RU175186U1 - LED SPOTLIGHT - Google Patents

Abstract

The utility model relates to the field of lighting engineering, namely to lighting devices using LEDs. The technical result is to increase the power of the searchlight. The LED floodlight contains a housing made of heat-conducting material, a light-optical block and a block of power sources, as well as a radiator with a set of radial heat-dissipating ribs, a mounting rotary bracket fixed to the sides of the housing, and a translucent screen covering the front side of the light-block. The light-optical unit includes reflectors installed in rows with an LED module installed in each of them. In this case, the reflectors have a mirror surface of a conical shape. The heat-dissipating ribs are made through and radial and are located around the light-optical block in the form of rays emanating from the center to the periphery. Moreover, the housing contains a set of radial heat-dissipating fins, identical to the fins of a radiator. 22 s.p. f-ly, 4 ill.

Description

The utility model relates to the field of lighting engineering, namely to lighting devices using semiconductor devices (LEDs), and is intended for lighting large open spaces, territories and objects: warehouses, ports, airfields, sports facilities, construction and work sites, storage areas, industrial premises.

Known LED floodlight (patent No. CN 201078670, IPC F21V23 / 00, F21V21 / 00, F21V29 / 00) containing a housing that is also used as a radiator, as well as a mounting bracket for installing it, and light-scattering are used on light sources lenses.

Known floodlight (patent RU 82481 U1, IPC F21S4 / 00, F21W131 / 00 from 04/27/2009) containing a housing made of heat-conducting material, a matrix of LEDs, a current source (if necessary, a control controller), a protective translucent material for use in indoor conditions and protective translucent material together with a sealing gasket and a protective cover for outdoor use, as well as a mounting bracket for mounting.

Known LED floodlight (patent No. 2531367, IPC F21L2 / 00, publ. 20.10.2014) containing radiation sources in the form of LEDs, an optical system placed in front of the LEDs, a means of dissipating thermal energy having a developed surface, and each of the LEDs is installed with the possibility thermal contact with the end surface of one of the identically directed and electrically insulated heat-conducting rods, the lateral surface of which is provided with longitudinal ribs forming open air ducts.

Known LED floodlight (patent No. 2566660, IPC F21S4 / 00, published on 10.27.2015), closest in technical essence to the claimed device and adopted as a prototype, comprising a housing made of heat-conducting material having a light module compartment with solid-state light sources of at least one and a power supply compartment, located above and below, respectively, with a partition between them and united from the back by a set of longitudinal heat-dissipating ribs; a fastening U-shaped bracket with fastening to the sides of the housing, a translucent screen on the front of the spotlight with fastening to the reinforced border of the housing, and the translucent screen is made in the form of modular optics with a set of lenses or one lens, depending on the required light intensity curve, light sources located either in the focus of the lenses of modular optics, or with an offset relative to them; the power source is installed either in the power supply compartment inside the case, or on the back of it outside; the spotlight housing has at least one cooling rib protruding beyond the translucent screen.

The disadvantages of the known devices is the insufficient power of the luminous flux to illuminate such objects as stadiums, airfields and other open areas.

The problem to which the present utility model is directed is to eliminate the aforementioned drawbacks of the prior art.

The technical result of the proposed technical solution is to increase the power of the light flux of the LED floodlight.

At the same time, an increase in the brightness and range of the luminous flux necessary for lighting large open areas is achieved.

At the same time, an increase in operating time is achieved, while reducing the dimensions and weight of the searchlight.

The inventive device is illustrated in the figures:

FIG. 1 is a front view of a spotlight;

FIG. 2 - rear view of the spotlight;

FIG. 3 - side view of the spotlight;

FIG. 4 - connecting compartment.

The inventive device consists of the following elements:

1 - LED modules;

2 - translucent screen;

3 - reflectors;

4 - installation ring-shaped element;

5 - mounting rotary bracket;

6 - power sources;

7 - pressure glands;

8 - a cover of a connecting compartment;

9 - a radiator;

10 - case;

11 - socket;

12 - external power cable.

