KR101312118B1 - LED Reflector Lamp - Google Patents

Abstract

The present invention provides an LED reflector lamp comprising a control circuit, comprising: at least two LED light sources controlled by the control circuit; At least two light source panels to which the at least two LED light sources are respectively fixed; At least one heat conduction plate to which the at least two light source panels are fixed in a heat conduction manner; A reflective cup having a reflective inner surface, a reflective opening formed by an edge of the reflective inner surface, and a slot formed at a bottom of the reflective cup, wherein the heat conducting plate fixed to the LED light sources and the light source panels comprises: A reflective cup inserted through the slot into the reflective cup such that LED light sources are parallel to the central vertical axis of the reflective cup; And a heat sink having a cavity therein, the cavity further comprising a heat sink sized and shaped to engage with at least a portion of the reflective cup and the heat conducting plate.

Description

LED Reflector Lamp {LED Reflector Lamp}

The present invention generally belongs to the field of lighting fixtures. More specifically, the present invention relates to an LED reflector lamp used as a lighting fixture with high lighting efficiency and improved heat dissipation characteristics.

As a light source using solid-state devices, the light emitting diodes (LED), born in the 1960s, have replaced conventional high-pressure halogem lamps in a wide range of lighting applications due to their long life, rugged construction, low power consumption, and flexible size. . However, LEDs produce light that is relatively high, resulting in weak light and short lifetime.

Currently available LED lamps used for illumination purposes typically require multiple LED light sources with lamp shades to achieve the required luminescence and output since one LED light source has a relatively low luminescence and output. . The greater the number of LED light sources, the stronger and more effective the LED lamp is. 1 shows a conventional LED lamp. The LED lamp of FIG. 1 has a number of LED light sources 1 evenly mounted horizontally on the same panel 2, where each LED light source is arranged on the same horizontal plane with a lampshade and then on the market It is assembled with a conventional lamp holder 3 to form a viewable conventional PAR lamp. As can be seen in FIG. 2, PAR lamps can satisfy the luminescence requirements, but have no special means for heat conduction and heat dissipation. As a result, the heat energy generated by the plurality of LED light sources cannot be dissipated effectively, so that the temperature of the housing of the lamp becomes so high that a person burns and the lamp is fragilely burned. Furthermore, since there are no elements that condense light, the light emitted from the LED light sources cannot be effectively collected, resulting in light loss and low utilization of light.

Chinese Utility Model No. 200820101329.7, entitled “LED Light Fixtures”, is an LED rod having a plurality of light units, each consisting of a light cover mounted on a horizontal panel relative to an axis perpendicular to the center of the housing of the light source and lamp. A lamp is disclosed wherein each LED light source is arranged on the same horizontal plane. This Chinese utility lamp improves heat dissipation, but all LED light sources are designed to face outwards. Thus, most of the luminous flux emitted from all LED light sources is projected directly onto the work surface, which is supposed to cause glare and glare and affect the human eye. In addition, this lamp cannot condense light and the effect is inferior. Since all the LEDs are arranged horizontally on the same plane, the size of the lamp is inevitably large for high output.

According to a conventional LED lamp, about 90% to 100% of its luminous flux is projected onto the assumed working surfaces, which causes problems of heat dissipation and short lifespan. The projection angles of these LED lamps are fixed and cannot be adjusted or changed by actual needs, which limits the application of these LED lamps. As described above, when the human eye comes in direct contact with light, the light output causes glare and damages the human eye. Moreover, there is no condensation of light emitted from these LED lamps, and therefore the lighting effect is relatively low.

Accordingly, there is a need to improve the currently available LED lamps used for lighting in terms of heat dissipation and light collection. If heat dissipation is improved, the size of the high power LED lamp can be made smaller and the lighting efficiency can be increased. If the projection angle is adjustable and the light can be focused, the problem of glare and glare can be avoided due to the improvement of the lighting efficiency and the increase of the luminous flux.

