EA028021B1 - Led lamp - Google Patents

Abstract

The invention relates to illumination devices. The technical result consists in changing the light intensity curve without disassembling the lamp itself or the parts thereof. The LED lamp comprises a housing containing a printed circuit board with LEDs, a primary optical system and a secondary optical system. The LEDs form segments onto which the primary optical system is installed directly, the secondary optical system being positioned thereabove and containing a group of lenses and installed with the possibility of radial displacement relative to the axis of the lamp.

Description

The invention relates to lighting devices and can be used as a stationary LED lamp for indoor lighting of mass use.

The claimed lamp can be built into ceilings, in particular, in false ceilings of rooms.

State of the art

The use of LEDs as light sources provides low power consumption, as well as small overall dimensions of the product, which makes LED lamps in demand in the modern market. One of the most important advantages of LED lamps is the ability to focus and direct the light flux in the right direction.

Currently, there is a need to install additional lighting at workplaces for spot work, which increases energy consumption and the cost of additional lighting equipment. Also, in the conditions of lighting warehouses, there is a need to change the light intensity curve (KSS) depending on their load, namely, in conditions of storage in rooms with narrow passages between the racks and their full load under the ceiling, there is a need to create a narrow directional curve of the force curve light, with a small workload, there is a need to create a wide diagram to provide more uniform illumination of objects. To date, the luminaires on the market do not allow the adaptation of KCC in place.

Known LED lamp (options) (patent KI No. 98542, IPC P21814 / 00, publ. 10/20/2010), comprising a housing of heat-conducting material, closed by a panel of translucent material, in which a printed circuit board with LEDs and a control unit are installed.

Known LED lamp (patent KI No. 114124, IPC P2184 / 00, publ. 04/10/2012) containing radiator plates bonded to each other and with a base, forming a heat-distributing surface and mounted on the base of the LED module containing a board with LEDs and a lens.

Known LED lamp (patent KI No. 112446, IPC Р21Ь4 / 00, publ. 10.01.2012) containing a diffuser housing, a cover, a printed circuit board with LEDs and an electronic circuit for controlling them, and lenses, the inner active surface of the diffuser housing contains at least one collimator lens having a cone shape with a radial side wall and truncated at the base to a regular hexagon.

A known lamp (patent KI No. 102749, IPC Р21Ь4 / 00, publ. 04/10/2011) containing a heat-conducting gasket, a printed circuit board with installed LEDs and a transparent panel with lenses, a heat-conducting gasket is applied to the printed circuit board made in the form of a solid plate; the cover is made in the form of a transparent panel with biconvex, plano-convex, concave-convex, biconcave, flat-concave, convex-concave lenses, coaxial with LEDs.

Known LED ceiling lamp (patent KI No. 112341, IPC P2188 / 00, publ. 10.01.2012), the closest in technical essence to the claimed device and adopted as a prototype, containing a housing with a fixed circuit board in it, on which light-emitting diodes, the primary optical system and a secondary optical system.

However, the known luminaires do not allow arbitrarily changing the light intensity curve depending on the need for lighting the premises.

Summary of the invention

The problem to which the invention is directed is to create a lamp that allows you to change the radiation pattern (distribution) of the light intensity curve without dismantling the lamp itself or its parts.

An additional task to which the claimed invention is directed is to reduce the overall dimensions and weight of the product, as well as simplify its maintenance and expand the range of applications.

The technical result consists in increasing the operational characteristics of the lamp by changing the curve of the light intensity.

The problem is solved by the use of a complex optical-mechanical system that allows, without dismantling the lamp itself or its parts, to change the light intensity curve.

The technical result is achieved by the fact that in the LED luminaire comprising a housing with a printed circuit board fixed on it, on which the LEDs, the primary optical system and the secondary optical system are placed, it is new that the LEDs form segments onto which the primary optical system is directly mounted, and above it is a secondary optical system containing groups of lenses and mounted with the possibility of radial movement relative to the axis of the lamp.

LEDs form three segments with an angle of 40 ° and lag behind each other by an angle of 80 °.

The secondary optical system contains three groups of lenses.

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Each group of lenses of the secondary optical system contains three segments with an angle of 40 °, equidistant from each other.

The segments included in the group of lenses of the secondary optical system contain lenses of the same degree, having their own form of refraction function.

The printed circuit board and the secondary optical system have the shape of a circle with the same diameter and are located on the same axis.

The distance between the primary optical system and the secondary optical system is minimal.

The secondary optical system is fixed to the housing via a rim using a movable connection.

Along the edge of the secondary optical system are positional marks.

