KR102466838B1 - Flood lighting device using multiple light sources - Google Patents

Abstract

According to the flood lighting device using a plurality of light sources of the present invention, a light source unit capable of irradiating a light source and including a plurality of laser diodes spaced apart from each other and a plurality of LEDs spaced apart from the laser diodes; a light concentrating unit provided in front of the light source unit and condensing the light emitted from the light source unit to a specific point; a fluorescent unit provided in front of the light collecting unit to convert a laser beam into white light; a reflector provided in front of the fluorescent part and reflecting the light source passing through the fluorescent part toward the front; a distance sensor provided in the light source unit to measure a distance between the light source unit and a light source target point located in front; and a control unit controlling the amount of light of the light source unit according to the distance between the light source targets measured through the distance sensor.
The effect of the present invention is that a plurality of LEDs and laser diodes are arranged so that short and long distances can be irradiated with one light source unit, and light transmission using multiple light sources can improve stability by detecting obstacles through an infrared sensor. A lighting device can be provided.

Description

Flood lighting device using multiple light sources}

The present invention relates to a flood lighting device using a plurality of light sources.

Although many new types of light sources have been developed in the past, traditional light bulbs are still widely used because of their low cost and pleasant emission spectrum.

As a light source for achieving energy-efficient lighting, a semiconductor light emitting device, preferably a module such as a light-emitting diode (LED) is used.

An LED light emitting device using such an LED is compact, has high power efficiency, and emits vivid color light emission. In addition, since the LED is a semiconductor device, there is no fear of short circuiting the light bulb. In addition, it has excellent initial drive characteristics and is strong against vibration and repetition of on/off lighting. Because of these outstanding characteristics, LED light emitting devices are used as various light sources.

Recently, demand for lighting devices using lasers, which are more directional than LEDs and are easy to use by condensing excited light, is increasing, and lighting devices using lasers enable higher luminance and output than LEDs.

However, in the prior art, there was an inconvenience in that each light emitting device made of a laser and an LED had to be used according to a long distance and a short distance. In addition, the output of the light source cannot be controlled according to the distance, and since the same output is achieved, there is a problem in that power consumption is high.

Korea Patent Publication No. 10-2004-0063140 Korea Patent Publication No. 10-2010-005363 Japanese Patent Publication JP2012-169050 Korea Patent Registration 10-1229143

An object of the present invention, conceived to solve the above-mentioned problems, is that a plurality of LEDs and laser diodes are disposed, so that short and long distances can be irradiated with one light source unit, respectively, and obstacle detection through an infrared sensor. It is to provide a flood lighting device using a plurality of light sources capable of improving stability.

According to the floodlighting device using a plurality of light sources of the present invention for achieving the above object, a plurality of laser diodes capable of irradiating light sources and arranged spaced apart from each other and a plurality of LEDs spaced apart from the laser diodes are provided. A light source unit comprising; a light concentrating unit provided in front of the light source unit and condensing the light emitted from the light source unit to a specific point; a fluorescent unit provided in front of the light collecting unit to convert a laser beam into white light; a reflector provided in front of the fluorescent part and reflecting the light source passing through the fluorescent part toward the front; a distance sensor provided in the light source unit to measure a distance between the light source unit and a light source target point located in front; and a control unit controlling the amount of light of the light source unit according to the distance between the light source targets measured by the distance sensor.

In addition, the light source unit further includes a board on which the laser diodes and the LEDs are disposed, the laser diodes and the LEDs are spaced apart at regular intervals and arranged in a grid pattern, and the laser diodes are spaced apart from each other at a first interval to Arranged surrounding the center point of the board, the LEDs are spaced apart from each other at a second interval shorter than the first interval, and are disposed throughout the board, enclosing the laser diodes, and adjacent to each other than the number of laser diodes disposed outside the laser diodes. It is characterized in that it is arranged so that the number of arranged between them is larger.

