RU164538U1 - LED LAMP - Google Patents

Abstract

An LED lamp comprising a radiator housing in the form of an elongated heat-sink profile with two lateral longitudinal ventilation channels with open ends, the channels being connected by support and carrier plates, end caps with holes, fixture fasteners, light modules, including printed circuit boards and LEDs mounted on printed circuit boards, a power supply unit with electrical wiring connected to the printed circuit boards, and protective screens made of optically transparent material, characterized in that in the upper part of each of the lateral longitudinal ventilation channels of the radiator case, exhaust openings are made, the total area of exhaust openings of each ventilation duct is 80-120% of the total area of openings in the open ends of the ventilation duct, the inner and outer surfaces of the walls of the ventilation ducts being wavy with a wave height to wave step from 1.2 to 2.5; in addition, the lamp contains at least two light modules located on the base plate, the total area of the light-emitting surfaces of all light modules is 40-60% of the area of the base plate.

Description

LED lamp refers to lighting engineering, namely, to designs of luminaires with light sources in the form of light emitting diodes, and is intended for lighting streets, roads, territories of transport hubs and industrial enterprises, parking lots, gas stations, warehouse complexes, indoor and outdoor lighting of industrial buildings, sports grounds and other facilities.

Known lamp LED and heat sink profile as its body [1], which contains a body-radiator of heat-conducting material with fins, two end caps, at least one light module located in the body, at least one external power source, at least one monolithic translucent a protective screen made of impact-resistant material with lenses covering the corresponding light module. As a radiator case, a drawn heat-sink profile is used, which is formed by a base plate with U-shaped channels dividing the body into internal and external parts, light modules and screens are mounted in the U-shaped part with fastening to the U-shaped channels, and the outer part contains ribs, the power supply compartment, made in the form of a through closed loop, in the cross section of which there are channels for fastening the end caps, T-shaped grooves for mounting the lamp.

The disadvantages of this analogue are:

1) Limited heat dissipation and heat transfer, since a monolithic translucent protective screen made of impact-resistant material with lenses covering the corresponding light module creates conditions for the formation of an unventilated volume under this screen, preventing convective heat transfer during the operation of the lamp;

2) U-shaped channels contained in the base plate of variable thickness weaken the cross section of the plate, reducing its strength when deformations and mechanical stresses occur due to temperature changes during the operation of the lamp;

3) The cross-sectional shape of the case-radiator is not rational according to the criterion of material consumption, since the size and number of heat-removing fins can be reduced.

Known LED lamp and heat sink profile as its case [2], which contains a radiator case with printed circuit boards with light sources mounted on it, a translucent screen to protect these boards from external influences, end caps and an external power source, and as a case, radiator used a heat-sink profile made of aluminum alloy with a U-shaped cross section and a base made in the form of a plate, on the surface of which there are longitudinal U-shaped elements shaped, of which the central U-shaped element is located along the longitudinal plane of symmetry, and the side walls of the profile are elements formed by closed contours of rectangular cross section, the outer side surface of the radiator body is made in the form of a smooth anodized surface or a surface with a polymer dust-repellent coating .

The disadvantages of this analogue are:

1) Insufficiently efficient heat dissipation during the operation of the luminaire, since convection heat transfer during the movement and mixing of the mass of unevenly heated air is prevented by end caps, as well as slow heat transfer in the corners of the internal space of the aluminum profile formed by closed rectangular contours;

2) The low reliability and efficiency of light output of LEDs, as a consequence of the above in paragraph 1 is not enough effective heat dissipation during the operation of the lamp;

3) The low strength and stiffness of the housing, in which the U-shaped heat-sink profile has a base made in the form of a plate, on the surface of which there are longitudinal U-shaped elements, in addition, there is one central U-shaped groove on the side of the upper surface . Along with other features of the analogue, the central groove significantly reduces the strength and rigidity of the device body;

4) Insufficient efficiency of the housing design according to the criterion of material consumption, since the low strength indicated in paragraph 2 above, as well as the low rigidity of the housing, can be compensated by an increase in thickness, which means an additional material consumption for the plate specified in paragraph 2 connecting the elements formed by closed rectangular loops sections.

The closest analogue of the proposed device, selected as a prototype, is a LED lamp [3], comprising a radiator body, end caps, a lamp mount, a printed circuit board made of heat-conducting material, LEDs mounted on a printed circuit board, and a power supply with electrical wiring connected to the printed circuit board, and a protective screen made of optically transparent material, while the radiator case is made in the form of an elongated profile with a longitudinal vertical wall and is open ends, two longitudinal vertical partitions, forming in the radiator case an upper compartment with upper and lower planes, two lateral closed compartments and a lower compartment having a PCB fixing plane, wherein a longitudinal vertical wall connects the lower plane of the upper compartment and the PCB fixing plane, a power supply unit is located in the upper compartment of the radiator case, while two longitudinal vertical walls are installed with the possibility of forming a central heat-insulating cavity, in which The lower part of the electrical wiring of the power supply unit, and two side ventilation cavities, in which the mounting plates of the fixture fastening element are located, are located. The outer side surface of the radiator body in the known lamp is made in the form of a smooth anodized surface or a surface with a polymer dust-repellent coating.