It is an object of the present invention to provide a novel LED reflector lamp having excellent properties in terms of heat conduction, heat dissipation, and light condensation, to address the above-mentioned conventional problems. The LED reflector lamp also has an adjustable projection angle to structurally solve the problem of glare and produce light without glare.

The object is an LED reflector lamp comprising a control circuit, comprising: at least two LED light sources controlled by the control circuit; At least two light source panels to which the at least two LED light sources are respectively fixed; At least one heat conduction plate to which the at least two light source panels are fixed in a heat conduction manner; A reflective cup having a reflective inner surface, a reflective opening formed by an edge of the reflective inner surface, and a slot formed at a bottom of the reflective cup, wherein the heat conducting plate fixed to the LED light sources and the light source panels comprises: A reflective cup inserted through the slot into the reflective cup such that LED light sources are parallel to the central vertical axis of the reflective cup; And a heat sink having a cavity therein, the cavity further comprising a heat sink sized and shaped to engage with at least a portion of the reflective cup and the heat conducting plate.

In one preferred embodiment of the present invention, the LED reflecting lamp comprises: two LED light sources; Two light source panels to which the two LED light sources are respectively fixed; And one heat conducting plate on which each of the two light source panels are fixed, wherein the heat sink has an annular structure and has a reflective inner surface that lies tight against the outer surface of the reflective cup.

Advantageously, said reflective cup consists of two symmetric halves disposed symmetrically about said central vertical axis, each of said two halves having a reflective inner parabolic surface formed by an extension of parabolas, wherein said LED The centers of the light sources are each located at the focal point of the parabolas of the inner parabolic surfaces. This configuration allows all the light emitted from the LEDs to be reflected by the inner parabolic surfaces of the two symmetrical halves to achieve better condensation, such that the LED reflector lamp has a higher luminous flux.

It has been found that when the LED light sources are arranged to overlap the focal points of the parabolas of the inner parabolic surfaces of the reflective cup, the luminous flux can be increased by about 5% to 20%.

The LED reflector lamp further comprises a metal cap disposed on a central vertical axis of the reflecting cup, the metal cap having two opposite sides, each side being formed with a notch having the same thickness as the heat conducting plate, The thermally conductive plate is adapted to be deeply snapped into the notch.

According to the invention, the LED light sources are glued or mechanically fixed to the light source panels, which are fastened by fasteners, glued, or viscous radiating oil to the heat conducting plate. To have an advantage, a radiating oil layer is arranged between the light source panels and the heat conducting plate.

Preferably, the reflective cup is generally horn shaped and the reflective inner surface of the reflective cup is coated with materials that reflect light.

The heat sink is hollow cylindrical and the inner surface has an arc shape corresponding to the outer surface of the reflective cup such that the inner surface of the heat sink lies tight against the outer surface of the reflective cup. The heat sink has a plurality of radiating fins disposed on the outer surface in a spaced manner parallel to the central vertical axis of the reflective cup. The heat sink also has a plurality of ribs at one end extending from the center of the one end of the heat sink to the sidewalls of the heat sink. These ribs function as reinforced ribs and facilitate heat dissipation.

According to the invention, the LED light sources are arranged to be close to the bottom of the reflective cup, or are arranged to be close to the reflective opening of the reflective cup. In this way, since the light emitted from the LED light sources is reflected by the inner surface of the reflective cup, the angle of the light beams reflected from the reflective cup can be changed between, for example, between 10 and 60 degrees. have.

In another embodiment of the invention, the central vertical axis of the heat conduction plate overlaps with the central vertical axis of the reflecting cup, and the tangent of the joint defined by the central vertical axis of the heat conduction plate and the arc lines of the reflecting cup The thermally conductive plate is arranged to be perpendicular to the central vertical axis of the thermally conductive plate.

The heat conducting plate, the heat sink and the reflecting cup may be made individually, or any two of them may be integrally formed, or both may be integrally formed.

To improve heat dissipation, the light source panels, the heat conducting plate, the heat sink and the reflecting cup are preferably formed of a thermally conductive material such as aluminum, aluminum alloy, or ceramic.

