RU2636791C1 - Led lamp - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: third contact 6 and fourth contact 7 are brought into contact with mating contacts of the external electric circuit, for example, by screwing the cap 5 into the female socket. The power supply unit 8 converts the voltage of the external electric source into an operating voltage required for the correct operation of the assembly 10. One or more light-emitting diodes 13 disposed on the substrate 15, when the current, supplied via the current-conducting string 16, flows through them, create optical radiation. The fluophoric layer converts this radiation of the light-emitting diodes 13 into the optical radiation with a modified spectrum, more favourable for human eyes. Different inclination of assemblies 10 relative to the bulb 1 axis, as well as their relative location allow, depending on the product design, to place the lighting spatial angle axis from each individual assembly 10 so that the general direction pattern of light radiation was the closest to the spherical shape.

EFFECT: increase in the uniformity of the direction pattern of the light radiation.

24 cl, 2 dwg

Description

Technical field

The invention relates to the field of lighting engineering, specifically to LED lamps.

State of the art

The closest technical solution (prototype) is an LED lamp (RF patent No. 158205, publ. 12/27/2015). An LED lamp contains a bulb made of a transparent, a base, a holder, a power supply unit, at least two assemblies, each of which consists of one or more LEDs. Assemblies can be located, for example, along the three side edges of an imaginary triangular pyramid. The lamp base is used to electrically connect to an external power source to supply power to the LED assemblies. Assemblies are connected electrically in parallel. The flask is filled with gas, the pressure of which can be in the range of 8-200 kPa.

A disadvantage of the known technical solution is the uneven pattern of the propagation of light radiation. This is due to the fact that light from one LED assembly propagates in a certain spatial angle, the axis of which is directed perpendicular to the LED assembly. The location of several LED assemblies in a known product does not allow you to create a uniform radiation pattern.

The technical result of the invention is to increase the uniformity of the radiation pattern.

The specified technical result is achieved due to the fact that in the LED lamp containing the bulb made transparent, the base, leg, holder, mount, power supply, first contact, second contact and four LED linear assemblies, the bulb is sealed to the base and filled with gas composition including at least helium, the power supply is located on the base, the leg is fixed on the side of the bulb on the base, the holder is mounted on the leg inside the bulb, a mount is placed in the middle of the holder, each LED The linear assembly contains one LED located on the dielectric substrate, part of the LED linear assemblies is located on the opposite side of the mounting base, and the other part of the LED linear assemblies is located between the leg and the mount, while the LED linear assemblies are mounted at one end remotely from the holder, and at the other end, the LED linear assemblies are mounted on the holder, inside the bulb are placed the first contact and the second contact, the first contact and The other contact is connected to the output of the power supply unit corresponding to each of them, the inputs of which are connected to the contact of the socle corresponding to each of them, and the LED linear assemblies are connected respectively to the first contact and the second contact so that they can emit visible light, in the first particular case each LED the linear assembly contains additional LEDs located on a common dielectric substrate along it, in the second particular case around each LED and vice versa the mixture of the compound and the phosphor is placed on each side of the substrate, in the third particular case the flask is made with a gas pressure in the range of 8-200 kPa, in the fourth particular case the LEDs are emitting light from at least the blue-violet zone of the visible spectrum, in the fifth particular case, the bulb is connected to the base through a ring of plastic; in the sixth particular case, each LED is made in the form of an LED chip, each LED chip containing several pn junctions connected in series, each about the LED chip, direct voltage 5.5V and higher, in the seventh particular case, the LED linear assemblies are connected in series-parallel, in the eighth particular case, the LED chips are connected in parallel, in the ninth particular case, the LED chips are connected in series-parallel, in the tenth particular case, the substrates are made transparent, in the eleventh particular case, the substrates are made of glass, in the twelfth particular case, the substrates are made of leucosapphire, in the thirteenth special case the substrates are opaque, in the fourteenth particular case the substrates are made of metal, in the fifteenth special case the substrates are made of ceramic, in the sixteenth special case the substrates are made of plastic, in the seventeenth special case the holes are made in the substrate, in the eighteenth particular case the nitrogen mixture , in the nineteenth particular case, the composition of the gas mixture includes any inert gas, in the twentieth special case a light-transmitting coating is applied to the glass flask from the outside, which improves heat the return between the glass and the surrounding air; in the twenty-first particular case, the glass flask is coated on the outside with a matte coating that improves the heat transfer between the glass and the surrounding air; in the twenty-second particular case, the LED linear assemblies are located in space along the edges of the polyhedron; in the twenty-third particular case, LED linear assemblies are located in space along the edges of a polyhedron.

