RU109825U1 - LED STREET LIGHT - Google Patents

Abstract

 1. LED street light, comprising an installation housing made of aluminum or its alloy, LEDs, a pulsed current stabilizer and a heat sink; wherein the installation case is made in the form of a cup with a flat bottom, and the bottom thickness of this cup is 5-10 mm, and the height of the edges of the walls of the cup above the plane of its bottom is 3-5 mm; all of these LEDs are rigidly fixed at the bottom of the installation case, and between all of these LEDs and the bottom surface of the installation case a layer is formed of such a material that has both good electrical insulating and heat-conducting properties, and on this layer a PCB circuit board is formed using MS PCB technology LEDs, and all these LEDs are electrically connected to the outputs of the indicated electrical circuit for their power supply; the heat sink is made in the form of metal plates arranged mutually parallel and rigidly fixed to the bottom of the installation case on the side on which there are no LEDs, characterized in that at least 100-110 are installed on the inside of the bottom of the installation case light-emitting diodes and with such a density of their placement that on average 1 to 5 cm of these squares account for 5-10 of these light-emitting diodes, while the dimensions of the bottom of the installation case are made so that all of these LEDs are placed on One surface of the bottom and so that their radiating side facing the side opposite to the bottom surface on which the LEDs mounted. ! 2. The LED street light according to claim 1, characterized in

Description

This utility model relates to lighting devices with LEDs and can be used for the manufacture of, for example, street lamps with cantilever mounting on a support.

Street LED lamps are known, manufactured by the company "LED Technologies" in Yekaterinburg and published on the website http://www.dankon.ru/lk_svet48ls.htm. LLC "LED TECHNOLOGIES" - registered 2007.06.27. All these fixtures contain a metal casing in the form of a cup with a flat bottom, and the external shape of this casing is close to the parallelepiped. LEDs are installed inside this cup-case, which are rigidly fixed on one of the sides of the aluminum plate, and this aluminum plate itself is rigidly attached to the bottom of the cup-case from the inside of this bottom and the side on which the LEDs are not mounted. In this case, the indicated metal plate is attached to the bottom of the cup body in such a way that it contacts the bottom as tightly as possible. On the side of the aluminum plate on which the LEDs are mounted, a layer of heat-conducting electrical insulation material is formed, i.e. from a material that has both good thermal conductivity and good electrical insulating properties. An insulated metal substrate (IMP) is usually used as such material. On the specified layer of a thermally conductive insulating material, a power circuit of the LEDs is made in the form of a board, to the corresponding terminals of which are connected the power inputs of the LEDs mounted on the aluminum plate. A pulsed electric current stabilizer is installed inside the cup-case, the outputs of which are connected to the inputs of the power circuit of the indicated LEDs, and the inputs of this electric current stabilizer are left free.

The above-described constructive solution for installing LEDs in the lamp housing provides a good heat dissipation from these LEDs to the cup body of the lamp itself. To remove heat into the surrounding atmosphere, a cooling radiator is rigidly fixed to the outer side of the casing-cup wall of this lamp, which is made in the form of metal plates located mutually parallel at a distance of (0.5-1.0) cm from each other, all of these plates can be located parallel or perpendicular to the plane of the bottom of the casing-cup of this lamp.

All the fixtures described above differ from each other, mainly, by their aperture ratio.

The closest known one is the “Street Lighting Lamp with High-Power LEDs” manufactured by Svitelcom LLC (Ukraine). This lamp is published on the website http://www.svl.com.ua/td/led/lamp.htm, RegDate (publication date): 2002-11-23.