The LED reflector lamp according to the present invention has excellent lighting and condensing effects, and thus no lamp shade is required for the lamp. Of course, a lampshade may be provided in the opening of the reflective cup if desired.

In the LED reflector lamp of the present invention, the LED light source panels are in intimate contact with the heat conduction plate integral with the heat sink to form a good path for heat conduction and heat dissipation. This path allows the thermal energy generated from the LED light sources to be successfully released through the light source panels- the heat conduction plate- the heat sink and the reflecting cup, and the on of the LED light sources is thus significantly reduced. Due to the absence of the lamp shade, the LED light sources can communicate directly with air to facilitate heat dissipation of the lamp, which further reduces thermal energy when the LED emits light. The shape of the LED reflector lamp of the present invention prevents the LED from overheating to increase the life of the lamp. The present invention has solved the problem of heat dissipation in exchange with high power LED lamps and allows a large number of LEDs to be mounted in a compact manner so that the high power LED lamp can be made small in size.

Since the LED light sources are mounted in the center of the reflecting cup, the light emitted from the LEDs is reflected outwardly by the reflecting cup so as to focus effectively. Changing the position of the LED light sources changes the angle of the light beams reflected by the reflecting cup, which is advantageous in many applications of lamps.

When the LED light sources are arranged at a position corresponding to the focal point of the parabolas forming the inner parabolic surfaces of the reflective cup, the lights are emitted from the LEDs at high speed in a more concentrated manner. In this case, the use of the low power LED reflector lamp can produce the same lighting effect as the conventional high power LED lamp. This low power LED reflector lamp has a long life due to its low power and low heat generation.

1 is a plan view of a LED lamp fixture conventionally available.
FIG. 2 is a front view of the LED lamp fixture of FIG. 1. FIG.
3 is a top perspective view of an LED reflector lamp with two light source panels constructed in accordance with a first embodiment of the present invention.
4 is a bottom perspective view of the LED reflector of FIG. 3.
5 is an exploded bottom perspective view of the LED reflector of FIG. 3.
6 is an exploded top perspective view of the LED reflector of FIG. 3.
7 is a top perspective view of an LED reflector lamp with three light source panels constructed in accordance with a second embodiment of the present invention.
8 is a top perspective view of an LED reflector lamp with four light source panels constructed in accordance with a third embodiment of the present invention.
9 is a top perspective view of an LED reflector lamp constructed in accordance with a fourth embodiment of the present invention, the LED reflector lamp having a reflecting cup consisting of two symmetrical halves.
FIG. 10 is a bottom perspective view of the LED reflector lamp of FIG. 9.
FIG. 11 is a top perspective view of the LED reflector lamp of FIG. 9.
12 (A) and 12 (B) are cross-sectional views of the central vertical axis of the LED reflector lamp of FIG. 9.

Although the present invention has been shown and described with reference to preferred embodiments, LED reflector lamps may be made of many different configurations, sizes, shapes, and materials.

Referring now to the drawings, FIGS. 3-6 provide an LED reflector lamp 100 constructed in accordance with a first embodiment of the present invention. In the present embodiment, the LED reflector lamp 100 includes two LED light sources 60, two light source panels 20, a heat conduction plate 10, a heat sink 50, a reflective cup 30, Metal cap 40 and control circuitry (not shown) for controlling the LED light sources. The control circuit may be integrally formed with the LED reflector lamp and may be fixed to the radiating fins at an outer surface of the heat sink, or may be formed separately from the LED reflector lamp to provide a plug type connector for electrical connection with the LED reflector lamp. Can have The control circuit is not an essential part of the invention and thus is not described in detail herein.

The LED light source 60 may be composed of one or more LEDs. In this embodiment, each of the two LED light sources 60 is composed of three chip LEDs fixed on each light source panel 20. The LED light sources 60 may be glued, fixed to the light source panels 20 mechanically or by any means known in the art. Each light source panel 20 has threaded holes 22, 24 through which the light source panel 20 is screwed onto the heat conducting plate 10. A spinning oil layer may be arranged between the light source panels 20 and the heat conducting plate 10 to obtain a better heat conducting effect. Of course, the light source panels 20 can be fixed on the heat conduction plate 10 to perform good heat conduction and heat release therebetween using techniques known in the art. For example, the light source panels 20 may be attached to the thermal conductive plate 10 through viscous spinning oil.

