RU81599U1 - LED LIGHT LAMP - Google Patents

Abstract

The LED lighting lamp comprises a housing 1 with a cavity 2 located mainly in its central part. The cavity 2 is connected by a hole 3 with the environment. The hole 3 is designed to install and fix the base 4, which can act as a radiator, with light-emitting semiconductor crystals 5 located on it with their electrical contacts 10, in the housing 1 and filling the cavity 2 with an elastic light-conducting medium 6. The cavity 2 is made in such a form that ensures uniform distribution of the medium of the light guide 6 about the crystal surfaces of the light guide 5. such a distribution medium 6 which may contain light scattering particles 7, for example, SiO _2, allowing t form a substantially omnidirectional radiation LEDs. The inclusion of phosphor particles in the light guide medium will allow the formation of a predetermined spectrum of the light flux of the lamp. The technical result is to simplify the manufacturing technology of the device, the formation of a uniform distribution of radiation in a full solid angle in a given spectral range, mainly in the visible range, and slow down the degradation of LEDs. 1 C.p.F., 2 ill.

Description

The technical field to which the invention relates.

The invention relates to lighting engineering, in particular to sources of optical radiation - lighting lamps on semiconductor light emitting diodes.

The prior art.

A light-signal device is known (RF Patent No. 2179280, F21S 8/00, 2002.02.10), which contains a transparent housing with light-emitting diodes (LEDs), external connection contacts, a transparent housing is made perforated with LEDs installed in the perforations, and is installed in the inner cavity of the housing an additional tubular-shaped board equipped with a mirror film with LEDs located in the optical gaps between the projections of the perforations of the transparent case.

The disadvantages of the known devices are: design complexity, significant dimensions and spatial heterogeneity of the light flux.

A known LED lamp (RF Patent No. 2179280, F21S 8/00, 2002.02.10), which contains a central rod and its surrounding groups of LEDs with current-carrying leads, assembled on plates made in the form of flat polygonal boards, some of which are installed in meridional planes intersecting the central rod, a LED is mounted on parts of the sides or edges of each board oriented in the surrounding space, the optical axis of which is perpendicular

the specified side or rib, and live leads are located on the surface of the board.

The disadvantages of the known device are: the complexity of the design, complex manufacturing technology, significant dimensions and spatial heterogeneity of the generated light flux.

A compact LED lamp is known (RF Patent No. 2245489, F21S 8/00, 2005.01.27), which contains several electrical insulating boards, along the perimeter of each of which there are LEDs, while the optical axes of the light sources are oriented on one or both sides thereof meridional planes of the entire active space of light emission. On the back side of the lower electrical insulating printed circuit board with LEDs, the elements of the power supply converter are assembled and the electrical insulating printed circuit board is mounted on a holder interfaced with a standard E 27 type socle.

The disadvantages of the known devices are: design complexity, complex manufacturing technology, significant dimensions and spatial heterogeneity of the radiation pattern of the generated light flux.

Known LED lamp (Application PCT / KROO / 01393, H01L 33/00), containing a flat substrate with LEDs placed on it and the wiring of their electrical contacts placed in a molded case made of transparent material, and electrical conductors connected to the wiring of electrical contacts, performing the role radiators.

The disadvantages of the known device are: complex manufacturing technology, spectral and spatial heterogeneity of the formed

luminous flux due to cracking of the housing as a result of heat exposure, as well as insufficient heat dissipation from LEDs and their rapid degradation as a result of an increase in internal voltage arising from thermal expansion.

The essence of the technical solution.

The technical result, which is aimed at achieving a technical solution, is to simplify the manufacturing technology of the device, the formation of a uniform distribution of radiation at full solid angle in a given spectral range, mainly in the visible range, and slow down the degradation of LEDs.

The technical result is achieved by the fact that the LED lighting lamp contains a housing of transparent material in which at least two light-emitting semiconductor crystals are placed, made in the form of a rectangular parallelepiped, with their electrical contacts installed on the base, a cavity is filled in the housing, filled with a light guide medium in which placed LEDs mounted on the base, the cavity is connected to the environment by a hole in which the base is fixed, the minimum the distances from each point on the surface of the cavity to the surface of the light-emitting semiconductor crystal closest to this point are equal to each other, and the total luminous flux of the crystals is radiated to a full solid angle. In this case, the light guide medium may be an elastic substance.

Enumeration of illustrations.

Figure 1 presents the front view of the LED lighting lamp.

Figure 2 presents a section of an LED lighting lamp.

An example of a lighting lamp.