Brief Description of the Drawings

The invention is illustrated by drawings (Fig. 1, 2), where figure 1 shows the relative position of the elements of the device; figure 2 shows the location of the elements of the LED linear assembly.

Disclosure of invention

On the tags are indicated: bulb 1, first contact 2, contact pad 3, second contact 4, socle 5, third contact 6, fourth contact 7, power supply 8, leg 9, LED linear assembly 10, mount 11, holder 12, LED 13 , hole 14, substrate 15, conductive thread 16.

The main elements of the device are LED linear assembly 10, bulb 1 and cap 5.

The LED linear assembly 10 (hereinafter referred to as the assembly) is a substrate 15 with LEDs 13 located on it (or LED chips, where the chip is one crystal with several or one pn junction made on it).

The substrate 15 is usually made of a dielectric material, such as leucosapphire. Also, the substrate material 15 may be glass, ceramic, plastic or metal. In the case of using the conductive material of the substrate 15, the installation of the LEDs 13 on the substrate 15 provides an additional dielectric layer between them. The substrate 15 can be made, for example, in the form of a rectangular plate, in the particular case of perforated. The substrate 15 may be made of a transparent material, as well as of an opaque one. Perforation of the substrate 15 is usually performed in the case of using an opaque material. In this case, the light emitted from the LEDs 13 also propagates through the perforated holes.

LED 13 is a semiconductor device that converts electrical energy into optical radiation energy based on the phenomenon of injection electroluminescence occurring in a semiconductor crystal with an electron-hole transition. The LED 13 contains one light emitting crystal with a high degree of brightness, emitting light in all directions. The most effective LEDs 13 emit light in the blue-violet zone of the visible spectrum. It is possible to use LEDs 13 emitting red, or green, or blue light. If there are several LEDs 13, then they are galvanically connected in series, parallel or series-parallel, and the connection itself is made by conductive threads 16. The LEDs 13 (or LED chips) are located on one of the large sides of the substrate 15. The location of the LEDs 13 (or LED chips ) may be different, in particular, the LEDs 13 (or LED chips) can be located on the same line. Through holes 14 can be formed in the substrate 15. In this case, the LEDs 13 (or LED chips) are located between the holes 14 on the substrate 15. The pads 3 are located on the side of the smaller edges of the plate 3. The LED 13 closest to the smaller edge of the substrate 15 (or LED chip ) is galvanically connected to the nearest contact pad 3 by means of a conductive thread 16. For gluing the LEDs 13 (or LED chips), an adhesive with high thermal conductivity is used. Around each LED 13 (or LED chip) and on the opposite side of the substrate 15 to each of them, a layer of a compound with a phosphor (or a mixture of phosphors) is applied.

The common contour of the LED lamp is formed by the base 5 and bulb 1.

Flask 1 is an airtight shell, shaped, for example, spherical, turning into a cylindrical. The flask 1 has a throat in a particular case at the end of the cylindrical part. Flask 1 assembly with cap 5 has a closed cavity. The cavity is filled with a gas composition under pressure in the range of 8-200 kPa. At least helium or any inert gas or nitrogen is included in the gas composition, and the inclusion of hydrogen in the composition is excluded. On the outer surface of the flask 1, a layer of a special transparent substance can be applied, which provides better heat transfer between the flask 1 and the environment. In the particular case, the layer may form a matte coating of the flask 1.

The cap 5 is a structural part of the LED lamp and serves for its installation and to provide galvanic communication of its internal elements with an external electric source. The base 5 is made, for example, of a cylindrical shape with an internal cavity closed on one side. The base 5 is connected to the flask 1. The connection is made in such a way that the neck of the flask 1 is hermetically fastened in a particular case through a plastic ring with an open part of the inner cavity of the base 5.