An electronic unit and a stepper motor are installed in the housing, the output shaft of which with the gear is located on the rim of the secondary optical system.

The secondary optical system is installed with the ability to control wirelessly or manually.

From below, the secondary optical system is covered by a protective screen made of optically transparent material.

The primary optical system is mounted directly on the LEDs and has the form of a single lens, or lens system, the number of which corresponds to the number of LEDs.

A printed circuit board contains one segment of LEDs occupying half its surface, while the secondary optical system contains two groups of lenses occupying half its surface.

The printed circuit board contains two segments of LEDs occupying two quarters of its surface and arranged in a checkerboard pattern, while the secondary optical system contains four segments staggered into two groups of lenses.

DESCRIPTION OF PREFERRED EMBODIMENTS

The claimed technical solution is characterized by FIG. 1-5.

In FIG. 1 shows a General view of the lamp with a cut.

In FIG. 2 presents a fragment of the lamp, type A.

In FIG. 3 shows a view of the lamp from below.

In FIG. 4 shows a view of the lamp from below, view BB.

In FIG. 5 shows a general view of the lamp.

The LED lamp contains a housing 1, in the lower part of which is mounted a circular printed circuit board 2 with the working surface down, on which light-emitting elements (LEDs) are located.

In a preferred embodiment, the LEDs are grouped into three identical angular segments at an angle of 40 ° relative to the center of the board, are located equidistant from each other, i.e. in increments of 80 °.

The primary optical system 3 is mounted directly on the LEDs, which can be in the form of a single lens that repeats the shape of the board, or a plurality of lenses, the number of which corresponds to the number of LEDs and is mounted directly on them.

Below, above the primary optical system 3 and on the same axis as the printed circuit board 2, there is a round optical secondary system (multi lens) 4 with a diameter equal to the diameter of the printed circuit board 2.

In a preferred embodiment, the secondary optical system consists of nine lens segments combined in three lens groups.

All segments of the secondary optical system 4 are equal and made at an angle of 40 ° relative to the center of the secondary optical system 4.

The segments of each group of lenses are located equidistant from each other and have lenses of the same degree.

Lenses included in one group have their own form of refraction function.

Each segment of the secondary optical system 4 in shape and size corresponds to each segment of the LEDs on the printed circuit board 2.

The distance between the primary optical system 3 and the secondary optical system 4 should be minimal.

The secondary optical system 4 is attached to the housing 1 by means of a movable connection by means of a rim for radial movement relative to the axis of the lamp.

Along the edge of the secondary optical system 4, positional marks are applied to determine the angle of rotation of the secondary optical system 4.

On the outer radius of the secondary optical system 4 in contact with the rim, the output shaft 5 of the stepper motor with gear is installed.

In the housing 1 is a stepper motor and an electronic unit 6, designed to control the operation of the lamp.

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The secondary optical system 4 can be controlled via a wireless communication channel (using the remote control or computer), or manually.

The secondary optical system 4 is covered by a protective screen made of optically transparent material.

In another embodiment, the printed circuit board 2 may contain one segment of LEDs occupying half the working surface of the printed circuit board 2. In this case, the secondary optical system 4 will contain two groups of lenses occupying half the working surface of the secondary optical system 4.

Also, the printed circuit board 2 may contain two segments of LEDs occupying two quarters of the working surface of the printed circuit board 2 and arranged in a checkerboard pattern. In this case, the secondary optical system 4 will contain four segments, staggered into two groups of lenses.

Further, the printed circuit board 2 and the secondary optical system may comprise a plurality of LED segments and lens groups.

The device operates as follows.

Initially, the segments of the LEDs are installed strictly above one of the lens groups of the secondary optical system 4. When the power is turned on, the signal enters the electronic unit 6 located in the housing 1. The electronic unit 6 converts the incoming alternating current into direct current, which is fed to the LEDs segmented on the printed circuit board 2. All LEDs light up simultaneously, creating a luminous flux, which, passing through the primary optical system 3 and the secondary optical system 4, is amplified and directed towards the illumination by this surface.

If there is a need to change the angle of illumination, the signal from the remote control, or from a computer, enters the electronic unit 6, which starts the stepper motor, which drives the output shaft 5. Through the gear transmission, the gear rotates the secondary optical system 4 by one step to the next position mark and each segment of one group of lenses of the secondary optical system 4 stands strictly above each segment of the LEDs.

In a preferred embodiment, three segments are included in one lens group with three LED segments.

Thus, geometrically combining the segments of the secondary optical system 4 strictly with the segments of the LEDs, three types of refraction function of the secondary optical system 4 can be obtained, which together with the LEDs can change the angle of illumination and KSS.