In addition, if the distance measured by the distance sensor corresponds to a preset set distance, the control unit controls the LEDs to be turned on by a set number, and the number of LEDs turned on as the set distance increases. It is characterized by an increase in

In addition, the control unit may control the LED and the laser diode to be simultaneously turned on when the set distance corresponds to a preset maximum distance, and control only the laser diode to be turned on when the set distance is shorter than the maximum distance.

In addition, the distance sensor is made of an infrared sensor, and the control unit turns off the turned-on laser diode and turns on only the LED as a whole when a heat corresponding to a body temperature is sensed when the distance is measured by the infrared sensor. characterized by control.

In addition, it is provided in front of the light source unit, the cover portion for transmitting only one of the light source of the laser diode or LED; and a moving unit coupled to the cover unit and moving outwardly so as not to be located in front of the light source unit, wherein the control unit controls the moving unit according to a distance of a specific target point on which the light source is to be illuminated. It is characterized in that the position of the cover portion is adjusted.

In addition, the cover unit includes a first cover that transmits only the laser diode light source and a second cover that transmits only the LED light source, and the control unit, when the specific target point is greater than a predetermined target distance, the first cover It is located in front of the light source unit, and characterized in that the second cover is located in front of the light source unit below.

In addition, the second cover is made up of a plurality, but the number of light sources of LEDs transmitted through each cover is different, and the control unit, when the specific target point is less than a preset target distance, the number of light sources preset according to the distance It is characterized in that any one of the second covers capable of transmitting the corresponding light source is positioned in front of the light source unit.

In addition, the control unit controls a plurality of LEDs by dividing them into a central portion, a middle portion, and an outer portion based on the center of the board, and if the set distance corresponds to a first distance, only the central portion of the LED is turned on, and the first If it corresponds to the second distance farther than the first distance, only the central and outer LEDs are turned on, and if it corresponds to the third distance farther than the second distance, only the central and middle LEDs are turned on, and at the fourth distance farther than the third distance If applicable, it is characterized in that LEDs of the center, middle, and outer portions are turned on as a whole.

In addition, it is provided in front of the light source unit, a temperature measuring sensor for measuring the temperature; a power supply unit supplying power to the light source unit; and a determination unit determining whether the light source unit is abnormal using temperature information measured by the temperature measurement sensor, wherein the determination unit determines whether an output temperature value output from the temperature measurement sensor corresponds to a set temperature value. A temperature judgment module that determines that an output temperature value is greater than a set temperature value, and an overheat judgment module that determines that overheating has occurred in the light source unit and generates a failure signal and reduces power supplied by the power supply unit when the temperature judgment module determines that the output temperature value is greater than the set temperature value; When the temperature judgment module determines that the output temperature value is less than the set temperature value, the light source unit determines that the light source is not operating normally, generates a failure signal, and includes a non-operational judgment module for increasing power supplied by the power supply unit, The unit is turned on when supplying increased power to the manager terminal when the temperature judgment module determines that the output temperature value is smaller than the set temperature value even though the power supply unit has supplied increased power for a certain period of time by the non-operation judgment module. It is characterized in that the type information of the light source is transmitted.

Also, a photographing unit configured to photograph the light source target by automatically adjusting the focus according to the distance between the light source targets measured through the distance sensor; a storage unit for storing an image captured by the photographing unit; and an image output unit for displaying so that a manager can check the image captured by the capturing unit.

As described above, the effect of the present invention is that a plurality of LEDs and laser diodes are disposed, so that short and long distances can be irradiated with one light source unit, respectively, and a plurality of light sources that can improve stability by detecting obstacles through an infrared sensor A flood lighting device using a light source may be provided.

1 and 2 are configuration diagrams showing a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.
3 is a block diagram showing a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.
4 is a front view showing a light source unit of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.
5 is an exemplary diagram illustrating a light source unit according to a distance to a light source target of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.
6 is a front view showing a cover of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, the present invention will be described with reference to drawings for explaining a flood lighting device using a plurality of light sources according to embodiments of the present invention.