The inventive floodlight (Fig. 1) consists of a housing 10 made of heat-conducting material containing a light-optical unit and a power supply unit 6, as well as a radiator 9 with a set of heat-dissipating ribs, a mounting rotary bracket 5, fixed to the sides of the housing 10, and a translucent screen 2.

The light-optic unit includes mounted in rows of reflectors 3 with an LED module 1 installed in each of them, while the reflectors 3 have a conical mirror surface.

The heat-dissipating ribs are made through and radial and are located around the light-optical block in the form of rays emanating from the center to the periphery.

The housing 10 contains a set of radial heat dissipating ribs identical to the ribs of the radiator 9.

In one embodiment, the light-optical unit includes four reflectors 3 mounted in two rows of two reflectors 3 in each row.

In other embodiments, reflectors 3 with LED modules 1 are installed in an amount of at least four, and are installed in at least two rows, at least two reflectors in each row.

For example, six reflectors 3 can be used, which are installed two in three rows or three in two rows. Or eight reflectors 3 can be used, which are installed two in four rows or four in two rows.

The number of reflectors 3 and LED modules 1 can be any, and they can be installed in any proportions for any number of rows.

Each reflector 3 has an LED module 1.

Each LED module 1 contains a set of LEDs.

The main structural elements on which all other elements are mounted are the radiator 9, which forms the front of the searchlight, and the housing 10, which forms the back of the searchlight.

The housing 10 is a basis for the elements, contains an internal cavity for mounting all the elements of the searchlight.

The execution of the housing 10 and the radiator 9 separate solid parts provides the convenience and simplicity of the process of assembling the spotlight.

The radiator 9 and the housing 10 are rigidly fixed to each other by the rear sides with screws.

Reflectors 3 and LED modules 1 are fixed with screws to the bottom of the internal cavity of the housing 10.

Reflectors 3 have a conical mirror surface, which allows efficiently concentrating the light flux into a narrow angle (20 °) to create directional lighting.

The combination of four LED modules 1 with reflectors 3 creates a concentrated luminous flux, which can significantly increase the lighting power.

The angle of the conical shape and the depth of the reflectors 3 determine the distribution of the light flux.

The housing 10 contains a set of radial heat-dissipating ribs identical to the ribs of the radiator, which, connecting with the ribs of the radiator 9, form a single radiator block.

Such a connection of the radiator 9 with the housing 10 forms the shape of a searchlight in the form of a rectangular parallelepiped with equal end walls and with rounded corners.

The heat-dissipating fins of the radiator 9 are made through and are fan-shaped around the light-optical block, i.e. directed from the center to the periphery in the form of outgoing rays.

Such a geometric design and arrangement of heat-dissipating ribs allows for the most efficient cooling of the LED block by natural air blowing without installing a fan, thereby increasing the duration of the searchlight and its service life.

More efficient cooling of the LED block allows the installation of more powerful LEDs, thereby providing a more powerful light output and brightness.

The power supply unit 6 is located on the reverse side of the housing 10 and includes two power sources 6 mounted in screws in the specially designated cavities of the housing 10 in parallel with each other using screws (Fig. 2).

Power sources 6 are used to convert the input voltage into a stabilized current for powering the LED modules 1.

The voltage to the power sources 6 is supplied from a sealed distribution compartment (Fig. 4).

Cable entry into the distribution compartment is carried out through three pressure glands 7.

Two pressure glands 7 are located on the back of the housing 10 between the power sources 6, and the third pressure gland 7 is on the lower end wall of the housing.

The input ends of the cables of the power sources 6 through two pressure glands 7 go into the distribution compartment, where they are connected to the external power cable 12, which is also introduced into the distribution compartment through the third pressure lead 7.

The output ends of the cables of the power sources 6 through the holes in the radiator 9 and the housing 10 enter the internal cavity of the housing 10 and are soldered to the pads of the LED modules 1.

The sealing of the distribution compartment is provided by cover 8 and a silicone gasket. Silicone gasket is installed between the compartment and the cover 8.