LED lighting lamp (figure 1, 2) contains a housing 1 with a cavity 2, located mainly in its central part. The cavity 2 is connected by a hole 3 with the environment and is designed to install and fix the base 4 with light-emitting semiconductor crystals 5 located on it with their electrical contacts 10 in the housing 1 and fill the cavity 2 with the light-conducting medium 6. The cavity 2 is made in such a form that ensures uniform distribution of the light guide medium 6 around the surfaces of the crystals 5. This shape is determined by calculating the distance from the points of the surface of the cavity 2 to the nearest points of the nearest crystals 5. This distribution The separation of the light-conducting medium 6, which may contain light-scattering particles 7, for example, SiO ₂ , makes it possible to form an almost uniform radiation pattern of LEDs. The inclusion of phosphor particles in the light guide medium will allow the formation of a predetermined spectrum of the light flux of the lamp.

The housing 1 with a cavity 2 and a hole 3 can be made of any transparent material that can be molded (casting, stamping). The housing 1 may be monolithic or assembled from components. The hole 3 can be made in such a way that its peripheral parts 12 can serve as guides for the base 4 and provide its axial orientation, and the stops 13 provide the positioning of the crystals 5 in the cavity 2 (figure 1). Along the longitudinal axis, hole 3 is made

with a cross section that allows you to enter into the housing 1 crystals 5 located on the base 4.

If the light guide medium 6 is elastic, it can relieve the internal stress of the crystals 5 that occurs during thermal expansion due to its own expansion and changing the boundaries of its location in the hole 3.

The base 4, mainly flat, can be made of a heat-conducting material, for example, from a metal coated with an electrically insulating material 8, to act as a radiator. A wiring topology 9 of the electrical contacts of the crystals 5 is formed on the electrically insulating layer 8. The crystals 5 can be fixed on adjacent or / and opposite sides of the base 4. One or more electrical contacts 10 of the crystals 5 can be made, for example, of a metal wire, for example, gold, soldered at one end to the wiring, and the other to the surface of the crystal 5. Places of soldering can be strengthened by enveloping drops of conductive adhesive 11. One or more electrical contacts of the crystals 5 can yt formed by planting a crystal on a conductive thermally conductive adhesive 11, the wiring at the corresponding location.

If the base 4 is made of metal, it can act as one of the electrical contacts, and the crystals 5 can be fixed directly to the sides of the base 4 by planting the crystals on a heat-conducting adhesive.

The housing 1 can be made in any form, however, mainly in such a way that its surface acts as a concentrating lens or the constituent elements of the surface form a group of at least two concentrating lenses, and the LEDs are located near the focus of the lens or lenses or with the smallest possible removal

From him. Advantageously, the housing 1 is made with a spherical surface.

The inclusion in the composition of the light guide medium 6 particles of the phosphor, allows you to convert the radiation flux of crystals 5, for example, from the ultraviolet or blue part of the spectrum in the region of white light.

In one embodiment of the manufacture of the LED lighting lamp, the crystals may be in thermal contact with the cooling element. The cooling element can be performed, for example, using the Peltier effect.

The connection of the lamp to the electric power source can be done through a standard base, the choice of which depends on the specific purpose of the lamp.

The choice of dimensions and shape of the housing also depends on the specific purpose of the lamp and is limited by the minimum dimensions due to the size of the crystals, the base and, in one of the manufacturing options, the cooling element.

The assembly of the LED lighting lamp is as follows. The base 4 with light-emitting semiconductor crystals 5 previously fixed thereon is placed in and fixed in a predetermined position in the housing 1. The base 4 can be placed in a predetermined position by the guides 12 of the hole 3 and the stops 13 made therein. In the case of a simpler configuration of the base 4 and the hole 3, the placement of the base 4 in a predetermined position can be provided by the installation tool. The base can be fixed with glue, soldering or other rigid joints, or by tightly touching the surfaces of the base 4 and the hole 3. Filling the cavity 2 with a light guide medium 6

can be carried out both before placing the base with crystals in it, and after. Then, if necessary, the polymerization of the light guide medium 6 and the glue are dried.

LED lighting lamp operates as follows.

When direct current is transmitted through light-emitting semiconductor crystals, nonequilibrium carriers are injected into them, which recombine with the release of photons in the visible radiation spectrum. The radiation of crystals passes through the light guide medium, which is the first stage in the formation of the radiation pattern of the LED lighting lamp. The presence of uniformly distributed particles scattering radiation in the light guide medium (SiO ₂ or SiO ₂ + phosphor) allows you to create a uniform radiation pattern in a given wavelength range. After radiation passes through the housing, the final radiation pattern of the LED lighting lamp forms a full solid angle.

Claims (2)

1. LED lighting lamp containing a housing made of a transparent material, in which at least two light-emitting semiconductor crystals are placed with their electrical contacts installed on the base, characterized in that a cavity is filled in the housing, filled with a light guide medium, in which the LEDs mounted on the base, while the cavity is connected to the environment by a hole in which the base is fixed, the minimum distance from each point on the surface of the cavity to the surface The light emitting semiconductor crystal nearest to this point is equal to each other, and the total luminous flux of the crystals is radiated to a full solid angle. 2. The LED lighting lamp according to claim 1, characterized in that the light guide medium is an elastic substance.