Meanwhile, according to the embodiments of the present invention, a flood lighting device using a plurality of light sources may be used for a light projection device for aviation or ship.

1 and 2 are configuration diagrams showing a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention. 3 is a block diagram showing a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention. 4 is a front view showing a light source unit of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention. 5 is an exemplary diagram illustrating a light source unit according to a distance of a light source target of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention. 6 is a front view showing a cover of a flood lighting device using a plurality of light sources according to a preferred embodiment of the present invention.

1 to 4, a floodlighting device using a plurality of light sources according to the present invention includes a light source unit 10, a light collecting unit 20, a reflecting unit 40, a distance sensor 50, and a control unit 60. include

First, the light source unit 10 includes a board 11 and a laser diode 12 and an LED 13 provided on the board 11 to irradiate a light source.

The board 11 is formed as a circular or rectangular plate, and a laser diode 12 and an LED 13 are arranged and provided.

A plurality of laser diodes 12 are disposed on the board 11 . At this time, the laser diodes 12 are disposed at each vertex of the square and have the same distance apart from each other.

In addition, the laser diode 12 is a light source capable of illuminating a long distance and generates blue light around a wavelength of 475 nm. The blue light is focused on a light collecting unit 20 to be described later, passes through a fluorescent unit 30 to be described later, and is irradiated to a light source target as light close to white light.

The LED 13 is spaced apart from the laser diode 12 and is formed in multiple numbers.

At this time, the laser diode 12 and the LED 13 are spaced apart at regular intervals and arranged in a horizontal and vertical grid pattern.

Four laser diodes 12 are spaced apart from each other at a first interval and surround the center point of the board 11, and four laser diodes 12 are disposed, and the arranged laser diodes 12 form a square shape based on the center point of the board 11.

In addition, the LEDs 13 are spaced apart at a second interval shorter than the first interval and disposed throughout the board 11, while surrounding the laser diode 12. In addition, the number of LEDs 13 disposed between adjacent laser diodes 12 is greater than the number disposed outside the laser diodes 12 .

That is, the number of LEDs 13 is greater than that of the laser diodes 12 . Since the LED 13 can irradiate a shorter distance than the laser diode 12, a larger number is required.

The light concentrating unit 20 is provided in front of the light source unit and condenses the light emitted from the light source unit 10 to a specific point.

The fluorescent unit 30 is provided in front of the light collecting unit 20 and converts the laser beam into white light. At this time, the fluorescent part 30 is made of translucent ceramic or transparent ceramic.

Here, a condenser lens may be further provided in front of the fluorescent unit 30 .

The reflector 40 is provided in front of the fluorescent part 30 and reflects the light source transmitted through the fluorescent part 30 toward the front.

The distance sensor 50 is provided in the light source unit 10 and measures the distance between the light source unit 10 and a point of the light source target 14 located in front.

The control unit 60 controls the amount of light of the light source unit 10 according to the distance between the light source targets 14 measured through the distance sensor 50 .

In addition, if the distance measured by the distance sensor 50 corresponds to the preset distance, the control unit 60 may control the LEDs 13 to be turned on as many as the preset number.

Then, the controller 60 increases the number of LEDs 13 turned on as the set distance increases. That is, this is to increase the amount of light as the distance from the light source target increases.

In addition, the controller 60 controls the LED 13 and the laser diode 12 to be simultaneously turned on when the set distance corresponds to the preset maximum distance, and controls only the laser diode 12 to be turned on when the set distance is shorter than the maximum distance. .

For example, if the distance of the light source target is 600 m, the LED 13 and the laser diode 12 may be simultaneously turned on, and if the distance is less than 600 m, only the laser diode 12 may be turned on.