This street lamp has basically the same design as the analogues described above, i.e. it contains a metal case in the form of a cup with a flat bottom, but the external shape of this case is close to a drop-shaped one. Powerful LEDs are installed inside this cup-case, which are rigidly fixed on one of the sides of the aluminum plate, and this aluminum plate itself is rigidly attached to the bottom of the case - the cups on the inside of this bottom and the side on which the LEDs are not mounted. Moreover, each of these LEDs contains only one semiconductor light-emitting crystal mounted on an aluminum base, and the emitting surface of this crystal is covered with a phosphor layer. The specified aluminum plate is rigidly attached to the bottom of the body - the cup and so that it is most tightly in contact with this bottom. On the side of the aluminum plate on which the LEDs are mounted, a layer of such a material is formed, which has both good heat-conducting and electrical insulating properties. This layer is usually made of an insulated metal substrate (see http://www.ncab.ru/front_end/pages/news/2) or from the material "Prepreg". On the specified layer of material having both good electrical insulating and heat-conducting properties, a power circuit of the LEDs is made in the form of a board, to the corresponding conclusions of which are connected the power inputs of the LEDs mounted on the aluminum plate. A pulsed voltage regulator is installed inside the cup housing, the outputs of which are connected to the inputs of the power circuit of the indicated LEDs, and the inputs of this current stabilizer are left free.

The above-described constructive solution for installing LEDs in the housing of the lamp provides a good heat sink from these LEDs to the body - the cup of the lamp itself. To remove heat into the surrounding atmosphere, a cooling radiator is rigidly fixed on the outer side of the casing wall - cups of this lamp from the bottom side, which is made in the form of metal plates located mutually parallel at a distance of (0.5-1.0) cm from each other, moreover, all these plates are parallel to the plane of the bottom of the body - the cup of the lamp.

The intensity of the light emitted by this street lamp is determined by the light power of the emitters and their number per unit area on which they are installed in the illuminator, i.e. in this lamp. The number of emitters per unit area of their installation is determined by the size of these emitters. In this lamp, LEDs are installed as emitters, each of which contains only one emitting semiconductor crystal. The size of the LED is determined not only by the size of the semiconductor crystal contained in it, but also by the design of this LED itself. In this case, the dimensions of the LED are much larger than the dimensions of the emitting semiconductor crystal installed in it. Therefore, the installation of LEDs in the illuminator with one emitting semiconductor crystal has significant limitations on increasing the number of emitters per unit area of their installation and does not allow increasing the light flux from the illuminator without increasing the power of the emitters themselves, in this case, the LEDs.

Thus, the known lighting devices with LEDs do not allow to significantly increase the strength of the light emitted by them, because the number of light-emitting semiconductor crystals per unit of the emitting surface of the lighting device is determined by the size of the LEDs installed in this device. At the same time, it is known that at present, Group Sharp CORPOATION has launched the production of Zenigata high-power multi-crystal LED modules. But for the use of these modules in street lights, it is necessary that at least three such modules are installed in the same plane on the same plane. However, in this case, the modules will emit a large amount of heat in total and it will be necessary to solve the problem of removing this heat from the LEDs, because otherwise, the heat generated will significantly reduce the efficiency of semiconductor light-emitting crystals, i.e. significantly reduce the intensity of the light flux they create. At the same time, it should be noted that the installation of the above fully finished LED modules, i.e. modules, the radiating crystal surface of which is coated with a phosphor, over which, in addition, a collecting lens is mounted, is not always a cost-effective solution, because the finished module is an expensive product.

The objective of this utility model is to significantly increase the number of light-emitting semiconductor crystals per unit of emitting surface in the lighting device while ensuring good heat removal from each of these crystals and while ensuring sufficiently high economic efficiency from the installation of these crystals with a high density.

The problem is solved in that, as is known, this LED street light contains an installation case made of aluminum or its alloy, LEDs, a pulsed stabilizer of electric current and a heat sink; wherein the installation case is made in the form of a cup with a flat bottom, and the bottom thickness of this cup is (5-10) mm, and the height of the edges of the cup walls above the plane of its bottom is (3-5) mm; all of these LEDs are rigidly fixed to the bottom of the installation case, and between all of these LEDs and the bottom surface of the installation case a layer is formed of such material that has both good electrical insulating and heat-conducting properties, and on this layer a circuit board of the indicated power circuit is formed using MS PCB technology LEDs, and all these LEDs are electrically connected to the outputs of the indicated electrical circuitry for their power supply; the heat sink is made in the form of metal plates arranged mutually in parallel and rigidly fixed to the bottom of the installation case from the side on which there are no LEDs,

Unlike the well-known, in this LED street light on the inside of the bottom of the installation case, at least (100-110) LEDs are installed and with such a density of their placement that on average 1 cm ^{2 of} this area accounts for (5-10) these LEDs, and the dimensions of the bottom of the installation case are made so that all of these LEDs are placed on one surface of this bottom and so that their emitting side is directed to the side opposite to the bottom surface on which these LEDs are mounted Lena.

