RU2563218C1 - General led lamp - Google Patents

Abstract

FIELD: electricity.SUBSTANCE: LED lamp contains LEDs (4) on board (5), installed longitudinally relatively the lamp axis; the power source is installed on isolated surface of LEDs board, and heatsink has at least two detachable parts locking the board on the surface area between LEDs and power source, at that parts of the heatsink are secured with each other at one side by the base (16), and at the another side by the optically transparent enclosure (1).EFFECT: increased production effectiveness of the lamp design, improved heat mode of LEDs operation, increased comfort of illumination expressed by uniform incandescence of the light emitting enclosure and its colour temperature.7 cl, 11 dwg

Description

- Field of technology.

The invention relates to the field of lighting, and in particular to light sources intended for use in general lighting devices.

- The prior art.

Known LED lamp containing a board with LEDs, placed along the longitudinal axis of the lamp; optically transparent shell; a radiator installed with the possibility of heat exchange with the board; a power source located on the base (patent for utility model CN 201892082 (U), IPC F21S 2/00, published on July 6, 2011).

A disadvantage of the known solution is the one-sided direction of the light flux, the low-tech design for mass production, due to the need to perform a large number of manual assembly operations. Similar designs of street lamps are described in the patent for utility model CN 201739916 (IPC F21S 8/00, published 02/09/2011), in application WO 2008100124 (IPC F21K 7/00, published 21.08.2008), in application KR 100987274 (IPC F21S 13 / 10, published on 12/10/2010)

Also known is the design of a high-brightness LED lamp containing LEDs placed on vertically mounted boards forming a trihedral prism, an optically transparent shell, a radiator and a base (utility model patent CN 201661875 (U), F21S 2/00, published 01.12.2010).

The known solution provides circular radiation of the light flux. The placement of boards forming a trihedral prism is associated with numerous technological difficulties, which increases the cost of the lamp. The shape of the board is critical for heat dissipation, since thermal resistance to convective flow will occur in the inner corners of the prism. The LEDs in the known solution experience significant thermal loads, which reduce the life of such a lamp. The known solution does not contain any information about the features of the connection of nodes and parts.

An integrated LED lamp is known, comprising a housing with a radiator and a power source installed inside it, a base mounted on the housing, an LED matrix mounted longitudinally on the axis of the lamp on the radiator, a light-scattering sheath mounted on the housing, made of optically transparent material, in volume or in part the volume of which particles of a phosphor or a mixture of phosphors are introduced (patent for utility model RU 1064 45, IPC H01L 33/00, published July 10, 2011)

In a known solution, discrete flat boards are installed circumferentially longitudinally to the axis of the lamp and provide circular light emission. However, the installation of the boards with the end face on a flat radiator cannot provide efficient heat exchange between the board and the radiator due to the small heat exchange surface area. The placement of boards that form a prismatic structure is fraught with numerous technological difficulties, which increases the cost of the lamp. The shape of the radiator and its location is critical for heat dissipation, since convection will be carried out only from the outer end surface of the radiator, which will not allow the lamp to be equipped with any powerful LEDs. Such a lamp can be used as a signal light source and is not suitable for creating general lighting.

The known solution according to the patent RU 106445 is the closest analogue of the claimed invention according to the main structural features and purpose.

The technical result of the invention is to increase the manufacturability of the lamp design, improve the thermal mode of operation of the LEDs, increase the comfort of lighting in relation to the uniformity of the glow and color temperature of the surface of the light-emitting shell.

- Disclosure of the invention

The invention is characterized by the following set of essential features.

A general-purpose LED lamp comprising LEDs located on a board mounted longitudinally to the axis of the lamp; a sheath of optically transparent material; a radiator installed with the possibility of heat exchange with the board; LED power supply; means for connecting to the electric network, made in the form of a base, characterized in that the power source is mounted on a separate surface of the LED board, and the radiator has at least two detachable parts fixing the board on at least one surface area located between LEDs and a power source, while the radiator parts are fastened together on one side by means of a connection to the electrical network, and on the other hand by an optically transparent sheath.