The cover 8 is pressed and fixed to the distribution compartment with screws.

For safe operation when installing the spotlight on the inner side of the cover 8, a disconnect switch (socket 11) is installed.

The socket 11 when opening the cover 8 of the distribution compartment forcibly opens the power supply circuit of the spotlight, thereby eliminating the risk of electric shock.

The front side of the light-optical unit, located in the inner cavity of the housing 10, is covered by a translucent screen 2, which is installed for sealing through a sealant.

The translucent screen 2 is pressed against the housing 10 by means of an annular element 4, while closing the light-optical block.

The translucent screen 2 is held by clips located two on each side of the screen 2 on the annular element 4.

As a translucent screen 2 is borosilicate tempered glass 2.

The annular element 4 is made in the form of a square with rounded corners and covers the perimeters of the reflectors 3.

On the reverse side of the spotlight, additional heat-dissipating ribs are made to increase heat dissipation from the entire surface of the housing 10.

A rotary bracket 5 (Fig. 3) is attached to the side end walls of the searchlight for mounting the searchlight on any surface.

The swivel bracket 5 has a U-shaped configuration with beveled corners and is paired with a searchlight with the possibility of its movement relative to the vertical axis.

A spotlight mounted on the surface with the help of a swivel bracket 5 has the ability to move up to 70 ° relative to its axis.

The end walls of the searchlight on the side of the mounting of the swivel bracket 5 contain additional rectangular windows formed by cutouts on the housing 10 and the radiator 9, designed for additional cooling of the LED block.

The radiator 9 and the housing 10 are made of a heat-conducting material, preferably a polymer-coated aluminum alloy.

Swivel bracket 5 provides the convenience and ease of installation of the spotlight on various surfaces.

At the fixing ends of the swivel bracket 5, a pair of arched holes are made in mirror image to each other, through which the bracket 5 is fixed with screws to the end walls of the searchlight.

At the same time, the screws do not firmly fix the swivel bracket 5, allowing it to move within the arcuate openings.

On other parts of the swivel bracket 5, additional mounting perforation holes of oval, triangular and round shapes are made to provide additional opportunities for its fixing in its various positions and on various surfaces.

According to one embodiment, the main technical characteristics of the LED floodlight are as follows:

Mains voltage 76-264 V;

The frequency of the mains 47-63 Hz;

Color temperature 4700-5300K;

Color rendering index Ra> 70;

Power factor (cos φ) not less than 0.96;

Operating temperature -40 to + 50 ° С;

Ripples of a light stream no more than 1%;

Searchlight life> 50,000 h;

KSS type (curve of intensity of light) 0-180 °;

Power 450 watts.

In one embodiment, the searchlight is made with a color rendering index Ra> 70 and a color temperature of 5000K, and in another embodiment, with a color rendering index Ra> 90 and a color temperature of 5700K. In the first case, the luminous flux of the searchlight is at least 47,000 lumens, in the second - at least 57,000 lumens.

Such indicators allow you to create uniform contrast lighting, as comfortable as possible for sporting events.

According to one embodiment, the overall dimensions of the searchlight are: height 420 mm, width 397 mm, case thickness 156 mm.

The angle of rotation of the spotlight mounted on the swivel bracket 5, relative to the vertical up to 70 °.

Together with the swivel bracket 5, the weight of the spotlight is 14 kg, which makes the spotlight one of the most lightweight powerful spotlights.

For installation and connection of a searchlight to an electric network:

connect an external power cable 12 to the spotlight;

fasten the swivel bracket 5 to the support, pole, upper base, etc. using bolted or threaded connections using holes in the bracket body;

fix the spotlight on the swivel bracket 5 with the help of 4 M10 bolts, respectively, having previously fixed them in the required position;

turn on the spotlight and check its operation.

The LED floodlight is compact, easy to use, allows you to increase the brightness of the light-optical unit, simplify installation due to the ease of design and increase its durability due to tightness, can be used both in dry rooms and in rooms with high humidity.