The aforementioned minimum density of semiconductor light-emitting crystals is due to the fact that, at a lower density of their placement, the wavefront of light emitted by all these crystals will be uneven in intensity, which will reduce the surface illumination efficiency of the LED illuminator. With a higher density of semiconductor light-emitting crystals, their thermal effect on each other will be so high that their light output can significantly decrease. In this case, the creation of a strong luminous flux sufficient to illuminate a surface with an area of even 1 m ² at a distance of at least 2 m from this illuminator will not be ensured, which is unacceptable for a street illuminator.

In this LED street light, all the LEDs on the bottom surface of the installation housing can be placed evenly. This will ensure a uniform distribution of radiation intensity in the cross section of the light flux.

In this LED street light, all the LEDs on the bottom surface of the installation case can be arranged in separate groups, each of these groups containing LEDs that are placed on an area of (100-110) mm and with a density of (25-30) pcs. ./cm ² , and each of these groups is located from the neighboring one at a distance of (5-7) mm. This solution provides new technological opportunities for the assembly of this illuminator.

In this LED street light, a layer of material having both good electrical insulating and heat-conducting properties can be formed of heat-conducting ceramics, for example, aluminum nitride. This improves LED cooling.

In this LED street light, LEDs can be installed in the form of multicrystalline modules, and these modules are located at a distance of (5-7) mm from each other and are electrically connected to the pulse electric current stabilizer in parallel or in series. This allows you to improve the manufacturing technology of this illuminator.

In this LED street light, the LEDs on the inner surface of the bottom of the installation case can be installed in the form of multi-crystal Zenigata LED modules of the Group Sharp CORPOATION company, and all these multi-crystal LED modules are installed so that their base fits snugly directly to the bottom surface of the installation case.

In this LED street light, all the LEDs from the side of their emitting surface can be coated with a layer of a phosphor that emits visible light under the influence of radiation from these LEDs, and this layer is made of such a thickness that the specified phosphor provides the most complete conversion of radiation coming from these LEDs. This makes it possible to obtain radiation of the desired color.

In this LED street light, the phosphor can be deposited on the surface of the transparent plate, and the transparent plate itself is mounted on the cup-body of this illuminator and so that it overlaps all light-emitting crystals and faces these crystals on the side on which the specified phosphor is applied .

In this LED street light in the installation case, on the side opposite to its bottom, a window closed with transparent material can be made, while this window has such dimensions and is positioned so that radiation emitted by all the LEDs passes through it.

In this LED street light, the heat sink can be made in the form of (4-7) identical aluminum plates with a thickness of (1-4) mm and a size of ((80-90) × (550-570) mm, all of which are rigidly fixed to installation case from the outside of its bottom and are arranged mutually parallel at a distance of (4-6) mm from each other. This improves LED cooling.

In this LED street light, all aluminum plates of the heat sink can be installed parallel to the bottom plane of the installation case, and a gap of (4-6) mm is made between the bottom and the plate closest to it.

In this LED street light, all aluminum plates of the heat sink can be installed perpendicular to the bottom plane of the installation case on which they are installed, at a distance of (4-6) mm from each other, one of the side edges of each of these plates being rigidly connected to the outer surface this bottom.

In this LED illuminator, a layer of material having both good electrical insulating and heat-conducting properties can be formed from a material called "Insulated Metal Substrate" or from Prepreg material (see http://www.ncab.ru/front_end/pages / news / 2).

In this LED illuminator, a layer of material having both good electrical insulating and heat-conducting properties can be formed from aluminum nitride.