As shown in FIGS. 5 and 6, the thermally conductive plate 10 has a notch 12 and a screw hole () at positions corresponding to the screw holes 22, 24 of the light source panels 20, respectively. 14) with a semicircular plate. The two light source panels 20 have the screw holes 22, 24 of the light source panels 20 centrally aligned with the notches 12 and the screw holes 14 of the heat conducting plate 10. By positioning the light source panels on the respective sides of the heat conducting plate 10 in the state and screwing them, they are respectively locked to the two sides of the heat conducting plate 10. As described above, the radiating oil layer may be coated on the contact surface between the light source panel 20 and the thermal conductive plate 10 before good screwing. As an alternative, viscous spinning oil may be used to attach the two light source panels 20 directly on each side of the heat conducting plate 10.

The heat sink 50 has an annular structure, and the heat conducting plate 10 is disposed in an internal cavity of the heat sink 50 so as to overlap the central vertical axis of the heat sink 50. In this embodiment, the heat sink 50 and the heat conduction plate 10 are integrally formed. Of course, the heat sink 50 and the heat conduction plate 10 may be plugged together for good heat conduction contact. 4 and 6 show that the heat sink 50 has a plurality of ribs 54 at its outer end extending from the center of the outer end to the side walls of the heat sink. These ribs 54 can function as reinforcing ribs and facilitate heat dissipation. The heat sink 50 is the outer surface 36 of the reflective cup 30 so that the inner surface of the heat sink 50 is placed tightly against the outer surface 36 of the reflective cup 30. It has an inner surface with an arc-shaped configuration that mates with, which facilitates heat dissipation through the reflective cup 30. The heat sink 50 also has a plurality of radiating fins 52 disposed on its outer surface in a manner parallel and spaced apart from the central vertical axis of the reflective cup. This arrangement of the radiating fins 52 further accelerates the release of thermal energy transferred from the heat conducting plate 10.

The reflective cup 30 has a reflective inner surface 32, a reflective opening formed by the edge of the reflective inner surface 30, and a slot 34 formed in the bottom of the reflective cup. The reflective cup 30 is generally horn shaped with a small diameter bottom and a large diameter opening to exhibit PAR characteristics. The horn-shaped structure increases the lighting effect and improves light condensing. The reflective inner surface 32 of the reflective cup 30 is a smooth arc surface that can be coated with light reflecting materials to enhance the lighting effect. Light emitted from the LED light sources 60 will be reflected onto the reflective inner surface 32 of the reflective cup and reflected outward by the reflective aperture. In this embodiment, the reflective opening does not have a glass lampshade, allowing the chip LEDs to directly interact with the atmosphere, which advantageously works for heat dissipation and for reducing the heat generation of the LEDs. If desired, smooth and transparent glass lampshades may be provided in the reflective cup. The slot 34 has the heat conduction plate 10 and the light source fixed to the LED light sources 60 with the LED light sources 60 parallel to the central vertical axis of the reflective cup 30. The size and shape are determined so that the panels 20 can be inserted into the reflective cup through the slot 34. Preferably, the central vertical axis of the heat conductive plate 10 overlaps the central vertical axis of the reflective cup 30 and is defined by the central vertical axis of the heat conductive plate 10 and the reflective cup 30. The thermally conductive plate 10 is arranged such that the tangent of the arc lines of is perpendicular to the central vertical axis of the thermally conductive plate 10. In this case, the three chip LEDs fixed to each of the light source panels 20 are all disposed on the same vertical plane, and the light emitted from the LEDs is onto the reflective inner surface 32 of the reflective cup. It is evenly reflected and reflected outward in a very concentrated way to reach lighting conditions.