A power supply unit 8 is located in the base 5. A power supply unit 8 is designed to convert an alternating voltage of an external electric source into a constant stabilized voltage depending on the number of installed LEDs 13. Thus, the power supply unit 8 is configured to supply voltage to the LEDs 13 in the range of 0.25 -1.00 from the voltage of the external electrical network. A third contact 6 and a fourth contact 7 are brought to the outer surface of the base 5. In a particular case, the third contact 6 is located on the cylindrical part of the base 5, and the fourth contact 7 is on the end side. The third contact 6 and the fourth contact 7 are electrically isolated from each other. The third contact 6 and the fourth contact 7 are electrically conductive pads having contact sections on the outer and inner sides of the base 5. The third contact 6 and the fourth contact 7 are capable of galvanic connection of each with the corresponding input of the power supply 8 (the connection is conventionally shown in FIG. . 1 by a dashed line). The third contact 6 and the fourth contact 7 are made with the possibility of galvanic connection with the respective contact of each of them with the contact of an external electric source (for example, by means of the response base 5 of the part - the cartridge).

The following elements of the device are placed inside the bulb 1: leg 9, holder 12, first contact 2, second contact 4, mount 11 and several assemblies 10.

The leg 9 is, for example, a cylindrical element located coaxially with the base 5 and flask 1 and attached to the base 5 from its inner side. Typically, the size of the leg 9 is such that it protrudes slightly from the cap 5 into the opening of the bulb 1. A holder 12 is attached to the leg 9 from the side opposite to the cap 5, which is a rod located coaxially with the bulb 1 and having a diameter smaller than the diameter of the leg 9 .

At the end of the holder 12, the opposite leg 9, is placed the first contact 2. At the other end of the holder 12 with a slight indentation from the leg 9 is the second contact 4. The first contact 2 and the second contact 4 in the particular case are made in the form of a cylindrical element, the diameter of which slightly exceeds holder diameter 12.

In a plane perpendicular to the holder 12 and located between the first contact 2 and the second contact 4 (for example, in the middle), there is a fastener 11. The fastener 11 is connected to the holder 12 and is an element remote from the holder 12 by a distance greater than the radii of the first contact 2 and the second contact 4. In the particular case, the mount 11 can be made in the form of a ring with a radius larger than the radius of the first contact 2 or second contact 4, and attached to the holder 12 by means of radial elements so that the mount 11 for imalo position coaxial to the holder 12.

In this case, the device may contain several assemblies located between the first contact 2 and the mount 11, as well as several assemblies located between the second contact 4 and the mount 11. One contact pad 3 assembly 10 is attached to the mount 11, and the second contact pad 3 to the first contact 2 or the second contact 4. Thus, the assemblies 10 are inclined relative to the holder 12. If thus, for example, eight assemblies 10 are installed (four between the first contact 2 and the mount 11 and four between the second contact 4 and is attached 11), then assemblies 10 will occupy the positions of the edges of an imaginary octahedron. Variants are also possible when assemblies 10 occupy the positions of the edges of an imaginary hexagon formed by two regular tetrahedrons, or some other polyhedron.

The first contact 2 is electrically connected to the output of the power supply unit 8 through a conductor passed through the material of the holder 12 and the legs 9 to the power supply 8. Similarly, the second contact 2 is electrically connected to the corresponding output of the power supply 8 through a conductor passed through the material of the holder 12 and legs 9 to the power supply 8 (these connections are shown in Fig. 1 by a dashed line). Each pair of assemblies 10, consisting of an assembly 10 located between the first contact 2 and the mount 11, and an assembly 10 located between the second contact 4 and the mount 11, are interconnected by a conductive element. Thus, each pair of such assemblies 10 forms one of the branches of a parallel electrical circuit, the nodes of which are the first contact 2 and the second contact 4. Moreover, each of the branches formed by such a pair of assemblies 10 is a series-connected section of the electrical circuit. In the aggregate, assemblies 10 (series-connected assemblies 10 of one branch and the branch as a whole connected in parallel in parallel) form a series-parallel electrical circuit.

The implementation of the invention

In the case of using the above elements and means, the invention is implemented as follows.

A flask 1 is made, for example, of a spherical shape, turning into a cylindrical base 5 with a power supply 8, a leg 9, a holder 12, a fastener 11, the required number of assemblies 10, as well as the first contact 2 and the second contact 4.

