RU113812U1 - LED STREET LIGHTING DEVICE - Google Patents

Abstract

1. A LED street lighting device comprising a radiator housing that can be connected to a support structure and has elements for convection heat dissipation on one side and at least one flat surface on the other,! at least one LED unit made with a flat heat-conducting base, on one side of which light-emitting semiconductor elements are fixed, closed by lens covers, and on the other side, the heat-conducting base is mated with a flat surface of the radiator housing,! a power supply unit installed on the side of the elements for convection heat dissipation of the radiator unit and configured to adapt the supplied power supply to the power supply parameters of the LED unit,! a screen made with the described straight forming a convex surface on one side and a concave surface on the other, where a radiator unit with a gap between the concave surface and elements for convection heat dissipation is located, oriented by the LED unit in the direction from the concave surface,! a protective cap made of a translucent material, fixed to the radiator body by a shell with the lens covers of the LED unit in the cap cavity, while the projection area of the screen onto a plane transverse to the device exceeds the area of a similar projection of the radiator body. ! 2. The device according to claim 1, characterized in that the LED unit and the radiator housing are mated through a heat-resistant rubber gasket. ! 3. The device according to claim 1, characterized in that the shell you

Description

The utility model relates to the field of lighting technology, and specifically to a LED street lighting device that can be used for outdoor installation in cold and temperate climatic zones, providing illumination of transport highways, various open areas and territories near buildings and other structures, unlimited time.

Compared with halogen lamps, fluorescent lamps, and mercury lamps that are currently widely used as light sources that consume a lot of energy, LEDs have the advantage of consuming significantly less energy, having a long life and no start-up time. LEDs are capable of emitting high-intensity light, but this significantly increases the heat generation, which leads to a decrease in the life of the LEDs, which necessitates the provision of effective constant heat dissipation in LED lighting devices.

Known LED street lighting device containing a radiator block made in the form of an elliptical plate with elements for convective heat dissipation on both sides, an LED block on one side of which light-emitting semiconductor elements are mounted, also made in the form of an ellipse and fixed in the center of the response shape in the hole radiator unit, a cover with lenses made of translucent material, which covers light-emitting semiconductor elements, as well as a casing made in This is a curvilinear volumetric figure with a part cut off along the plane in the shape of an ellipse around the perimeter, along which a radiator block is fixed to the casing to the outside with a cover with lenses. The casing is made from the side opposite to the location of the radiator block, with ventilation openings that are closed by an external screen mounted on the casing at a distance from its outer surface in a shape that repeats a fragment of the casing surface covered by it (KR 20110029209 A, IPC F21S 13/10, 03/23/2011 )

When operating this well-known outdoor LED lighting device in cold or temperate climatic zones, falling snow and wind fill the cavity between the casing and the screen, which prevents free convection of air through the openings in the air, despite the high temperature of the air coming out through the openings . This leads to overheating of the light emitting semiconductor elements and reduces their service life. In addition, water can accumulate inside the casing cavity, especially during periods when the device is turned off, the casing prevents its evaporation, which may adversely affect the safe operation of the device.

A LED street lighting device is known, comprising a radiator unit made in the form of an ellipsoid part with flat and convex parts and having a socket on the side of the flat part for mounting an LED unit. The convex part of the radiator block is made in the form of a set of cooling fins and is closed on top by a screen located at a distance from the ribs also in the form of a part of an ellipsoid, and ventilation holes are made in the screen. The radiator housing socket is closed by a hinged lid with a plate of translucent material for the passage of light from the LED block. The radiator block is made with ears for fixing on a supporting structure. The power supply is installed on a supporting structure separately in the immediate vicinity of the radiator unit (KR 20110028705 A, IPC F21S 13/10, 03/22/2011).

