RU2630439C2 - Led lamp - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: LED lamp can be used for indoor and outdoor main and decorative lighting. The lamp has a radiator casing consisting of two plates contacting the horizontal sections 6 with a heat sink base 3 from two different sides. In the center of the plate closest to the LED 4 there is an opening 5 for placing the LED on the heat sink base. The plates are bent by bending to form radial corrugations from the boundary 7 of the horizontal section to the outer edge 8 of the plate so that the corrugations are at an angle to the horizontal. Along the upper ribs 9, the ripple at the border 7 of the horizontal portion of the plate has a longitudinal hole 12. The horizontal plate portion 6 and the heat sink base 3 may be in the form of a circle, a square, a rectangle, an ellipse, a hexagon, an octagon. The initial blank of the radiator plate can have the form of a circle, a square, a rectangle, an ellipse, a hexagon, an octagon.

EFFECT: increase in the efficiency of the heat sink of the plates and the radiator as a whole, the creation of a luminaire combining the simplicity of the design with a high degree of unification for the various versions and power of the luminaire.

3 cl, 7 dwg

Description

The invention relates to lighting devices with LED light sources and can be used for indoor and outdoor lighting.

Known LED lamp containing a housing-radiator, made in the form of a metal plate with bent, at a certain angle to the direction of the emitted light, the outer edges or petals of the plates (http://setilumen.ru/, 09/28/2015).

The disadvantage of this device is the large dimensions of the casing-radiator with a lamp power of more than 50 watts.

The closest in technical essence is an LED lamp containing a heat sink of the LED radiation source, including a set of plates whose ends are bent and the seating surfaces of which are in contact with each other (RU 2511564 09/17/2012).

The disadvantages of the known device are:

- или

-образной форме пластин может составлять лишь 40-60% от общей площади пластин, вследствие того, что горизонтальная часть каждой пластины радиатора имеет достаточно большую площадь поверхности, но она практически не участвует в процессе теплоотдачи в окружающую среду, а преимущественно передает тепло между пластинами;small average heat transfer area of the radiator plates, which at

- or

-shaped shape of the plates can make up only 40-60% of the total area of the plates, due to the fact that the horizontal part of each radiator plate has a sufficiently large surface area, but it practically does not participate in the process of heat transfer to the environment, but mainly transfers heat between the plates;

a large number of plates in the radiator set and, as a result, a decrease in the heat removal efficiency of each subsequent plate from the heat radiation source due to the large number of transition contacts between the plates.

The technical essence of the known device lies in the fact that the heat sink is made of a set of plates in contact with one horizontal part, and the entire radiator of one of the plates in contact with a heat sink, and also that the two plates closest to the source of LED radiation the largest contact area between each other, while the contact area of each subsequent plate with the previous one decreases. It follows that in the set of plates their number is three or more, and also that the heat transfer value of each subsequent plate is less than that of the previous one, that is, the heat removal efficiency of each subsequent plate from the heat radiation source of the plate decreases.

Due to the fact that the thermal resistance between the source of thermal radiation and each subsequent plate increases by the sum of the thermal resistances of the plate and the transition contact between the surfaces of the plates, and the thermal resistance of the transition layer between the contact surfaces of the plates is 15-25 times higher than the thermal resistance of the material of the plate itself and all Since these thermal resistances in the heat transfer circuit are connected in series, the total thermal resistance of the radiator with the number of plates 3 or more it is significant.

The technical problem to which the invention is directed is to reduce the number of radiator plates and reduce the complexity of manufacturing an LED lamp as a whole.

The technical result of solving the problem is to increase the efficiency of heat removal of the plates and the radiator as a whole, as well as the creation of a lighting device that combines simplicity of design with a high degree of unification for various versions and power of the lamp.