The disadvantages of the LED lamp selected as a prototype are:

1) The low reliability of the luminaire and the limited scope of its application, since the design of this luminaire operates using the exhaust pipe effect, which is realized in this device if the luminaire is installed at a certain angle to the illuminated surface, since only in this case a traction is formed in this design air and the specified effect of the exhaust pipe is created when the air flow passes through the slots in the end caps and through the longitudinal channels made e in the side compartment of closed-body radiator with open ends. Thus, if the lamp is installed without tilting, the effect of the exhaust pipe does not occur, heat transfer decreases, the temperature of the LEDs increases, as a result, their light output decreases and degradation increases, which reduces the reliability of the lamp and limits its scope;

2) The low heat exchange rate of the luminaire elements with the environment, since the protective screen, although made of optically transparent material, overlaps the board with the LEDs installed on it throughout its area, which prevents the convective heat removal from the board and from the LEDs in the direction of their light flux , reduces the intensity of heat transfer in the lamp and, due to possible overheating, reduces, as noted above, the reliability of the lamp and limits its scope;

3) In addition, there is a low intensity of heat removal from the casing and the board of the LED lamp, since the outer side surface of the casing-radiator is made in the form of a smooth surface, which reduces the heat transfer intensity compared to a non-smooth, for example, corrugated surface.

The technical result achieved is to eliminate the disadvantages of the prototype, namely, to increase the reliability of the luminaire and to increase the light output of the LEDs by intensifying the heat dissipation generated during the operation of the luminaire by constructively providing enhanced heat exchange of the luminaire elements with each other and with the environment. Improving the reliability of the operation of the lamp, the intensification of heat transfer and, as a result, the improvement of light output is achieved in inextricable structural and functional connection with the design features of the proposed LED lamp, including increasing the strength of the housing-radiator of the lamp, its rigidity and reducing material consumption.

The specified technical result is achieved by the fact that: in the upper part of each of the lateral longitudinal ventilation channels of the radiator case, exhaust openings are made, the total area of the exhaust openings of each ventilation duct is 80-120% of the total open area in the open ends of the ventilation duct, with internal and external the surface of the walls of the ventilation ducts are made wavy with a ratio of wave height to wave step from 1.2 to 2.5; in addition, the lamp contains at least two light modules located on the base plate, the total area of the light-emitting surfaces of all light modules is 40-60% of the area of the base plate.

The essence of the utility model is illustrated by the following graphic materials presented in FIG. 1 - FIG. 3.

FIG. 1: LED lamp with two light modules (general view, in isometric view, turned upward by the light-emitting surfaces of the light modules).

FIG. 2: housing-radiator of the LED lamp (a general view, in isometric view, is turned down by the light-emitting surfaces of the light modules).

FIG. 3: housing-radiator of the LED lamp with a power supply installed in it (side view, turned by the light-emitting surfaces of the light modules down).

The LED lamp consists of a radiator housing 1 in the form of an elongated heat sink profile with two lateral longitudinal ventilation channels 2 with open ends, the channels being connected by a supporting 3 and a carrier 4 plates, end caps 5 with holes, fixture fasteners 6, light modules 7, including printed circuit boards and LEDs mounted on printed circuit boards, a power supply unit with electrical wiring 8 connected to the printed circuit boards, and protective shields 9 of optically transparent material. In the upper part of each of the lateral longitudinal ventilation channels 2 of the radiator casing 1, exhaust openings 10 are made, the inner 11 and outer 12 surfaces of the walls of the ventilation channels being made wavy.

Improving the reliability of the operation of the LED lamp and expanding the scope of its application is achieved through the use of the "exhaust pipe" effect, which in the proposed device is realized at any angle of inclination of the LED lamp to the illuminated surface, even at an angle of inclination of 0 °. This effect is as follows: the air inside the ventilation channels 2, during the operation of the lamp is heated, i.e. its temperature becomes higher than the temperature of the air outside the lamp, due to which a pressure difference is created inside the ventilation channels 2 and outside, resulting in air draft. Heated air from the ventilation ducts 2 passes through the exhaust openings 10, freeing a certain amount for colder air coming from the environment through the ventilation ducts 2 through the openings at their ends. As a result, the heat transfer rate increases and the temperature of the LEDs decreases, which helps to increase their light output and reduce degradation, which increases the reliability of the lamp. The total area of the exhaust openings 10 for each ventilation channel 2 is 80-120% of the total area of the openings in its open ends. If the total area of the exhaust openings 10 is less than 80% of the total area of the openings in the open ends of the channel 2, then the heat transfer intensity is insufficient. With increasing area of the exhaust openings 10, the heat transfer intensity increases. However, if the total area of the exhaust openings 10 is more than 120% of the total area of the openings in the open ends of the channel 2, then the mechanical strength of the design of the casing-radiator is significantly weakened and the heat transfer intensity decreases.