In this known solution, it is also possible that the precipitation of snow and wind will lead to the filling of the cavity between the radiator block and the screen, which will prevent the free flow of air into the area of the cooling fins, while the radiator case does not remove heat directly from the heated surface of the LED block, which is installed in the socket without direct pairing of the heated surface with the radiator block. These circumstances together lead to overheating of the light-emitting semiconductor elements, which reduces their service life. In this known construction, due to the presence of holes in the radiator casing, water can also accumulate in the cavity of the cavity from the cooling fins, in particular as a result of condensation from atmospheric air. In addition, the implementation of even adjacent, but still separate directly LED lighting devices and its power supply makes it more difficult to manufacture the structure and its installation.

The technical result of the utility model is to expand the arsenal of LED street lighting, to ensure the long-term possibility of reliable and safe use of the LED street lighting device in the open in cold or temperate climatic zones by eliminating the negative impact on the functioning of the device of atmospheric factors of these climatic zones, particularly significant snowfall. The device is effectively cooled, which ensures its significant service life, can be used as a replacement for existing lighting devices through the use of previously supplied power lines and, to a large extent, can use previously constructed supporting structures for installation.

The indicated technical results are achieved by the LED street lighting device, which contains:

- a radiator housing made with the possibility of connection with the supporting structure and having elements for convective heat dissipation on one side and at least one flat surface on the other;

- at least one LED block made with a flat heat-conducting base, on one side of which light-emitting semiconductor elements are fixed, closed with lens caps, and the second side of the heat-conducting base is paired with a flat surface of the radiator body;

- a power supply installed on the side of the elements for convective heat dissipation of the radiator unit and configured to adapt the supplied power supply to the power supply parameters of the LED unit;

- a screen made with the described direct generatrices with a convex surface on one side and a concave surface on the other, where a radiator block is located with a gap between the concave surface and the elements for convection heat dissipation, oriented by the LED block in the direction from the concave surface;

- a protective cap made of translucent material, mounted on the radiator body with a shell with the location of the lens caps of the LED unit in the cavity of the cap.

In this case, the projection area of the screen on a plane transverse to the device exceeds the area of the same projection of the radiator body.

In the best embodiment of the utility model, to increase reliability and safety, the LED unit and the radiator housing are interfaced through a gasket of heat-resistant rubber.

Also, to increase reliability and safety, it is preferable when the shell is made with a skirt protruding in the direction of the screen around the radiator body and holes in the interface zone with the protective cap on the inside of the skirt for free flow of water from the cavity bounded by the skirt. The protective cap can be installed hermetically, and the cavity inside the protective cap in this case communicates with the atmosphere through a non-return valve, which allows air pressure to escape from the cavity inside the protective cap, which eliminates the accumulation of water condensing from atmospheric air inside the protective cap.

In a preferred embodiment of the utility model, the radiator housing is made in the form of a section of the profile of a U-shaped cross section With an external flat surface corresponding to the portion between the protrusions of the specified section, which the radiator housing is paired with the heat-conducting base of the LED unit. Moreover, the elements for convective heat dissipation are made in the form of a set of longitudinal ribs on a portion of the inner surface corresponding to the portion between the protrusions of the cross section of the radiator body, and also in the form of sets of longitudinal ribs corresponding to each of the sections forming the protrusions of the cross section of the radiator body. This embodiment of the radiator casing allows to ensure the manufacturability of the radiator casing with guaranteed continuity of the material, providing reliable thermal conductivity.

In a preferred embodiment of the utility model, the power supply is located in the cavity of the radiator housing, which allows you to combine all the necessary functional elements of the device in one structural module.

The LED street lighting device can be equipped with brackets fixed on the radiator body with axial hinge elements for articulating on the supporting structure. When implementing the device with the installation of the power supply, in this case it can be located in the cavity of the radiator housing between the brackets.

The screen in the preferred embodiment of the utility model is made in the form of a curved plate of a metal alloy with a cross section in the form of a circular arc.

