power supply installed in it and formed by a central shelf and adjoining two side inclined walls with end grooves in which a protective transparent screen is installed, the lower longitudinal cavity with the central a central LED module, while the casing is equipped with lower side docking elements, cooling fins with upper side docking elements made at their ends, as well as upper fastening elements made with the possibility of fixing the lamp on a support, according to the technical solution, the central shelf has a central longitudinal hollow ledge made in the area of the central LED module; LED m mounted on the side inclined walls in the lower longitudinal cavity blowing and lateral inclined walls themselves are pairwise disposed hollow longitudinal projections formed in the area of installation of LED modules, wherein one pair of longitudinal hollow projections has cooling ribs on the upper side coupling elements and the other pair of longitudinal projections provided with additional cooling fins.

The LED module is an aluminum board with soldered LEDs.

LED modules can be fastened to the housing by riveting.

The central LED module can be equipped with an optical lens.

The side inclined walls of the housing are preferably located at an angle of 20-30 degrees relative to the protective transparent screen.

The upper fasteners in cross section may have a rectangular shape and size corresponding to the hexagonal head of the bolt.

Protective transparent screen can be made of polycarbonate.

The protective transparent screen can be fixed in the end grooves of the side inclined walls of the housing through a seal made of foamed polyethylene by seaming.

The LED luminaire can be equipped with at least two end caps that accurately repeat the contour of the transverse section of the housing and have recesses in the region of its two cavities.

The power supply can be installed in the upper cavity of the housing by means of guides made in the walls of the housing.

The housing can be made by extrusion.

As the heat-conducting material of the housing, aluminum or an aluminum alloy may be selected.

The lower and upper lateral docking elements can be made with the possibility of fixing their connection using fasteners.

The technical result due to the given set of features is to increase the lighting efficiency by increasing the illumination area by performing in the case of the central shelf with a central LED module and two side inclined walls adjoining to it, on which the light flux can be distributed at an acute angle to the illuminated surface LED modules, in the area of which longitudinal hollow protrusions are made, contributing to an increase in the heating area the surface of the heat-conducting housing directly in the zone of intensive heating of the LED modules and ensuring heat removal from this zone by cooling fins located on the longitudinal hollow protrusions, one pair of which is equipped with upper side docking elements, which together with the lower side docking elements allow you to fasten several cases into a single design, which also affects the increase in the area of illumination with a simultaneous increase in heat dissipation due to the formed ribs and cooling adjacent air duct housings.

In addition, the implementation of longitudinal hollow protrusions provides the installation, if necessary, on LED modules of additional optics in the form of optical lenses, which in turn affect the increase in intensity and, consequently, the lighting efficiency, and also allow the installation of LEDs of higher power.

The essence of the utility model is illustrated by drawings, which depict:

in FIG. 1 - LED lamp, cross section,

in FIG. 2 - connection of lamp housings in cross section.

The LED fixture mounted on the support includes at least one housing 1 made in the form of an elongated hollow profile made of heat-conducting material. Housing 1 has an upper cavity 2 closed in cross section with a power supply 3 installed in it and a lower longitudinal cavity 4. Lower longitudinal cavity 4 is formed by the central shelf 5 and adjacent to it two side inclined walls 6 with end grooves 7. A protective transparent screen 8 is installed in the end grooves 7. On the central shelf 5, central th LED module 9. The housing 1 is equipped with lower lateral connecting elements 10, cooling fins 11 with upper lateral connecting elements 12 made at their ends, as well as upper fastening elements 13 adapted to fix the lamp on a support. The upper lateral docking elements 12 are made in the form of profiled grooves.

The central shelf 5 has a central longitudinal hollow protrusion 14. It is made in the area where the central LED module 9 is located. LED modules 15 are installed on the side inclined walls 6 in the lower longitudinal cavity 2. The side inclined walls 6 have longitudinally placed hollow protrusions 16 made in a pair installation of LED modules 15. On one pair of longitudinal hollow protrusions, cooling fins 11 with upper lateral connecting elements 12 are placed, and other pairs of longitudinal protrusions 16 are provided with additional ribs s 17 cooling.