According to the invention, the light source panels 20 may be arranged such that the LED light sources 60 are close to the slot 34 at the bottom of the reflective cup 30 or the LED light sources 60 are the reflective cups. It may be arranged to be close to the reflective opening of 30. As described above, the light emitted from the chip LEDs is reflected outward through the reflective inner surface 32 of the reflective cup 30, thereby positioning the LED light sources 60 on the reflective cup. By changing the angle of the light beams reflected outwardly from the reflecting cup, the projection angle of the lights of the LED reflector lamp may be adjusted. This is different from conventional LED lamps that employ reflective lamp covers to control the angle of the light beams. In the LED reflector lamp of the present invention, the angle of the light beams can be varied generally between 10 degrees and 60 degrees.

The metal cap 40 is a hollow cylinder having two opposite sides with an open end, a closed end and a notch 42. The sizes of the notches correspond to the thickness of the heat conduction plate 10 so that the heat conduction plate 10 is deeply snapped into the notches 42. The metal cap 40 can receive the light emitted from the LED light sources directly below the metal cap 40 and in the center of the reflective cup, so that people can be emitted directly from the LED light sources. There is no direct contact with the lights, which protects the eyes from glare and glare. The upper surface of the closed end of the metal cap 40 may be designed with green fluorescence to recognize the LED reflector lamp of the present invention.

The heat conducting plate 10, the heat sink 50 and the reflecting cup 30 may be made separately, and may be bitably connected to each other to make good contact in a heat conducting manner. Two of them, that is, the heat conduction plate 10 and the heat sink 50, the heat conduction plate 10 and the heat conduction cup 30, or the heat sink 50 and the reflection cup 30 are It can be formed integrally. In addition, the heat conductive plate 10, the heat sink 50, and the reflective cup 30 may be made in one piece.

Preferably, the light source panels 20, the heat conductive plate 10, the heat sink 50, and the reflective cup 30 are formed of a heat conductive material selected from the group consisting of aluminum, aluminum alloy, and ceramic.

7 illustrates an LED reflector lamp 200 constructed in accordance with a second preferred embodiment of the present invention. The LED reflector lamp of this embodiment is structurally identical to that shown in the first embodiment except for the following.

The LED reflector lamp has three light source panels 220 and three LED light sources 260, each of which is fixed to each light source panel 220.

The heat conduction plate 210 is triangular and comprises a central post defined by three side planes 214 and three heat conduction branch plates 212 extending from the central post, the three light source panels The fields 220 are respectively secured to three side planes 214, each divided by the branch plates 212.

The metal cap 240 has three corresponding notches which are in engagement with the joints of the three side planes 214.

The heat sink 250 of the second embodiment has a structure substantially the same as the heat sink 50 of the first embodiment. High power LED reflector lamps can be manufactured due to the addition of one or more LED light sources.

8 illustrates an LED reflector lamp 300 constructed in accordance with a third preferred embodiment of the present invention. The LED reflector lamp of this embodiment is structurally identical to that shown in the first embodiment except for the following.

The LED reflector lamp has four light source panels 320 and four LED light sources 360, each of which is fixed to each light source panel 320.

The heat conducting plate 310 comprises a rectangular central post defined by four side planes 314, the four light source panels 320 each having four side planes 314, respectively. It is fixed.

The metal cap 340 has four corresponding notches which are in engagement with the joints of the four side planes 314.

Compared with the LED reflector lamp 200 of the second embodiment, the addition of one or more LED light sources allows for much higher power LED reflector lamps.

9-12 show an LED reflector lamp 400 constructed in accordance with a fourth preferred embodiment of the present invention. The LED reflector lamp of this embodiment is structurally the same as that shown in the first embodiment, and includes two LED light sources 460, two light source panels 420, a heat conduction plate 410, and a heat sink 450. And a control circuit for controlling the LED light sources.