This result is achieved in that, in contrast to the known LED lamp containing at least one LED, a heat sink, a heat sink made of a set of plates, the following differences are provided in the invention:

- the radiator consists of a set of two plates;

- the plates are in horizontal contact with the heat sink base from two different sides thereof;

- in the center of the plate closest to the LED, there is a hole for placing the LED on the heat sink base;

- the horizontal sections of the plates and the heat sink base are in the shape of a circle;

- the plates are bent by bending with the formation of radial corrugations from the boundary of the horizontal section to the outer edge of the plate so that the edges of the corrugations are located at an angle to the horizontal;

- in the upper part of at least several corrugations at the boundary of the horizontal section of the plate there is at least one longitudinal hole.

Between the set of essential features of the proposed device and the achieved technical result, there is a causal relationship, namely:

- Due to the fact that the horizontal sections of the plates have the shape of a circle, their surface area will be small in size and therefore the surface area of all faces of the corrugations of the plate that efficiently transfer heat will amount to 85-95% of the total area of the plate.

For example, with the diameter of the initial blank of the plate equal to 40.0 cm, the surface area of the plate is 1256.0 cm ² , the horizontal section with a diameter of 15.0 cm of the plate has an area equal to 177.0 cm ² . Thus, in this case, the area of all faces of the corrugations of the plate will be 1256 - 177 = 1079 cm ² , which is 85.9% of the total surface area of the plate.

- In addition, the fastening of two radiator plates to the base from two different sides ensures the parallel inclusion of thermal resistance of the transition contacts of the plates with the base, which reduces the total thermal resistance of the radiator and provides approximately equal heat dissipation efficiency of both radiator plates.

- The presence of corrugations in the radiator plate, the edges of which are located at an angle to the horizontal, in combination with the longitudinal holes in the upper part of the corrugations of at least one plate, increases the speed and turbulence of the air flow washing the radiator plates, which leads to an increase in the heat transfer of the plates to the environment .

- All of the above essential features together allow you to reduce the number of radiator plates to two, as well as reduce the number of transition contacts and increase the efficiency of heat sink of the radiator as a whole.

As developing signs that complement the above set, we give the following:

- the initial blank of the radiator plate may be in the form of a circle, square, rectangle, ellipse, hexagon, octagon;

- the horizontal portion of the radiator plate and the heat sink base may be in the form of a circle, square, rectangle, ellipse, hexagon, octagon;

- the upper and lower plates of the radiator body are made with different opening angles of the lower ribs of the corrugations;

- the number of corrugations of the lower and upper plates can be different;

- a reflector can be attached to the lower ribs of the corrugations of the lower plate of the case-radiator;

- the cross section of the corrugations of the plates can be made in various ways, for example triangular, trapezoidal, sinusoidal or combined.

The invention is illustrated by the following graphic materials presented in FIG. 1-7:

FIG. 1. The scheme of the LED lamp according to option 1.

FIG. 2. The scheme of the LED lamp according to option 1, bottom view.

FIG. 3. Radiator plate in isometry.

FIG. 4. The scheme of the LED lamp according to option 2.

FIG. 5. The scheme of the LED lamp according to option 3.

FIG. 6. The scheme of the LED lamp according to option 1 with a reflector.

FIG. 7. The movement pattern of the cooling air flow in the cross section of the corrugations of a triangular section of two radiator plates.

The proposed device comprises a radiator case formed by the lower plate 1 and the upper plate 2, attached on both sides to the base 3. An LED source 4 is attached to the base 3, for which, in the center of the horizontal section 6 of the plate closest to the LED, there is a corresponding hole 5 . On the opposite side of the LED lamp is a power source.

The lower and upper plates 1, 2 of the radiator body are bent by bending, with the formation of radial corrugations from the border 7 of the horizontal section to the outer edge 8 of the plate. Each corrugation has an upper rib 9 and a lower rib 10, between which there are edges 11 corrugations located at an angle "β" to the horizontal. In the upper ribs 9 there is one or more longitudinal holes 12.

The lower plate 1 and the upper plate 2 can be made, respectively, with different angles α1 and α2 of opening of the lower ribs 10 of the corrugations.