In the best embodiment of the utility model, the LED unit has the following features:

- a flat heat-conducting base on the first side is made with printed conductors on a dielectric layer;

- light-emitting semiconductor elements are fixed using heat-resistant polymer adhesive material;

- the lens covers are made of translucent polymeric material for each semiconductor light emitting element, in the flat base of each of which a centrally located socket is made, and are installed with the location of each semiconductor light emitting element corresponding to each cover in a socket filled with translucent heat-resistant polymer material.

On the basis of each lens cover for securing it, protrusions located in through holes made in the heat-conducting base and melted at the ends during assembly from the second side of the heat-conducting base can be made.

In a preferred embodiment, at the base of each lens cover, an additional recess is made, connected by a linear groove in the base with a socket for displacing a translucent heat-resistant polymer material along it into the additional recess when a lens cover is installed with a semiconductor light-emitting element in the socket. It is possible to make an additional recess in the form of an annular groove around the socket, which is preferably made with a conical lateral surface oriented with the top of the cone in the direction from the base of the lens cover.

In a preferred embodiment, each semiconductor light-emitting element may be fixed with a conductive heat-resistant polymer adhesive material in a portion of a printed conductor of a flat heat-conducting base. It is possible when each semiconductor light emitting element is fixed by a heat-resistant polymer adhesive material in an open area of a flat heat-conducting base. It is also possible when each semiconductor light emitting element is fixed by a heat-resistant polymer adhesive material in an open area of the dielectric layer of a flat heat-conducting base.

In a preferred embodiment, the flat heat conducting base is made of an aluminum alloy, but other suitable materials may be used.

To illuminate various highways with LED street lighting devices installed along them, it is preferable when at least a part of the lens covers are each made in the form of a rectangular shape with rounded corners, the ratio of the length to width of which does not exceed two, with an aspherical surface for forming luminous flux from the opposite side of the base, and the aspherical surface has a convex shape in the direction corresponding to the short side, and the sections are convex oh shapes rising towards the edges corresponding to the short sides.

To illuminate areas of equal length and width, it is possible when at least a portion of the lens covers are each made in the form of a section with a cylindrical surface at the base, continuing in the direction from the base of the surface section in the form of an ellipsoid of revolution.

Light-emitting semiconductor elements can be fixed in rows on a flat heat-conducting base.

The possibility of implementing a utility model is illustrated by an example of a specific implementation of the LED street lighting device, which is illustrated by graphic materials.

Figure 1 shows a LED street lighting device, a longitudinal section; figure 2 is a transverse section.

with a supporting structure element for installing an LED street lighting device.

Figure 3 presents a side view of the LED street lighting device with an element of the supporting structure for fixing it.

Fig. 4 is a cross-sectional view of a radiator body.

Figure 5 shows a fragment of a longitudinal section of the shell with a skirt.

Figure 6 shows a diagram of a LED unit coupled to the radiator body with one light-emitting semiconductor element closed by a lens cap.

The LED street lighting device comprises a radiator housing 1, LED blocks 2, a power supply 3, a screen 4, a protective cap 5, a shell 6.

The radiator housing 1 is made with the possibility of connection with the supporting structure 7 (Fig.2, 3), for which there are brackets 8 (Fig.1, 2).

Each LED unit 2 is made with a flat heat-conducting base 9 (Figs. 1, 2, 6), on one side of which light-emitting semiconductor elements 10 (Fig. 6) are fixed, closed with lens caps 11, and the second side of the heat-conducting base 9 is paired with a flat surface 12 radiator housing 1.

The radiator housing 1 has elements for convection heat dissipation 13, 14 on one side and the aforementioned flat surface 12 on the other (figure 4). The radiator housing 1 is made in the form of a section of the profile of a U-shaped cross section with an outer flat surface 12 corresponding to the section between the protrusions of the specified section, which the radiator housing 1 is paired with the heat-conducting base 9 of the LED unit 2. Elements for convection heat dissipation 13 and 14 are made in the form a set of longitudinal ribs 13 on a portion of the inner surface corresponding to the portion between the protrusions of the cross section of the radiator body 1, and also in the form of sets of longitudinal ribs 14, corresponding each of the sections forming the protrusions of the cross section of the radiator housing 1. The radiator housing 1 is made of aluminum alloy. Other alloys may be used.

