RU2483391C2 - Light diode lamp - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: light diode lamp comprises an envelope, a base for insertion into a cartridge, light diodes connected via a microchip to contacts of the base and a radiator for heat transfer from light diodes. Besides, light diodes are installed on a thermal tube, which is made with the base and a hollow coolant leg, and around the lamp envelope and underneath there are elements of the radiator connected with the base of the thermal tube. Inside the cavity of the thermal tube there is a coolant arranged, which operates in the boiling phase, and contacts of power supply to light diodes are pulled via current-conducting path or wires stretching along the surface of the thermal tube. Light diodes are arranged on the base, which is connected with the thermal tube via a heat conducting material, and inside the radiator there is a blow fan, which is connected to a piezoelement arranged as capable of creating high-frequency mechanical oscillations of the fan.

EFFECT: provision of a colder condition of light diodes and accordingly increase of their luminosity and service life.

3 cl, 1 dwg

Description

The invention relates to LED lamps.

Modern LED lamps, for example, the LED E27 series externally have an unaesthetic appearance, bulky, dimly shine (on average - 300 ... 500 lm) and due to the fact that there is no way and there is nowhere to transfer heat from diodes.

Usually on diode lamps, diodes stand on a large mass of metal, which accumulates heat in itself, but it is very poorly dumped into space, and as a drawback (and consequence) - all such lamps shine sectorly due to the huge metal radiator occupying the lamp substrate .

The prior art solution US 2009046458, which is a classic lamp, where the fins of the radiator are behind the zone of the opening angle of the diode. The circuit does not allow sufficient heat to be removed from the diodes in general, since the diodes have an aperture angle of 120 degrees, and as a result they should be far enough apart, i.e. the density of light emitters is growing, this circuit cannot be placed in a lamp, or with very weak diodes, about 200-300 lm of light.

Known patents US 2009021944, CN 101349411, which describes a heat pipe in the amount of 3 pieces, which take heat from a metal hexagon, on which are scarves (stars) with diodes mounted on them. Those. the diode is not directly standing on the tube, the light source is not a point source, a huge amount of light is lost (reflected from the protective bulb back to this hexagon). The design is very bulky and heavy, a lot of metal inside the emitter, where it is completely useless. The radiator in this circuit stands below and implements the classic circuit of an LED lamp.

The closest analogue is (patent RU 101270 U1) an LED lamp containing a bulb, a base for insertion into a cartridge, LEDs connected via a microcircuit to the contacts of the base, a radiator for transferring heat from the LEDs, characterized in that the LEDs are mounted on a heat pipe, which is made with a base and a hollow leg-coolant, and around the lamp bulb and under it there are elements of a radiator connected to the base of the heat pipe, and inside the cavity of the heat pipe there is a heat carrier operating in the bale phase Nya and contact power LEDs made on the conductive paths through wires on the surface of the heat pipe. The lamp is equipped with a cone of mirror material located at the base of the heat pipe with the function of reflecting the rays incident on the upper part of the base of the heat pipe.

The technical result of this solution is a compact light emitter that does not create light loss and illuminates at angles of 360 × 270 × 270 degrees, in which the cooling radiator is able to significantly increase its area without significantly increasing the size of the lamp.

However, this solution is not ideal from a technical point of view, since the heating of LEDs reduces the resource of their work and there are light losses with luminosity.

The technical result of the claimed invention is a device that provides a colder state of the LEDs, and accordingly their luminosity (brighter) and service life are increased.

The claimed technical result is achieved due to the fact that the LED lamp containing the bulb, a base for insertion into the cartridge, LEDs connected via a chip to the contacts of the base, a radiator for transferring heat from the LEDs, and the LEDs are mounted on a heat pipe, which is made with a base and a hollow with a heat carrier, and around and under the lamp bulb there are elements of a radiator connected to the base of the heat pipe, and inside the cavity of the heat pipe there is a heat carrier operating in the boiling phase I and the contacts on the LED power conducted through the conductive paths or wires on the surface of the heat pipe, characterized in that the LEDs are arranged on the base, which is connected to a heat pipe via the heat conducting material. In addition, the protective flask is made with a light-emitting phosphor applied from the inside. A reflective element is located at the base of the protective bulb around the heat pipe. Inside the radiator there is a fan of blowing, which is connected to a piezoelectric element made with the possibility of creating high-frequency mechanical vibrations of the fan.

The invention can be implemented in the following way.

The lamp consists of the following elements (see Figure 1):

protective flask (1), LEDs (2), bases for mounting LEDs (3), intermediate heat-conducting material (4), heat pipe (5), reflective cone (6), combined radiator (7), blower fan (8), intermediate heat-conducting material (9), lamp housing (10), piezoelectric element (11).

The protective flask (1) is made with a light-emitting phosphor applied from the inside (the light-emitting phosphor is not shown in the sketch), which allows the use of phosphor-free LEDs emitting in the blue spectrum in the lamp design. This modernization will remove from the LEDs a part of the thermal load generated in the diodes due to the internal reflection of light inside the phosphor layer in the LED. This improvement will make the lamp colder, and therefore brighter (LEDs have a strong degradation both in terms of service life and in the luminosity created by them, depending on their own temperature).

The LEDs (2) are installed on the basis of (3), which allows them to be placed at the right angles to obtain a picture of the correct shadowless light distribution. The base (3) is connected to the heat pipe (5) by means of an intermediate heat-conducting material (4).

Material (4) encloses the heat pipe and provides tight thermal contact for heat transfer to the heat pipe.

The reflective cone (6) serves to minimize the loss of light entering the base of the base. It can be made of a light-reflecting material and casts spurious rays in the right direction, making them useful.

The combined radiator (7) is connected to the heat pipe (5) by means of an intermediate heat-conducting material (9). This allows you to transfer heat from the heat pipe (5) to various sections of the radiator, which due to this can be spaced in space.

Inside the radiator (7) there is a fan of blowing (8), which is connected to the piezoelectric element (11). The piezoelectric element (11) creates high-frequency mechanical vibrations of the fan (8). These vibrations create the movement of air inside the radiator, thereby increasing the efficiency of heat removal.

The lamp is formed by inserting into a light-distributing opaque flask (1) (can be made of plastic or glass) around its side surfaces of a secondary metal radiator (7), which can be made of light metal or metal alloys.

The standard base with a plastic ballast (10) is a lamp housing and contains control electronics for powering the LEDs, the electrical contacts to which go through the cavity of the heat pipe (5).

Claims (3)

1. An LED lamp containing a bulb, a base for insertion into a cartridge, LEDs connected via a chip to the contacts of the base, a radiator for transferring heat from the LEDs, the LEDs being mounted on a heat pipe that is made with a base and a hollow heat carrier, and around the bulb lamps and under it there are elements of a radiator connected to the base of the heat pipe, and inside the cavity of the heat pipe there is a heat carrier operating in the boiling phase, and the power contacts to the LEDs are drawn through conductive paths or wires running along the surface of the heat pipe, characterized in that the LEDs are placed on the base, which is connected to the heat pipe through a heat-conducting material, and inside the radiator there is a fan of blowing, which is connected to a piezoelectric element configured to create high-frequency mechanical vibrations of the fan. 2. The LED lamp according to claim 1, characterized in that the protective bulb is made with a light emitting phosphor applied from the inside. 3. The LED lamp according to claim 2, characterized in that at the base of the protective bulb around the heat pipe is a reflective element.