The blue laser diode can irradiate a light source about 600m, so if there is a light source target 14 at a distance greater than 600m, it is preferable to turn on the LED 13 and the laser diode 12 at the same time. It is preferable to turn on only (12), but it is not limited thereto.

On the other hand, in order to more efficiently control the plurality of LEDs 13, the control unit 60 divides the plurality of LEDs 13 into a central part, a middle part, and an outer part based on the center of the board 11 and controls them. can

At this time, if the set distance corresponds to the first distance, only the central LED 13 may be turned on. Here, the LEDs 13 in the central part are not turned on continuously with the adjacent LEDs 13, but the LEDs 13 arranged skipping each other are turned on. In addition, when the set distance corresponds to a second distance greater than the first distance, only the central and outer LEDs 13 may be turned on. At this time, the LED 13 of the central portion may be continuously turned on.

In addition, if the set distance corresponds to a third distance longer than the second distance, only the central and intermediate LEDs 13 are turned on. At this time, all of the LEDs 13 in the central part may be turned on, and the LEDs 13 in the middle part may be skipped and turned on without being continuous with the adjacent LEDs 13.

Here, reference may be made to FIG. 5, and a gray circle in FIG. 5 indicates that the LED 13 is on, and a blue circle indicates that the LED 13 is off. In addition, a red rectangle indicates a state in which the laser diode 12 is off, and a green rectangle indicates a state in which the laser diode 12 is turned on.

In addition, when the set distance corresponds to the fourth distance, which is longer than the third distance, the LEDs 13 of the center, middle, and outer portions may be turned on as a whole.

In this way, at the set distances 1 to 4 shorter than the irradiation distance of the laser diode 12, the light source is irradiated using only the LED 13, but the LED 13 turned on for each distance is changed to emit light. can be adjusted, and power supply can be saved.

On the other hand, the distance sensor 50 is made of an infrared sensor.

At this time, when measuring the distance with the infrared sensor, the control unit 60 turns off the on laser diode 12 and controls only the LED 13 to be turned on as a whole when a heat corresponding to the range of the body temperature is sensed.

That is, if the set distance corresponds to the preset maximum distance, the LED 13 and the laser diode 12 are turned on at the same time, and when the heat corresponding to the body temperature is sensed, the laser diode 12 is turned off, and the laser diode 12 is turned off, In a short state where only the laser diode 12 is turned on, the laser diode 12 is turned off and all the LEDs 13 are turned on.

This is to prevent obstruction of the field of view and to protect the eyesight and field of view of the irradiated person, since the light intensity of the laser diode 12 is strong.

Meanwhile, referring to FIG. 5 , the flood lighting device using a plurality of light sources according to the present invention further includes a cover part 70 and a moving part 80.

The cover unit 70 is provided in front of the light source unit 10 and transmits only one light source of the laser diode 12 or the LED 13 .

That is, the cover part 70 includes a first cover 71 that transmits only the light source of the laser diode 12 and a second cover 72 that transmits only the light source of the LED 13 .

At this time, the second cover 72 is made of a plurality of pieces, and the number of light sources of the LEDs 13 passing through each cover is different. For example, the second cover 72 may be formed of covers respectively corresponding to the first to fourth distances.

Here, the cover unit 70 may be provided with a lens corresponding to a light source to transmit. Accordingly, the light source of the laser diode 12 or some or all of the LEDs 13 may be transmitted through the lens.

The moving unit 80 is coupled to the cover unit 70 and can be moved outward so as not to be located in front of the light source unit.

At this time, the moving unit 80 includes a plurality of grippers holding the cover unit 70, an extension part extending from each gripper part, a rotation shaft provided at the end of the extension unit, and a rotation shaft in which the extension unit is rotatably provided. It may include a motor that is provided in and can rotate each extension based on the rotation axis.

That is, the control unit 60 may adjust the position of the cover unit 70 by controlling the moving unit 80 according to the distance of a specific target point on which the light source is to shine.