The brackets 8 have elements 15 (Fig. 1) of an axial hinge for hinging on the supporting structure 7. The power supply 3 is installed in the cavity 16 of the radiator housing 1 between the brackets 8 on the side of the elements for convection heat dissipation in the form of ribs 13. The power supply 3 is made with the ability to adapt the supplied power to the power parameters of the LED unit 2.

The screen 4 is made with the described direct generatrices of the convex surface 16 (Fig. 2) on one side and the concave surface 17 on the other, where the radiator unit 1 is located with a gap between the concave surface 17 and the elements for convection heat dissipation in the form of ribs 13, 14, oriented LED unit 2 in the direction from the concave surface 17. In this particular case, the screen 4 is a curved plate of a metal alloy with a cross section in the form of a circular arc. Other forms of the cross section of the screen 4 are possible, but the condition must always be fulfilled that the projection area of the screen 4 on a plane transverse relative to the device exceeds the area of the same projection of the radiator body 1. The brackets 8 pass through the hole 18 (Fig. 1) in the screen 4 with supporting structure.

The protective cap 5 is made of translucent material (glass or polymer transparent material) and mounted on the radiator body 1 by a shell 6 with the lens caps 11 of the LED unit 2 in the cavity 19 of the protective cap 5. The shell 6 is made with a skirt 20 protruding in the direction of the screen 4 around the radiator housing 1 and holes 21 (FIG. 5) in the interface zone with the protective cap 5 on the inside of the skirt 20. The protective cap 5 is sealed and the cavity 19 communicates with the atmosphere through the check valve 22 (FIG. 1), upgraded in radiator housing 1.

The LED unit 2 and the radiator housing 1 are interfaced through a gasket 23 (Fig.6) made of heat-resistant rubber. The flat heat-conducting base 9 is made with printed conductors 24 on the dielectric layer 25 and is made of aluminum alloy. For the manufacture of a flat heat-conducting base 9, other known acceptable materials, various composite materials, ceramic, conductive, and also dielectrics can be used. The light-emitting semiconductor elements 10 are fixed in rows using a heat-resistant polymer adhesive material 26, which can be used as a composition on a silicone, in the best case, or acrylic basis.

Each semiconductor light-emitting element is fixed with a conductive heat-resistant polymer adhesive material on the portion of the printed conductor 24 of the flat heat-conducting base 9. To ensure electrical conductivity, a filler in the form of silver is usually introduced into the heat-resistant polymer adhesive material, which is characterized by chemical resistance and the highest coefficient of thermal conductivity at low specific conductivity resistance in the form of powder, microspheres, flakes (flakes). Other suitable metals in other forms may be used. As noted above, each semiconductor light-emitting element 10 can be fixed by a heat-resistant polymer adhesive material 26, which does not have electrical conductivity, in an open area of a flat heat-conducting base 9 (this and the following options are not illustrated with graphic materials). Or, when each semiconductor light emitting element 10 is fixed by a heat-resistant polymer adhesive material in an open area of the dielectric layer 25 of a flat heat-conducting base 9.

Lens covers 11 are made of translucent polymeric material. In a particular case, polycarbonate is used.

In Fig.7 shows the lens cover 11 is a side view with a half longitudinal section along the axis, and Fig.8 is a front view with a half longitudinal section along the axis.

Each lens cover 11 is made in the form of a figure of a rectangular shape with rounded corners 27, the ratio of the length to width of which does not exceed two, with an aspherical surface 28 to form a light flux from the opposite side of the base 29. The aspherical surface 28 has a convex shape 30 in the direction corresponding to the short side 31, and portions 32 of the convex shape rising in the directions toward the edges corresponding to the short sides 31.