As complementary and developing features of the device, you must specify the following:

- the board may have a flat or cylindrical surface. The flat board was fixed on an electrically insulated metallized surface located between the LEDs and the power source, which is equipped with through holes filled with heat-conducting material to enhance heat transfer between the radiator and the board. To increase heat transfer, an additional electrically insulated section can be made, for example, below the power source. In the embodiment of placing the LEDs on a cylindrical surface, the board is made on a flexible base and mounted on an additional longitudinal hollow radiator element;

- the shape of the surface of the longitudinal element of the radiator adjacent to the flexible board determines the spatial positioning of the LEDs. In the case of placing LEDs on the cylindrical surface of the board, it is optimal to equidistant the LEDs from the inner surface of the optically transparent shell;

- the LED board may have a multilayer structure comprising at least one layer of copper. Copper layers can intensify the heat removal process. The thickness of the layers, as well as their number, is selected depending on the amount of heat generated by the LEDs;

- LEDs are mounted on the board with the ability to directly irradiate the inner surface of the spatially remote shell. In the case of radiation in the blue and / or ultraviolet part of the spectrum, the shell is made of optically transparent material containing different compositions of phosphor particles located in the material of the shell and / or on its surface. If the radiation is mixed, then the shell can be matted;

- detachable parts of the radiator can be made of an electrically insulating polymer composite, which ensures electrical safety of the structure, for example, the Xyloy polymer composite by Cool Polymers, Inc. (USA);

- parts of the radiator of the LED lamp have at least one longitudinal mating surface, including the longitudinal axis of the lamp, and can be symmetrical;

- detachable parts of the radiator can be made of electrically conductive material, however, in this case, it is necessary to install a transitional part from the insulating material between the radiator and the means for connecting to the electric network;

- the surface of the detachable parts of the radiator, regardless of the material of the radiator, facing the inside of the optically transparent shell, have a concave surface, made with the possibility of scattering direct radiation of the LEDs and redirecting the reflected radiation to the inner surface of the shell. In particular, the concave surface may be coated with a phosphor or, for example, a metal film. This use of the reflective surface allows not only to equalize the brightness of the radiating surface of the shell, but also to adjust its color temperature by using colored LEDs for this purpose, in particular, SMT-type LEDs with side glow;

- a feature of one of the lamp embodiments is the additional cooling of the LEDs due to convection channels formed by holes in the lower part of the precast radiator, a cavity in the additional longitudinal element of the radiator, and an opening in the upper part of the shell. This solution allows you to use more powerful LEDs and increase the light intensity of the lamp;

- the means of connecting to the electric network can be made in the form of a threaded base, or a coaxial type connector, or any other means of connecting to the electric network, the shape of which ensures the fixing of parts of the detachable radiator.

- List of graphic materials

The invention is illustrated by the following graphic materials:

in FIG. 1 shows a side view of the appearance of an LED lamp having a flat LED board;

in FIG. 2 shows a side view of the appearance of an LED lamp having a cylindrical LED board;

in FIG. 3 shows an axial section of the LED lamp shown in FIG. 1 parsed;

in FIG. 4 shows an axial section of the lamp shown in FIG. 2 parsed;

in FIG. 5 is a sectional view of the general purpose LED lamp assembly shown in FIG. one;

in FIG. 6 shows a cross-section of the general-purpose lamp assembly shown in FIG. 2, having a detachable composite radiator and an additional metal radiator element;

in FIG. 7 is an isometric view of a flat board of an LED lamp;

in FIG. 8 is an isometric view of a board with a cylindrical surface;

in FIG. 9 is an isometric view of a top view of one of the parts of a precast radiator for a flexible board option;

in FIG. 10 is an isometric view of a bottom view of a portion of the precast radiator shown in FIG. 9;

in FIG. 11 is an isometric view of a shell with an opening for the air duct of the lamp of FIG. 2.

A general-purpose LED lamp (Figs. 1 and 2) contains an optically transparent sheath 1, a radiator 2, and means 3 for connecting to the electric network. LEDs 4 are placed on the board 5 (Fig. 3, 4, 5, 6, 7 and 8). In embodiments, the radiator 2 has parts 2 ′ and 2 ″ that are detachable along the L line, and an additional radiator element 6, for applications of a flexible board (Fig. 4, 6, 8).