The increase in luminous flux in this LED illuminator is achieved due to the fact that semiconductor light-emitting crystals are installed in it with a high density of their placement (15-30 crystals / cm ² ). The LEDs used in the analogs contain only one crystal located on an area of ~ 0.25 cm ² or 4 crystals per 1 cm ² . Therefore, the magnitude of the light flux coming from the above crystals

LED modules are much larger than the amount of light output coming from single crystal LEDs. In the above LED modules, all LED crystals are mounted on a substrate of a substance having good heat-conducting and electrical insulating properties, for example aluminum nitride, and an electrical power supply circuit for this LED crystal is formed on the same substrate. As a result of this, each of the LED crystals installed in the module is provided with a good heat sink to the radiator, which, in turn, ensures high light emission efficiency of these crystals. At the same time, the crystal density was set so that the heat released by them manages to escape through the substrate without overheating the crystals themselves, and at the same time, this density is such that the light flux coming from each of the crystals merges with each other, creating enough uniform light field.

The design of this street LED illuminator is shown in the accompanying description of figures 1, 2 and 3.

Figure 1 shows a photograph of a General view of a street LED illuminator.

In figure 2. The street LED illuminator assembly with the cover removed in 3 projections is shown.

In figure 3. shows a side view of the street LED illuminator in side and from one of the ends in section.

The outdoor LED illuminator contains a metal housing 1, a metal base plate 2, multi-crystal modules of

Zinigata 3 semiconductor light-emitting crystals (semiconductor light sources), pulsed electric current stabilizer 4, heat sink radiator 5.

The metal case 1 is made in the form of a cup with a flat bottom. In this case, the shape of the cup can be any - round, oval, rectangular or some other.

Zinigata 3 multi-crystal LED modules are rigidly fixed on one of the sides of the base plate 2 and are placed uniformly and at a distance of (5-7) mm from each other. Moreover, all of these Zinigata 3 LED multicrystalline modules are electrically connected in series and / or parallel by conductors to a pulse electric current stabilizer 4.

In the internal space of the metal casing 1, pulse electric current stabilizers 4 are also installed, the number of which can be more than one. Moreover, these switching electric current stabilizers 4 are rigidly fixed to the bottom of the metal housing 1 and are located next to the base plate 2. Multicrystalline LED modules Zinigata 33 are connected in series and / or parallel to the electrical outputs of the pulse stabilizers of electric current 4, and the electrical inputs of these pulse electric current stabilizers 4 are left free and can be connected to an electric power source, for example, to an electrical network.

A removable cover 6 is fixed at the ends of the side walls of the metal housing 1, which covers the internal space of the metal housing 1. The removable cover 6 is made of metal sheet and in that place of this removable cover 6, which is located against the Zinigata 3 multi-crystal LED modules, a window 7 is made, which covered with transparent material for optical radiation. In this case, the side of the window 7 facing the multicrystalline LED modules 3 is covered with a layer of phosphor emitting light under the influence of radiation incident on it from the LED modules Zinigata 3.

A piece of pipe 8 is rigidly attached to one of the sides of the metal casing 1, which makes it possible to attach a metal casing 1, and therefore the entire street LED illuminator, to some console-mounted pin.

Street LED illuminator operates as follows.

An electric current is supplied to the electrical inputs of a pulse voltage stabilizer 4 from a household electrical network. The electric current converted in the specified pulse stabilizer 4 is supplied to the electrical inputs of the Zinigata 3 multi-crystal LED modules, as a result of which all these modules 3 begin to emit light. Because Since all these multi-crystalline modules 3 are located in close proximity to each other, the light flux coming from each of these modules overlap each other. As a result of this, the luminous fluxes from all the multi-crystalline modules 3 are added into one luminous flux having a large luminous power. At the same time, a removable cover 6 mounted on the metal housing 1 protects the Zinigata 3 multi-crystal LED modules from adverse effects of the surrounding atmosphere, and the light flux generated by these modules 3 passes into the surrounding space through a transparent window 7 made in the removable cover 6. the side of this transparent window 7 may be coated with a phosphor layer, which converts the radiation emitted by the multi-crystal modules 3 into radiation of a different color. The heat generated in this case by both the crystals and their power supply circuit is discharged through the aluminum nitride substrate on which these modules are installed, goes to the bottom of the installation case 1 along the walls of this case 1, to the heat sink radiator 5 and from the heat sink radiator 5 is dissipated into the surrounding atmosphere . As a result of all this, Zinigata 3 multi-crystal LED modules are effectively cooled by ambient air to operating temperatures and generate light flux also with the greatest efficiency.