The presence of the swivel bracket 5 allows to simplify installation due to the ease of construction, to increase its durability.

The presence and configuration of heat-dissipating fins of the radiator 9 can increase the rigidity of the structure, reduce glare of light from a metal surface.

The geometric shape of the radiator ribs is designed in such a way as to minimize the mass-dimensional characteristics at the installed power.

The advantages of the spotlight are ergonomics, simplicity and ease of installation, maximum light output with reduced power consumption.

LED floodlight has shown high efficiency when illuminating open spaces: sports stadiums, construction sites, logistics complexes, outdoor areas of enterprises.

Claims (23)

1. LED floodlight, comprising a housing of heat-conducting material, a light-optical unit and a power supply unit, as well as a radiator with a set of heat-dissipating ribs, a mounting rotary bracket fixed to the sides of the housing, and a translucent screen covering the front side of the light-optical unit, characterized in that the light-optical unit includes installed in rows of reflectors with an LED module installed in each of them, while the reflectors have a mirror surface of a conical shape, heat-dissipating fins are made through and radial and are located around the light-optical block in the form of rays emanating from the center to the periphery, and the housing contains a set of radial heat-dissipating fins identical to the radiator fins. 2. The searchlight according to claim 1, characterized in that the reflectors with LED modules are installed in an amount of at least four, and are installed in at least two rows, at least two reflectors in each row. 3. The searchlight according to claim 1, characterized in that each LED module contains a set of LEDs. 4. The searchlight according to claim 1, characterized in that the end walls on the side of the mounting bracket contain additional rectangular windows formed by cutouts on the housing and the radiator. 5. The searchlight according to claim 1, characterized in that additional heat dissipating ribs are made on the reverse side of the searchlight. 6. The searchlight according to claim 1, characterized in that the radiator and the housing are rigidly fixed to each other by the rear sides. 7. The searchlight according to claim 1, characterized in that the connection of the radiator to the body forms a searchlight in the form of a rectangular parallelepiped with equal end walls and with rounded corners. 8. The searchlight according to claim 1, characterized in that the housing contains an internal cavity for attaching all elements of the searchlight. 9. The searchlight according to claim 1, characterized in that the power supply unit includes two power sources fixed to the back of the housing parallel to each other. 10. The searchlight according to claim 1, characterized in that the reflectors and LED modules are fixed with screws at the bottom of the internal cavity of the housing. 11. The searchlight according to claim 1, characterized in that the housing contains a distribution compartment, configured to supply voltage to power sources. 12. The searchlight according to claim 11, characterized in that the distribution compartment is closed by a lid and contains a silicone gasket for sealing. 13. The searchlight according to claim 11, characterized in that an isolator is installed on the inside of the lid of the distribution compartment, which is configured to open the luminaire supply circuit when the lid is opened. 14. The searchlight according to claim 11, characterized in that it contains three pressure glands for cable entry into the distribution compartment, two of which are located on the back of the housing between the power sources, and the third on the lower end wall of the housing. 15. The searchlight according to claim 1, characterized in that a sealant is installed between the translucent screen and the housing for sealing. 16. The searchlight according to claim 1, characterized in that the translucent screen is fixed to the housing by means of an annular element. 17. The searchlight according to claim 16, characterized in that the annular element is made in the form of a square with rounded corners and covers the perimeters of the reflectors. 18. The searchlight according to claim 16, characterized in that the translucent screen is held by clips located two on each side of the screen on an annular element. 19. The searchlight according to claim 1, characterized in that the borosilicate tempered glass serves as a translucent screen. 20. The searchlight according to claim 1, characterized in that the casing and the radiator are made of an aluminum alloy with a polymer coating. 21. The searchlight according to claim 1, characterized in that it is made with the possibility of movement relative to its axis by an angle of up to 70 ° by means of a swivel bracket. 22. The searchlight under item 1, characterized in that the swivel bracket contains additional mounting holes of oval, triangular and round shapes. 23. The searchlight according to claim 1, characterized in that the housing and the radiator are solid.

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