In order to increase the heat transfer rate in addition to the “exhaust pipe” effect, the inner 11 and outer 12 surfaces of the walls of the ventilation ducts 2 are made wavy with a ratio of wave height h to wave step t from 1.2 to 2.5. Such a technical solution leads to an increase in the area of the cooled surface and, as a result, to an increase in the heat transfer intensity compared to the smooth walls of the ventilation ducts 2. Moreover, the influence of the wave-like surface becomes insignificant if the indicated ratio is less than 1.2. With an increase in this ratio, the heat transfer area increases, however, with an increase in this ratio in excess of 2.5, the material consumption increases, and the heat transfer intensity increases slightly.

In order to increase reliability, the lamp contains at least two light modules 7. Moreover, if one light module 7 fails, the functioning of the proposed lamp does not stop completely, but only partially. With the increase in the number of modules 7, the reliability of the operation of the lamp as a whole increases.

In addition, improving the reliability of the LED lamp is achieved by the fact that the light-emitting surfaces of the light modules 7 overlap the base plate 3 of heat-conducting material only in part of the area of the base plate 3, which intensifies the heat removal from the base plate 3 in that part of its surface that is not covered by the light emitting the surface of the light modules 7. The total area of the light-emitting surfaces of all light modules 7 is 40-60% of the area of the base plate 3. If the total area of the light of the radiating surfaces of all light modules 7 is more than 60% of the area of the base plate 3, the area of heat removal from the surface of the base plate 3 not occupied by the light-emitting surface of the light modules 7 is insufficient for the efficient operation of the LED lamp. With a decrease in the area of the base plate 3, which is closed from the light-emitting surface of the light modules 7, the heat transfer intensity increases. However, a decrease in the total area of the light-emitting surfaces of all light modules 7 below 40% of the area of the base plate 3, leads to a slight increase in the heat transfer intensity, while the dimensions and material consumption of the lamp increase sharply, which in turn leads to a significant increase in its cost and lower competitiveness in the market LED lights.

An increase in the strength and rigidity of the LED lamp housing under thermal and mechanical effects is achieved by the fact that the side ventilation ducts 2 are connected by a supporting 3 and a carrier 4 plates, the distance between the outer planes of which is equal to the height of the side longitudinal ventilation ducts 2. Reducing this distance will reduce the strength and stiffness of the housing- radiator 1 and make it difficult to place and install the power supply 8 and the conductive elements between the power supply 8 and the LEDs. Increasing this distance will lead to an irrational increase in the dimensions of the lamp.

The functioning of the LED lamp is partially described above, in the description of its structural elements and their purpose. However, for completeness, the following additions are required. The luminaire is mechanically connected to a bracket or other external support. The functioning of the LED lamp involves connecting the power supply to an external electrical network that is not an element of this lamp. The power supply unit of the lamp is mechanically connected to the casing-radiator, while the power supply unit is electrically connected using insulated conductors with light emitting diodes. Light emitting diodes connected to the power supply unit, as components of light modules, which, in turn, are necessary elements of the luminaire and are mechanically connected to it, function as light flux sources. The luminous flux passes through the optically transparent shields of these light modules, thereby illuminating the desired object.

SOURCES

1. Description of the utility model for patent RU 149674 “LED lamp and heat-sink profile as its case” (Pak V.A. Publ.: 01.20.2015).

2. Description of the invention to the patent RU 2513033 “LED lamp and heat sink profile as its body” (Pak VA, Kabanov AA Publ.: 04.20.2014).

3. Description of the utility model for patent RU 154191 "LED lamp" (Kurmaev I.Kh. Publ.: 08.20.2015).

Claims (1)

An LED lamp comprising a radiator housing in the form of an elongated heat-sink profile with two lateral longitudinal ventilation channels with open ends, the channels being connected by support and carrier plates, end caps with holes, fixture fasteners, light modules, including printed circuit boards and LEDs mounted on printed circuit boards, a power supply unit with electrical wiring connected to the printed circuit boards, and protective screens made of optically transparent material, characterized in that in the upper part of each of the lateral longitudinal ventilation channels of the radiator case, exhaust openings are made, the total area of exhaust openings of each ventilation duct is 80-120% of the total area of openings in the open ends of the ventilation duct, the inner and outer surfaces of the walls of the ventilation ducts being wavy with a wave height to wave step from 1.2 to 2.5; in addition, the lamp contains at least two light modules located on the base plate, the total area of the light-emitting surfaces of all light modules is 40-60% of the area of the base plate.

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