In other words, the controller 60 positions the first cover 71 in front of the light source unit 10 when the specific target point is greater than or equal to the preset target distance, and places the second cover 72 in front of the light source unit 10 when it is less than or equal to the target distance. place it in the front

In addition, when the target distance is the maximum distance, the cover unit 70 may not be positioned in front of the light source unit 10 in a state in which both the laser diode 12 and the LED 13 are turned on.

In addition, the control unit 60, when the specific target point is less than the preset target distance, the second cover 72 of any one of the light source unit 10, which can transmit the light source corresponding to the preset number of light sources according to the distance. place it in the front

Accordingly, even if the manager changes the specific target point to illuminate the light source, the cover unit 70 is positioned according to the distance of the specific target point by the moving unit 80 under the control of the control unit 60 without a separate manipulation, A specific target point can be quickly irradiated with a light quantity suitable for the distance of the specific target point, and at the same time, the visibility is appropriately adjusted so that the administrator can easily check the specific target point with the naked eye and minimize the administrator's eye fatigue.

In addition, if the specific target point corresponds to the first distance, the control unit 60 turns on the LED 13 that is turned on when the second distance, that is, the LED 13 of the outer part in advance, so that the specific target point is the second distance. When changed to , the second cover 72 corresponding to the second distance can be placed in front so that the amount of light suitable for the second distance can be rapidly irradiated. That is, when turning on the LED 13, the control unit 60 may preliminarily turn on the LED 13 capable of irradiating a farther distance than a specific target point.

Meanwhile, the floodlighting device using a plurality of light sources according to the present invention further includes a temperature measurement sensor, a power supply unit, and a determination unit.

A temperature measuring sensor is provided in front of the light source unit 10 to measure the temperature.

The power supply unit supplies power to the light source unit 10 .

The determination unit determines whether the light source unit 10 is abnormal using the temperature information measured by the temperature measurement sensor.

At this time, the determination unit includes a temperature determination module that determines whether the output temperature value output from the temperature sensor corresponds to the set temperature value, and when the temperature determination module determines that the output temperature value is greater than the set temperature value, the light source unit 10 is overheated. An overheating judgment module that determines that it has occurred and generates a failure signal and reduces the power supplied by the power supply unit, and when the temperature judgment module determines that the output temperature value is smaller than the set temperature value, it is determined that the light source unit 10 does not operate normally and an inoperative determination module generating a failure signal and increasing the power supplied by the power supply unit.

In addition, the power supply unit is turned on when the temperature judgment module determines that the output temperature value is smaller than the set temperature value even though the power supply unit has supplied increased power for a certain period of time by the non-operation judgment module, when supplying the increased power to the manager terminal. The type information of the light source is transmitted.

This is to facilitate maintenance by quickly and accurately diagnosing normal operation of the laser diode 12 and the LED 13 emitting different light sources by analyzing the temperature change inside the light source unit 10 .

In addition, the floodlighting device using a plurality of light sources according to the present invention further includes a photographing unit, a storage unit, and an image output unit.

The photographing unit automatically adjusts the focus according to the distance between the light source targets 14 measured through the distance sensor 50 to photograph the light source target 14 .

The storage unit stores an image captured by the photographing unit. At this time, the stored image can be used as analysis data later.

The image output unit displays the image so that the administrator can check the image captured by the photographing unit. At this time, if the video output unit is made of a touch screen, it is possible to enlarge or reduce the image according to a touch operation, so that the administrator can magnify and check the image displayed on the video output unit when it is difficult to check with the naked eye.

Those skilled in the art to which the present invention pertains will understand that the present invention can be embodied in other specific forms without changing its technical spirit or essential features. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. The scope of the present invention is indicated by the claims to be described later rather than the detailed description above, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof are included in the scope of the present invention. should be interpreted In addition, the operation sequence of the components described in the above-described process does not necessarily have to be performed in a time-series order, and even if the execution sequence of each component and step is changed, if the gist of the present invention is satisfied, these processes will fall within the scope of the present invention. Of course you can.