Claims (12)

1. LED street light, comprising an installation housing made of aluminum or its alloy, LEDs, a pulsed current stabilizer and a heat sink; wherein the installation case is made in the form of a cup with a flat bottom, and the bottom thickness of this cup is 5-10 mm, and the height of the edges of the walls of the cup above the plane of its bottom is 3-5 mm; all of these LEDs are rigidly fixed at the bottom of the installation case, and between all of these LEDs and the bottom surface of the installation case a layer is formed of such a material that has both good electrical insulating and heat-conducting properties, and on this layer a PCB circuit board is formed using MS PCB technology LEDs, and all these LEDs are electrically connected to the outputs of the indicated electrical circuit for their power supply; the heat sink is made in the form of metal plates arranged mutually parallel and rigidly fixed to the bottom of the installation case on the side on which there are no LEDs, characterized in that at least 100-110 are installed on the inside of the bottom of the installation case LEDs and with such a density of their placement that on average 1 to 5 cm ^of this area are 5-10 of these LEDs, while the dimensions of the bottom of the installation case are made so that all of these LEDs are placed on and one surface of this bottom and so that their radiating side is directed to the side opposite to the bottom surface on which these LEDs are mounted. 2. The LED street light according to claim 1, characterized in that in it all the LEDs are placed uniformly on the bottom surface of the installation case. 3. The LED street light according to claim 1, characterized in that in it all the LEDs are located on the bottom surface of the installation case in the form of separate groups, each of these groups comprising LEDs located on an area of 100-110 mm and placed with a density of 25-30 pieces / cm ² , and each of these groups is located from the neighboring at a distance of 5-7 mm. 4. The LED street light according to claim 1 or 2, characterized in that in it a layer of material having both good electrical insulating and heat-conducting properties is formed of heat-conducting ceramics, for example, aluminum nitride. 5. The LED street light according to claim 3, characterized in that the LEDs are installed in the form of multicrystalline modules, and these modules are located at a distance of 5-7 mm from each other and are electrically connected to the pulse electric current stabilizer in parallel or in series. 6. The LED street light according to claim 5, characterized in that in it directly on the inner surface of the bottom of the installation case, the LEDs are installed in the form of Zenigata multi-crystal LED modules from Group Sharp CORPOATION, and all of these multi-crystal LED modules are installed in such a way that they base tightly fit directly to the bottom surface of the installation case. 7. The LED street light according to claim 2 or 3, characterized in that in it all the LEDs from the side of their emitting surface are coated with a layer of such a phosphor that emits visible light under the influence of radiation of these LEDs, and this layer is made of such a thickness that the specified phosphor the most complete conversion of radiation coming from these LEDs was provided. 8. The LED street light according to claim 7, characterized in that the phosphor is deposited on the surface of the transparent plate, and the transparent plate itself is mounted on the cup body of this illuminator and so that it overlaps all light-emitting crystals and is facing these crystals the side on the surface of which the specified phosphor is applied. 9. The LED street light according to claim 1, characterized in that in it in the installation case from the side opposite to its bottom there is a window closed with a transparent material, said window having such dimensions and positioned so that radiation passes through it, emitted by all LEDs. 10. The LED street light according to claim 1, characterized in that the heat sink in it is made in the form of 4-7 identical aluminum plates with a thickness of 1-4 mm and a size of (80-90) × (550-570) mm, all of which rigidly mounted on the installation housing from the outside of its bottom and are arranged mutually in parallel at a distance of 4-6 mm from each other. 11. The LED street light according to claim 10, characterized in that in it all the aluminum plates of the heat sink are installed parallel to the plane of the bottom of the installation case, and a gap of 4-6 mm is made between the bottom and the plate closest to it. 12. LED street light according to claim 10, characterized in that in it all the aluminum plates of the heat sink are installed perpendicular to the plane of the bottom of the installation case on which they are installed, at a distance of 4-6 mm from each other, one of the side edges of each these plates are rigidly connected to the outer surface of this bottom.