The detachable parts 2 ′ and 2 ″ are configured to fix the board 5 on an electrically insulated surface 7 and an additional surface 7 ′. The power supply 8 of the LEDs 4 is mounted on a separate surface 9 of the board 5 and in the assembly is in the cavity 17 of the radiator 2.

The surfaces 10 of the detachable parts of the radiator 2, facing the inside of the optically transparent shell 1, can have a concave surface, in particular coated with a phosphor, capable of scattering direct radiation of SMT LEDs 18 (Fig. 6, 8) and redirecting the reflected radiation to the inner surface of the shell one.

In the case of a flat board 5, it is fixed on an electrically insulated metallized surface 7 located on both sides of the board between the LEDs 4 and a separate surface 9. On the surface 7 in the flat board 5 there are through holes (not shown in the drawings) filled with heat-conducting material (for example , metal) to enhance heat transfer with a radiator 2. To equalize the brightness of the radiation, the surface of the shell SMT-LEDs can be installed on the edge of the board 5.

In the embodiment of placing the LEDs 4 on a cylindrical surface, the board 5 (Fig. 8) is made on a flexible base and mounted on an additional longitudinal hollow element 6 of the radiator 2. The shape of the surface adjacent to the flexible board 5 of the additional element 6 of the radiator 2 determines the spatial positioning of the LEDs. The profile of the cylindrical surface of the additional element 6 may be any, for example, hexagonal or octagonal. To intensify the heat transfer process on the inner surface of the additional element 6, in some cases, cooling fins 11 can be made. The abutment density of the board 5 to the additional element 6 can be increased by performing a longitudinal slot 19 on the body of the element 6. This will allow the elastic forces of the element 6 to be used, which will provide additional pressing of the board to the parts of the radiator 2.

The surface 15 (Fig. 9 and 10) of the mating parts of the radiator 2 with the surface of the board 5 provides efficient heat transfer between the radiator 2 and the board 5.

In one embodiment, the connection of the parts 2 ′ and 2 ″ of the radiator 2 is carried out by a threaded base 3. For this, a screw guide 16 is made on the lower part of each of the parts of the radiator 2.

A feature of another embodiment of the LED lamp is the possibility of using more powerful LEDs, which is provided by the presence of through ventilation ducts (Fig. 5), formed by longitudinal slots 12 in the lower part of the collapsible radiator 2, a cavity 13 in the additional element 6 of the radiator 2 and a hole 14 in the upper part of the shell 1 (Fig. 11).

- Possibility of industrial application

The options for combinations of elements of a general-purpose LED light source described in the description are not exhaustive. They can be modified to meet specific lighting purposes. The structural elements of the lighting device have simple shapes that can be manufactured using known means with automated control.

Claims (7)

1. A general-purpose LED lamp comprising LEDs located on a board mounted longitudinally to the axis of the lamp; optically transparent shell; a radiator installed with the possibility of heat exchange with the board; an LED power source and a base, characterized in that the power source is mounted on a separate surface of the LED board, and the radiator has at least two detachable parts fixing the board on at least one surface area located between the LEDs and the power source, while the radiator parts are fastened together on one side by a base and, on the other hand, by an optically transparent shell. 2. The LED lamp according to claim 1, characterized in that the LED board has a multilayer structure comprising at least one layer of copper. 3. The LED lamp according to claim 2, characterized in that the fixing section of the board with a collapsible radiator is equipped with through holes filled with heat-conducting material. 4. The LED lamp according to claim 1, characterized in that the radiator is made of electrically conductive material, and a transition piece of electrical insulation material is installed between the radiator and the base. 5. The LED lamp according to claim 1, characterized in that the radiator is made of an insulating polymer. 6. The LED lamp according to claim 1, characterized in that the surface of the detachable parts of the radiator facing the inside of the optically transparent shell has a curved surface configured to scatter the direct radiation of the LEDs. 7. The LED lamp according to claim 1, characterized in that the LEDs are mounted with the possibility of direct irradiation in the blue and / or ultraviolet part of the spectrum of the inner surface of the optically transparent shell, equipped with phosphor particles placed in the shell material and / or on its surface.

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