In the lower and upper plates 1,2 and base 3 there are matching through holes 13, through which heated air enters the environment.

A reflector 14 can be attached to the lower ribs 10 of the corrugations of the lower plate 1.

In the embodiment of the luminaire shown in FIG. 1, the directions of the angles α1 and α2 of the opening of the ribs of the corrugations of the plates 1 and 2 coincide with the direction of the light flux of the LED.

In a second embodiment of the luminaire shown in FIG. 4, the angles α1 and α2 of the opening of the ribs of the corrugations of the plates 1 and 2 are directed in opposite directions.

In a third embodiment of the luminaire shown in FIG. 5, the directions of the angles α1 and α2 of the opening of the ribs of the corrugations of the plates 1 and 2 coincide with each other, but are opposite to the direction of the light flux of the LED.

LED luminaires according to options 2 and 3 can be made with a reflector, similarly to the luminaire in FIG. 6.

The value of the angle β of the inclination of the faces of the 11 corrugations to the horizontal, the size and direction of the angles α1 and α2 of the opening of the lower ribs of the 10 corrugations, as well as the shape and size of the initial blanks for the radiator plates 1, 2 and the options for the LED lamp, are selected taking into account the purpose of the lamp, its power and obtaining the greatest heat transfer efficiency of the radiator.

The device operates as follows.

When the LED lamp is connected to the mains supply, a constant electric current is supplied to the LEDs through the power source, ensuring their glow. During the operation of the luminaire, the thermal energy released by the LED source 4 is transmitted through heat conduction to the base 3 and then to the horizontal and corrugated sections of the lower plate 1 and the upper plate 2 of the radiator. Further, from the corrugations of both plates, heat transfer to the environment is carried out.

In the steady-state thermal mode of the luminaire, the temperature of the corrugations of the plates at the boundary 7 of the horizontal section of the lower and upper plates will exceed the temperature of the corrugations at the outer edge of the 8 plates. In FIG. 7 shows how air heated by the lower surface of the faces 11 of the corrugations of the lower plate 1 under the action of gravitational forces forms an upward air flow moving along the surface of the face from the lower edge 10 to its upper edge 9 and, further, along the upper edge 9, through longitudinal holes 12 moves to the upper rib 9 of the corrugation of the upper plate 2, where it is connected to the same air flow of the upper plate.

In addition, the air heated by the upper surface of the faces 11 of the corrugations of the lower plate 1, moves vertically upward, and, moving along the lower surface of the faces 11 of the upper plate 2, creates an air flow that goes through the longitudinal holes 12 in the upper ribs 9 of the upper plate 2 into the surrounding Wednesday The interaction of these three air flows along the upper ribs 9 of the upper plate 2 creates additional turbulence in the air flow, which also contributes to an increase in the intensity of heat removal from the radiator plates to the environment.

A certain part of the heat generated is transferred to the environment by the upper surface of the faces 11 of the upper plate 2, however, in this case, the air flow does not flow along the surface of the corrugation faces, but is torn off vertically upwards.

Claims (3)

1. LED lamp containing a radiator housing made of a set of plates, a heat sink base and mounted on it, at least one LED, a power source, characterized in that the radiator consists of a set of two plates in horizontal contact with the heat sink base from two different of its sides, the horizontal sections of the plates and the heat sink base are circular and both plates are bent by bending, with the formation of radial corrugations from the boundary of the horizontal section to the outer edge of the layer Otherwise, the corrugation faces are located at an angle to the horizontal, in the upper ribs of at least several corrugations there is at least one longitudinal hole at the border of the horizontal section of the plate, and in the center of the plate closest to the LED there is a hole for placing the LED on the heat sink base. 2. The LED lamp according to claim 1, characterized in that the initial flat billet of the radiator plate may be in the form of a circle, square, rectangle, ellipse, hexagon, octagon. 3. The LED lamp according to claim 1, 2, characterized in that the horizontal portion of the radiator plate and the heat sink base can be in the form of a circle, square, rectangle, ellipse, hexagon, octagon.

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