To further change the angle of illumination, the secondary optical system 4 is moved to the next mark by supplying a new signal to the electronic unit 6.

The secondary optical system 4 can be moved manually by turning the secondary optical system 4 until a characteristic click occurs at the moment the secondary optical system 4 moves to the next mark.

Management of the lamp is as follows.

When power is supplied to the driver located in the electronic unit 6, the microcontroller control system is launched, which consists of a switching power supply, a stepper motor, a microcontroller, and a wireless communication channel unit using the ΖίβΒοο protocol.

The microcontroller system works according to the following algorithm (the countdown starts from the moment the voltage is applied):

1. Initialization of the microcontroller (setting input / output ports and peripheral modules).

2. Initialization of the wireless communication channel unit (setting up I / O ports, peripheral modules, starting PWM with the last saved values, searching for a network, joining a network).

3. Initialization of the position of the secondary optical system 4 (search for the starting position, setting the last saved position) When commuting the windings of the gear on the output shaft 5 of the stepper motor through the gear transmission, the secondary optical system 4 rotates.

4. Waiting for a command over a wireless protocol.

5. When passing the command to adjust the brightness in the block of the wireless communication channel, the PWM value is adjusted, thereby adjusting the driver output current. The system goes into standby mode for new data.

6. When passing the command to adjust the position of the secondary optical system 4, the wireless channel unit transmits this command via the serial interface to the microcontroller. In the microcontroller, the command is processed and the position of the secondary optical system 4 is adjusted by switching the windings of the stepper motor by the microcontroller. When switching the windings, the gear on the output shaft 5 of the stepper motor rotates the secondary optical system 4 through the gear transmission. During rotation, the position marks switch the computer, thereby reporting the positions of the secondary optical system 4. When the secondary optical system 4 is set to the specified position, the stepping windings are switched engine. The last position of the secondary optical system 4 is immediately stored in the non-volatile memory of the microcontroller with its subsequent verification of the correctness of the stored data. The system goes into standby mode for new data.

The inventive lamp allows you to provide a powerful stream of light sufficient to illuminate industrial and commercial premises with the possibility of arbitrary changes in the light intensity curve depending on the needs for its change at a given time without dismantling the lamp or its parts.

Also, the proposed design allows you to create an economical, with a guaranteed long service life indoor lamp.

Claims (15)

CLAIM 1. The LED lamp, comprising a housing with a printed circuit board fixed on it, on which the LEDs, the primary optical system and the secondary optical system are located, characterized in that the LEDs form sectors on which the primary optical system is directly mounted, with a secondary optical system located above it containing groups of lenses and mounted for rotation about the axis of the lamp. 2. The lamp according to claim 1, characterized in that the LEDs form three 40-degree sectors located in increments of 80 °. 3. The lamp according to claim 1, characterized in that the secondary optical system contains three groups of lenses. 4. The lamp according to claim 1 or 3, characterized in that each group of lenses of the secondary optical system contains three 40-degree sectors located in increments of 80 °. 5. The lamp according to claim 1, characterized in that the sectors included in the group of lenses of the secondary optical system contain lenses with the same optical properties. 6. The lamp according to claim 1, characterized in that the printed circuit board and the secondary optical system are in the form of a circle with the same diameter and are located on the same axis. 7. The lamp according to claim 1, characterized in that the distance between the primary optical system and the secondary optical system is minimal. 8. The lamp according to claim 1, characterized in that the secondary optical system is mounted on the housing by means of a rim with the possibility of rotation. 9. The lamp according to claim 1, characterized in that positional marks are applied along the edge of the secondary optical system. 10. The lamp according to claim 8, characterized in that an electronic unit and a stepper motor are installed in the housing, the output shaft of which with the gear is located on the rim of the secondary optical system. 11. The lamp according to claim 1, characterized in that the secondary optical system is installed with the possibility of control over a wireless communication channel or manually. 12. The lamp according to claim 1, characterized in that behind the secondary optical system in the direction of light from the LEDs is a protective screen made of optically transparent material. 13. The lamp according to claim 1, characterized in that the primary optical system is a single lens or lens system, the number of which corresponds to the number of LEDs. 14. The lamp according to claim 1, characterized in that the printed circuit board contains one sector of LEDs occupying half of its surface, while the secondary optical system contains two groups of lenses occupying half of its surface. 15. The lamp according to claim 1, characterized in that the printed circuit board contains two sectors of LEDs occupying two quarters of its surface and arranged alternately, while the secondary optical system contains four sectors, combined into two groups of lenses, each of which contains two opposite sectors.