The lower lateral docking elements 10 and the upper lateral docking elements 12 are made in the form of a groove on one side of the housing 1 and a spike on the other and allow you to connect several housings 1 together, thereby increasing the power of the lamp and increasing the area of the illuminated surface. The lower and upper lateral docking elements 10, 12 are made with the possibility of additional fixation of their connection using fasteners. For this purpose, profiled grooves are made at their ends to enable rigid bonding of the bodies to each other using fasteners, preferably self-tapping screws.

The 9.15 LED modules are aluminum boards with LEDs soldered onto them. They are attached to the housing 1 by riveting. This embodiment ensures the manufacturability of the process, the reliability of fastening the modules to the lamp housing, tight contact between the light module and the housing and, as a result, high-quality heat removal from the light module, thereby increasing the period of reliable operation.

The central longitudinal hollow protrusion 14 made in the Central shelf 5 allows you to remove heat directly from the place of intense heating of the Central LED module 9, increasing the heating area of the housing, and also makes it possible to use the LED module with powerful LEDs and secondary optics in the form of optical lenses 19.

The side inclined walls 6 of the housing 1 are located at an angle of 20-30 degrees relative to the protective transparent screen 8. The installation of LED modules 15 on the side inclined walls 6 of the housing 1 makes it possible to expand the light intensity curve by more than 120 degrees.

To facilitate the installation of the lamp, the upper fastening elements 13 in a cross section have a rectangular shape and size corresponding to the hexagonal head of the bolt, due to which the problem of connecting the lamp housing with fastening elements for fixing to any support is solved.

The protective transparent screen 8 is made of an optically transparent material, preferably polycarbonate, and is fixed in the end grooves 7 of the side inclined walls 6 of the housing 1 through a seal made of foamed polyethylene by rolling, which allows it to be fixed without the possibility of shear. The tightness of the luminaire is ensured, the processability is increased, since the proposed implementation eliminates the screws, screws or bolts for fastening the protective coating to the body. This, in turn, saves materials and production time of the lamp, making it possible to exclude the process of twisting fastening elements (screws, screws). Efficiency of work is also ensured by increasing the reliability of the luminaire, as it eliminates the possibility of a violation of the tightness of the luminaire and the ingress of moisture and other factors that disrupt the luminaire.

The LED lamp is equipped with at least two end caps that accurately repeat the contour of the transverse section of the housing 1 and have recesses in the region of its two cavities 2.4. Fasteners can be self-tapping.

The power supply 3 is installed in the upper cavity 2 of the housing 1 specially allocated for it by means of guides 18 made in the walls of the housing 1. Installation with maximum adaptability, but at the same time high reliability.

The housing 1 is made integral from a heat-conducting material, preferably aluminum or an aluminum alloy, by extrusion. This embodiment saves time on the assembly of the housing and materials for fasteners.

LED lamp works as follows. After fixing the device to the support and connecting to the mains, an alternating voltage is supplied to the power supply 3. In the power supply 3, the voltage is converted from AC to DC with stabilized current. The stabilized current from the power supply 3 is supplied to the central LED module 9 and the LED modules 15. The LEDs of the modules 9, 15 begin to emit light. The light flux emitted by the central LED module 9 is directed perpendicular to the illuminated surface, and the light fluxes of the LED modules 15 are directed at an angle corresponding to the angle of inclination of the side inclined walls 6, while increasing the area and intensity of illumination. The generated heat from the LEDs is transmitted to the housing 1 and is removed to the atmosphere. More intense heating occurs in the installation area of the LED modules 9, 15. Due to the increased surface area in this zone by means of longitudinal hollow protrusions 16 and 14 in the side inclined walls 6 and the central shelf 5, accelerated heat transfer and heat removal to the surrounding using cooling fins 11 and additional cooling fins 17 directly from the intense heating zone. The upper cavity 2 closed in cross section with the power supply 3 installed in it limits the heat supply from the LED modules 9, 1 to the power supply 3, thereby ensuring its effective cooling, which leads to an increase in its service life of the device.