In the flat base 29, a centrally located socket 33 is made, where a semiconductor light-emitting element 10 corresponding to each lens cover 11 is located. The socket 33 is filled with a translucent heat-resistant polymer material, mainly on a silicone base, which in the finished product has the form of a gel, but can be solidified to form compositions. It is possible to use compositions on an acrylic basis. Any of the known acceptable phosphors may be introduced into the composition of the translucent heat-resistant polymer material.

On the basis of 29 made protrusions 34, which are located in the through holes made in the heat-conducting base 9 (not shown in the drawings) and fused at the ends 35 during assembly from the second side of the heat-conducting base 9.

At the base 29, an additional recess 36 is made, connected by a linear groove 37 with a socket 33 for expelling a translucent heat-resistant polymer material through it into the additional recess when installing the lens cover 11. The additional recess 36 is made in the form of an annular groove around the socket 33. The socket 33 is made with a conical side surface 37, oriented by the top of the cone in the direction from the base 29.

Aspherical surface 28 is optimized to ensure high uniformity of illumination of a road section with a length of 30 m and a width of 5.6 m when illuminated by two LED street lighting devices made according to a utility model.

In the best embodiment, the aspherical surface 28 is described with respect to three mutually perpendicular axes Z, located centrally relative to the lens cover 11 in the direction from the aspherical surface 28, X, oriented parallel to the long side 38, and Y, oriented parallel to the short side 31, with the following function:

where

R _x = 3.85;

a ₂ = 0.153;

a ₄ = -0.0164;

a ₈ = 9.308 · 10 ^-4 ;

a ₁₀ = 6.71 · 10 ^-7 ;

a ₁₂ = -7.285 · 10 ^-9 ;

a ₁₄ = 3.217 · 10 ^-11 ;

R _y = -75.0;

b ₂ = 4.30 · 10 ^-4 ;

b ₄ = -3.20 · 10 ^-3 ;

b ₆ = 1.90 · 10 ^-4 ;

b ₈ = -8.101 · 10 ^-6 ;

b ₁₀ = 1.35 · 10 ^-7 ;

b _l2 = 0;

b ₁₄ = 0.

The aspherical surface 28 forms the luminous flux of the highest intensity along the long sides 38 of the lens cover 11, as well as in the direction along the width of the lens cover along its short sides 31. The lens covers 11 of the described shape are installed with the long sides 38 oriented along the LED street lighting device, presented as an example implementation of the utility model, that is, along the illuminated section of the road. The LED street lighting device may contain all of the lens caps 11 of the described shape, or only part of them. The lens caps 11, all or part, may have a shape (not shown in the drawings) in the form of a portion with a cylindrical surface at the base, extending in the direction from the base of the surface portion in the form of an ellipsoid of revolution.

The example of the implementation of the utility model is not exhaustive. Other embodiments are possible corresponding to the scope of patent claims. All the details of the LED street lighting device made in accordance with the patent claims are made using known technologies corresponding to the materials used.

Claims (21)