The LED reflector lamp 400 differs from that of the first embodiment in that the reflecting cup 430 is composed of two symmetric halves 431 and 432 of the same structure and the same dimensions. The halves 431 and 432 are assembled together to form a horn. These halves are relatively symmetrical with respect to the central vertical axis of the reflective cup in which the slots 434 are formed. The slot 434 is illustrated such that the heat conduction plate 410 fixed to the LED light sources 460 and the light source panels 420 are inserted into the reflective cup 430 through the slot 434. It has the same size and shape as 9.

The LED reflector lamp 400 has two halves 431, 432 having respective reflective inner surfaces which are parabolic surfaces formed by the extension of parabolas, and the centers of the LED light sources 460 are each It is characterized in that it is located at the focal point of the inner parabolic surfaces. In other words, the focal points of the parabolas of the two halves 431, 432 overlap with the centers of the two LED light sources 460, as shown in FIGS. 12A and 12B. This structure allows all the light emitted from the LED to be reflected by the inner parabolic surfaces of the two symmetrical halves 431, 432 for better condensing and enhanced lighting effects. It has been found that the luminous flux of the LED reflector lamp of this embodiment is increased by about 5% to 20% over conventional LED lamps.

The reflective inner surfaces of the symmetric halves 431 and 432 are smooth and may be coated with a light reflective material to further enhance the lighting effect. The reflective inner surfaces of the halves 431, 432 can be any surfaces of suitable structure capable of collecting light, which are within the capabilities of those skilled in the art.

According to the present invention, the light source panels fixed to the LED light sources can be placed tightly against a heat conduction plate connected to the heat sink in a heat conduction manner, so that the light source panels-the heat conduction plate-the heat sink It is thus possible to create a path with good thermal conductivity and heat release properties. The heat energy generated by the light sources can be quickly released through this path, which easily reduces the temperature of the LED light sources. Thus, the problem associated with heat dissipation of the LED lighting fixtures is successfully solved. Moreover, the opening of the reflecting cup where the lamp shade is not arranged helps to improve heat dissipation. Light emitted from the LED light sources can be reflected outwardly through the reflective inner surface of the reflective cup to focus the lights, in a manner that the LED light sources are parallel to the central vertical axis of the reflective cup. It is because it is mounted in the center of the said reflection cup. If the centers of the LED light sources are designed to overlap the focal points of the parabolas of the reflective cup, the LED reflector lamp of the present invention will bring better condensing and higher luminous flux. In addition, the modification of the structure of the heat conduction plate increases the number of the LED light sources and the light source panels, thereby enabling the manufacture of a series of high power LED reflector lamps.

If the LED light sources are near the bottom of the reflective cup, the projection angle of the light emitted from the LED light sources will be small. If the LED light sources are in the vicinity of the reflective opening of the reflective cup, the projection angle of the light emitted from the LED light sources will be large. In this way, the projection angle of the LED reflector lamp can be adjusted to meet different applications. The number of LED light sources may be two, or larger, for example three or four, or even larger. Thus, the production of high power LED lamps is possible in a wide range of cases.

Accordingly, the present invention effectively solves the problem of heat dissipation associated with high power LED lamps and provides an LED reflector lamp that exhibits high light effect and improved heat dissipation characteristics.

While the nature of the invention has been described in accordance with some preferred embodiments, the invention is not limited to the structure and function of the embodiments and figures described above. Various modifications are possible to the present invention as long as the basic principles of the present invention are not changed, changed, or modified. Modifications and variations which can be readily obtained by those skilled in the art without departing from the scope of the present invention are within the scope of the present invention.

Claims (22)