When a luminaire having more than one body 1 is used, the bodies 1 are connected in a row by means of the lower and upper lateral docking elements 10, 12. An additional increase in the area of the illuminated surface, the light intensity, and the power of the lamp are increased. The power is limited by the ability of the lamp to remove heat to prevent overheating and, as a result, the failure of the lighting device. When several buildings 1 are fastened between them, due to the implementation of cooling fins 11, 17, channels for air ventilation are formed, which prevents overheating of the lamp. This design of the lamp provides effective cooling of the LEDs and the power source, which significantly increases the reliability of the product.

Thus, the proposed lamp has several advantages: improving heat dissipation from the LED module, increasing the manufacturability of the lamp housing, reducing the complexity of the assembly of the product, increasing the operational reliability of the lamp, as well as the possibility of using various types of LEDs, secondary optics, the largest possible angle of illumination the formation of various non-standard light intensity curves. The device allows you to optimally realize the diverse needs of consumers by changing the power of the lamp by increasing the number of installed cases, the direction of light, overall dimensions and shape of the elements of the device. Also, the design of the lamp allows you to install it on various supports.

Claims (13)

1. The LED lamp, mounted on a support and comprising at least one housing made in the form of an elongated hollow profile made of heat-conducting material, having an upper cavity closed in cross section with a power supply installed in it and formed by a central shelf and two side panels adjoining it inclined walls with end grooves in which a protective transparent screen is installed, a lower longitudinal cavity with a central LED module mounted in it on the central shelf, while the enclosure is equipped with lower side docking elements, cooling fins with upper side docking elements made at their ends, as well as upper fastening elements configured to fix the lamp on a support, characterized in that the central shelf has a central longitudinal hollow protrusion made in the central LED module, LED modules are installed on the side inclined walls in the lower longitudinal cavity, and the side inclined walls themselves are pairwise sized wide hollow protrusions made in the installation area of the LED modules, moreover, cooling fins with upper lateral connecting elements are placed on one pair of longitudinal hollow protrusions, and other pairs of longitudinal protrusions are provided with additional cooling fins. 2. The LED lamp according to claim 1, characterized in that the LED module is an aluminum board with LEDs soldered to it. 3. The LED lamp according to claim 1, characterized in that the LED modules are mounted to the housing by riveting. 4. The LED lamp according to claim 1, characterized in that the central LED module is equipped with an optical lens. 5. The LED lamp according to claim 1, characterized in that the side inclined walls of the housing are located at an angle of 20-30 degrees relative to the protective transparent screen. 6. The LED lamp according to claim 1, characterized in that the upper fastening elements in a cross section have a rectangular shape and size corresponding to the hexagonal head of the bolt. 7. The LED lamp according to claim 1, characterized in that the protective transparent screen is made of polycarbonate. 8. The LED lamp according to claim 1, characterized in that the protective transparent screen is fixed in the end grooves of the side inclined walls of the housing through a seal made of foamed polyethylene by seaming. 9. The LED lamp according to claim 1, characterized in that it is equipped with at least two end caps that accurately repeat the contour of the transverse section of the housing and have recesses in the region of its two cavities. 10. The LED lamp according to claim 1, characterized in that the power supply is installed in the upper cavity of the housing by means of guides made in the walls of the housing. 11. The LED lamp according to claim 1, characterized in that the casing is made by extrusion. 12. The LED lamp according to claim 1, characterized in that aluminum or an aluminum alloy is selected as the heat-conducting material of the housing. 13. The LED lamp according to claim 1, characterized in that the lower and upper lateral docking elements are made with the possibility of fixing their connection using fasteners.

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