1. An LED street lighting device comprising a radiator housing configured to connect to a support structure and having elements for convection heat dissipation on one side and at least one flat surface on the other, at least one LED block made with a flat heat-conducting base, on one side of which light-emitting semiconductor elements are fixed, covered with lens caps, and the second side of the heat-conducting base is paired with a flat surface of the radiator body, a power supply installed on the side of the elements for convective heat dissipation of the radiator unit and configured to adapt the supplied power supply to the power supply parameters of the LED unit, a screen made with the described direct generatrices of a convex surface on one side and a concave surface on the other, where a radiator block is located with a gap between the concave surface and the elements for convection heat dissipation, oriented by the LED block in the direction from the concave surface, a protective cap made of translucent material, mounted on the radiator case with a shell with the lens caps of the LED unit in the cavity of the cap, while the projection area of the screen onto a plane transverse to the device exceeds the area of the same projection of the radiator case. 2. The device according to claim 1, characterized in that the LED unit and the radiator housing are interfaced through a gasket of heat-resistant rubber. 3. The device according to claim 1, characterized in that the shell is made with a skirt protruding in the direction of the screen around the radiator body and with holes in the interface zone with a protective cap on the inside, side of the skirt for free flow of water from the cavity bounded by the skirt. 4. The device according to claim 1, characterized in that the protective cap is sealed, and the cavity inside the protective cap communicates with the atmosphere through a non-return valve, allowing air pressure to escape from the cavity inside. 5. The device according to any one of claims 1 to 4, characterized in that the radiator housing is made in the form of a section of a profile of a U-shaped cross section with an external flat surface corresponding to the section between the protrusions of the specified section, which the radiator housing is paired with the heat-conducting base of the LED unit, wherein the elements for convective heat dissipation are made in the form of a set of longitudinal ribs on a portion of the inner surface corresponding to the portion between the protrusions of the cross section of the radiator body, and in the form of sets of longitudinal ribs corresponding to each of the sections forming the protrusions of the cross section of the radiator body. 6. The device according to claim 5, characterized in that the power supply is located in the cavity of the radiator housing. 7. The device according to claim 5, characterized in that it is equipped with brackets fixed to the radiator body with axial hinge elements for articulating on the supporting structure, and the power supply is located in the cavity of the radiator body between the brackets. 8. The device according to any one of claims 1 to 4, characterized in that it is equipped with brackets fixed to the radiator body with axial hinge elements for articulating on the supporting structure. 9. The device according to any one of claims 1 to 4, characterized in that the screen is made in the form of a curved plate of a metal alloy with a cross section in the form of a circular arc. 10. The device according to any one of claims 1 to 4, characterized in that the flat heat-conducting base on the first side is made with printed conductors on a dielectric layer, the light-emitting semiconductor elements are fixed using heat-resistant polymer adhesive material, the lens caps are made of translucent polymer material for each semiconductor light-emitting element, in the flat base of each of which a centrally located socket is made, and are installed with an arrangement corresponding its cover each semiconductor light emitting element in a socket-filled translucent heat-resistant polymeric material, 11. The device according to claim 10, characterized in that on the basis of each lens cover for securing it there are protrusions located in the through holes made in the heat-conducting base and melted at the ends during assembly from the second side of the heat-conducting base. 12. The device according to claim 11, characterized in that at the base of each lens cover an additional recess is made, connected by a linear groove in the base with a socket for expelling a translucent heat-resistant polymer material through it into the additional recess when installing a lens cover with an arrangement of a semiconductor light-emitting element in the socket . 13. The device according to p. 12, characterized in that the additional recess is made in the form of an annular groove around the socket. 14. The device according to claim 10, characterized in that the socket is made with a conical lateral surface oriented by the top of the cone in the direction from the base of the lens cover. 15. The device according to claim 10, characterized in that each semiconductor light-emitting element is fixed by a conductive heat-resistant polymer adhesive material on a plot of a printed conductor of a flat heat-conducting base. 16. The device according to claim 10, characterized in that each semiconductor light-emitting element is fixed by a heat-resistant polymer adhesive material in an open area of a flat heat-conducting base. 17. The device according to claim 10, characterized in that each semiconductor light emitting element is fixed by a heat-resistant polymer adhesive material in an open area of the dielectric layer of a flat heat-conducting base. 18. The device according to any one of claims 1 to 4, characterized in that the flat heat-conducting base is made of aluminum alloy. 19. A device according to any one of claims 1 to 4, characterized in that at least a portion of the lens caps are each made in the form of a rectangular shape with rounded corners, the ratio of the length to width of which does not exceed two, with an aspherical surface for the formation of the light flux from the opposite side of the base, and the aspherical surface has a convex shape in the direction corresponding to the short side, and areas of convex shape rising in the directions to the edges corresponding to the short sides. 20. The device according to any one of claims 1 to 4, characterized in that at least a portion of the lens caps are each made in the form of a section with a cylindrical surface at the base, continuing in the direction from the base of the surface section in the form of an ellipsoid of revolution. 21. The device according to any one of claims 1 to 4, characterized in that the light-emitting semiconductor elements are fixed in rows.