An LED reflector lamp comprising a control circuit,
At least two LED light sources controlled by the control circuit;
At least two light source panels to which the at least two LED light sources are respectively fixed;
At least one heat conduction plate to which the at least two light source panels are fixed in a heat conduction manner;
A reflective cup having a reflective inner surface, a reflective opening formed by an edge of the reflective inner surface, and a slot formed at the bottom of the reflective cup, wherein the heat conducting plate fixed to the LED light sources and the light source panels comprises: A reflective cup inserted through the slot into the reflective cup such that LED light sources are parallel to the central vertical axis of the reflective cup; And
A heat sink having a cavity therein, the cavity having a size and shape to be coupled with at least a portion of the reflective cup and the heat conducting plate,
LED reflector lamp, characterized in that it further comprises.
The method of claim 1,
The LED reflector lamp,
Two LED light sources;
Two light source panels to which the two LED light sources are respectively fixed; And
In each side, the two light source panels include one heat conduction plate to each fixed,
And the heat sink has an annular structure and has a reflective inner surface that lies tight against the outer surface of the reflective cup.
The method of claim 1,
The LED reflector lamp further comprises a metal cap disposed on a central vertical axis of the reflecting cup, the metal cap having two opposite sides, each side being formed with a notch having the same thickness as the heat conducting plate, LED reflector lamp, characterized in that the heat conduction plate is deeply snapped into the notch.
The method of claim 1,
The reflective cup consists of two symmetric halves disposed symmetrically about the central vertical axis, each of the two halves having a reflective inner parabolic surface formed by an extension of the parabolas, the center of the LED light sources. LED reflector lamps, each of which is located at the focal point of the parabolas of the inner parabolic surfaces.
5. The method according to any one of claims 1 to 4,
And the LED light sources are glued or mechanically fixed to the light source panels.
5. The method according to any one of claims 1 to 4,
And the light source panels are fixed to the heat conducting plate by fasteners, glued, or viscous radiating oil.
5. The method according to any one of claims 1 to 4,
LED reflector lamp, characterized in that a layer of radiating oil is arranged between the light source panels and the heat conducting plate.
5. The method according to any one of claims 1 to 4,
LED reflector lamp, characterized in that the reflecting cup is generally horn-shaped.
5. The method according to any one of claims 1 to 4,
And the reflective inner surface of the reflective cup is coated with materials that reflect light.
5. The method according to any one of claims 1 to 4,
And the heat sink is hollow cylindrical and the inner surface of the heat sink has an arc shape corresponding to the outer surface of the reflecting cup so that it lies tight against the outer surface of the reflecting cup.
5. The method according to any one of claims 1 to 4,
And the heat sink has a plurality of radiating fins arranged on an outer surface in a spaced manner parallel to the central vertical axis of the reflective cup.
5. The method according to any one of claims 1 to 4,
And the heat sink has a plurality of ribs at one end extending from the center of the one end of the heat sink to the sidewalls of the heat sink.
4. The method according to any one of claims 1 to 3,
And the LED light sources are arranged to approach the bottom of the reflective cup.
4. The method according to any one of claims 1 to 3,
And the LED light sources are arranged proximate to the reflective opening of the reflective cup.
5. The method according to any one of claims 1 to 4,
The central vertical axis of the thermally conductive plate overlaps the central vertical axis of the reflective cup, and the tangent of the joint defined by the central vertical axis of the thermally conductive plate and the arc lines of the reflective cup are the central vertical axis of the thermally conductive plate. LED reflector lamp, characterized in that the heat conducting plate is arranged perpendicular to the.
5. The method according to any one of claims 1 to 4,
The heat conduction plate is LED reflector lamp, characterized in that formed integrally with the heat sink.
5. The method according to any one of claims 1 to 4,
The heat conduction plate is LED reflector lamp, characterized in that formed integrally with the reflecting cup.
5. The method according to any one of claims 1 to 4,
The heat sink is LED reflector lamp, characterized in that formed integrally with the reflecting cup.
5. The method according to any one of claims 1 to 4,
The heat conduction plate is LED reflector lamp, characterized in that formed integrally with the heat sink and the reflecting cup.
5. The method according to any one of claims 1 to 4,
And the light source panels, the heat conduction plate, the heat sink, and the reflecting cup are formed of a heat conductive material.
21. The method of claim 20,
The thermally conductive material is an LED reflector lamp, characterized in that selected from the group consisting of aluminum, aluminum alloy, and ceramic.
5. The method according to any one of claims 1 to 4,
LED reflector lamp, characterized in that the lamp shade is provided in the opening of the reflective cup.

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