Elements are connected according to the product design described above. Before the final assembly of the product, air is evacuated from the flask 1 and the cavity of the flask 1 is filled with the necessary gas mixture.

The third contact 6 and the fourth contact 7 are introduced into interaction with the response contacts of the external electrical circuit, for example, by screwing the base 5 into the response cartridge. The power supply unit 8 converts the voltage of the external electrical source into the operating voltage necessary for the assembly 10 to work correctly. One or more LEDs 13 located on the substrate 15, when current flows through them, supplied through the conductive thread 16, creates optical radiation. The phosphor layer converts this radiation of the LEDs 13 into optical radiation with a modified spectrum, more favorable for the human eye.

The different inclination of the assemblies 10 relative to the axis of the bulb 1, as well as their relative location, allows depending on the design of the product to arrange the axis of the spatial angles of illumination from each individual assembly 10 so that the general radiation pattern of radiation is closest in shape to spherical (or other necessary shape )

Thus, the implementation of the product as described above ensures the creation of a uniform radiation pattern.

Claims (24)

1. LED lamp containing a flask made of light-tight, base, leg, holder, mount, power supply, first contact, second contact and four LED linear assemblies, the bulb connected to the base is hermetically sealed and filled with a gas composition comprising at least helium, the unit the power supply is located in the base, the leg is fixed in the base from the side of the bulb, the holder is mounted on the leg inside the bulb, in the middle part of the holder there is a mount, and each LED linear assembly contains one LED located and on the dielectric substrate, a part of the LED linear assemblies is located on the opposite side of the mounting base, and the other part of the LED linear assemblies is placed between the leg and the mount, with the LED linear assemblies at one end mounted on the mount remotely from the holder, and the other end of the LED linear assemblies mounted on the holder , the first contact and the second contact are placed inside the flask electrically isolated from each other, the first contact and the second contact are connected to the corresponding to each of them Exit power unit having inputs connected with the corresponding each of them to contact the cap, and the LED linear assembly are respectively connected to the first contact and the second contact to enable the radiation of the visible light range. 2. The device according to p. 1, characterized in that each LED linear assembly contains additional LEDs placed on a common dielectric substrate along it. 3. The device according to claim 1, characterized in that a mixture of a compound and a phosphor is placed around each LED and the opposite side of the substrate relative to each of them. 4. The device according to claim 1, characterized in that the flask is made with a gas pressure in the range of 8-200 kPa. 5. The device according to p. 1, characterized in that the LEDs are emitting light at least from the blue-violet zone of the visible spectrum. 6. The device according to claim 1, characterized in that the flask is connected to the cap through a ring of plastic. 7. The device according to p. 1, characterized in that each LED is made in the form of an LED chip, and each LED chip contains several p-n junctions connected in series, each LED chip has a direct voltage of 5.5 V or higher. 8. The device according to claim 1, characterized in that the LED linear assemblies are interconnected in series and parallel. 9. The device according to claim 7, characterized in that the LED chips are interconnected in parallel. 10. The device according to p. 8, characterized in that the LED chips are interconnected in series and parallel. 11. The device according to p. 1, characterized in that the substrate is made transparent. 12. The device according to p. 11, characterized in that the substrate is made of glass. 13. The device according to p. 1, characterized in that the substrate is made of leucosapphire. 14. The device according to p. 1, characterized in that the substrate is made opaque. 15. The device according to claim 1, characterized in that the substrate is made of metal. 16. The device according to p. 1, characterized in that the substrate is made of ceramic. 17. The device according to p. 1, characterized in that the substrate is made of plastic. 18. The device according to claim 1, characterized in that the holes are made in the substrate. 19. The device according to p. 1, characterized in that the composition of the gas mixture includes nitrogen. 20. The device according to p. 1, characterized in that the composition of the gas mixture includes any inert gas. 21. The device according to claim 1, characterized in that a light-transmitting coating is applied to the glass flask from the outside, which improves heat transfer between the glass and the surrounding air. 22. The device according to claim 1, characterized in that the glass flask is coated on the outside with a matte coating that improves heat transfer between the glass and the surrounding air. 23. The device according to claim 1, characterized in that the LED linear assemblies are located in space along the faces of the polyhedron. 24. The device according to claim 1, characterized in that the LED linear assemblies are located in space along the edges of the polyhedron.

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