10: light source unit 11: board
12: laser diode 13: LED
14: light source target 20: light collecting part
30: fluorescent part 40: reflecting part
50: distance sensor 60: control unit
70: cover part 71: first cover
72: second cover 80: moving part

Claims (9)

A light source unit capable of irradiating a light source and including a plurality of laser diodes spaced apart from each other and a plurality of LEDs spaced apart from the laser diodes;
a light concentrating unit provided in front of the light source unit and condensing the light emitted from the light source unit to a specific point;
a fluorescent unit provided in front of the light collecting unit to convert the laser beam into white light;
a reflector provided in front of the fluorescent part and reflecting the light source passing through the fluorescent part toward the front;
a distance sensor provided in the light source unit to measure a distance between the light source unit and a light source target point located in front;
a control unit controlling the amount of light of the light source unit according to the distance between the light source targets measured by the distance sensor;
a cover unit provided in front of the light source unit and transmitting only one light source of the laser diode or the LED; and
A moving part coupled to the cover part and moving outwardly so as not to be located in front of the light source part; includes,
The floodlighting device using a plurality of light sources, characterized in that the control unit adjusts the position of the cover unit by controlling the moving unit according to the distance of a specific target point on which the light source is to be illuminated.
According to claim 1,
The light source unit further includes a board on which the laser diode and the LED are disposed,
The laser diode and the LED are spaced apart at regular intervals and arranged in a grid pattern,
The laser diodes are spaced apart from each other at a first interval and are disposed surrounding the center point of the board,
The LEDs are spaced apart at a second interval shorter than the first interval and disposed throughout the board, surrounding the laser diodes, and the number of the LEDs disposed between adjacent laser diodes is greater than the number disposed outside the laser diodes. A floodlighting device using a plurality of light sources, characterized in that arranged as shown in FIG.
According to claim 2,
The control unit, when the distance measured by the distance sensor corresponds to a preset set distance, controls the LEDs to be turned on by a preset number,
The floodlighting device using a plurality of light sources, characterized in that the number of LEDs turned on increases as the set distance increases.
According to claim 3,
The control unit controls the LED and the laser diode to turn on at the same time if the set distance corresponds to a preset maximum distance, and controls to turn on only the laser diode if the distance is shorter than the maximum distance. lighting device.
According to claim 4,
The distance sensor is made of an infrared sensor,
The control unit turns off the turned on laser diode and controls only the LEDs to be turned on as a whole when a heat corresponding to a range of body temperature is detected when measuring a distance with the infrared sensor. .
delete According to claim 1,
The cover part includes a first cover that transmits only the laser diode light source and a second cover that transmits only the LED light source,
The floodlighting device using a plurality of light sources, characterized in that the control unit positions the first cover in front of the light source unit when the specific target point is equal to or greater than the set target distance, and positions the second cover in front of the light source unit when it is less than or equal to the target distance.
According to claim 7,
The second cover is made of a plurality, but the number of light sources of LEDs that transmit each cover is different,
Wherein the control unit, when the specific target point is less than or equal to a preset target distance, positions a second cover capable of transmitting a light source corresponding to a preset number of light sources according to the distance in front of the light source unit. Characterized in that A flood lighting device using multiple light sources.
According to claim 3,
The control unit divides and controls the plurality of LEDs into a central portion, a middle portion, and an outer portion based on the center of the board,
If the set distance corresponds to the first distance, only the central LED is turned on, and if the set distance corresponds to a second distance greater than the first distance, only the central and outer LEDs are turned on, and corresponds to a third distance greater than the second distance. A floodlighting device using a plurality of light sources, characterized in that only the LEDs of the central and middle portions of the lower surface are turned on, and LEDs of the central, middle, and outer portions are turned on as a whole when the fourth distance is farther than the third distance.

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