KR100920724B1 - Infrared rays floodlight - Google Patents

Abstract

The present invention is an infrared light emitter used in conjunction with a camera (CCTV) to facilitate the monitoring of low light areas, by limiting the irradiation angle and the range emitted from each lens during infrared irradiation, the interference of light or overlapping An infrared light emitter for optimizing the quality of an image obtained by excluding an image, which is formed in combination with a main body having a rectangular shape, and includes a first lens having a plurality of aspherical lenses arranged in a rectangular shape so that a spherical portion faces forward. Mounting part; And a second lens mounting portion to which an infrared lamp is installed so as to correspond to the aspherical lens of the first lens mounting portion, respectively, and a lens portion having a built-in spherical lens is mounted in the uppermost row and the lowest horizontal row of the infrared lamp. The top and bottom horizontal rows of the lens mounting section are dual lens mounting sections in which the aspherical lens and the spherical lens of the lens section are installed together, and the middle row of the first lens mounting section is divided into the aspherical lens mounting section in which only the aspherical lens is installed alone. It is composed.

Infrared, Floodlight, Lamp, Camera, Surveillance

Description

Infrared Emitters {INFRARED RAYS FLOODLIGHT}

The present invention relates to an infrared light emitter used in conjunction with a camera (CCTV) to facilitate the monitoring of low light areas, and more particularly, by limiting the irradiation angle and range emitted from each lens during infrared irradiation The present invention relates to an infrared light emitter which excludes interference or overlap of light so that the quality of an acquired image is excellent.

As is well known, an infrared light emitter is usually installed together with a surveillance camera (CCTV) and interlocks with each other. The infrared light is irradiated at night (no light) without a light source to cause a low light camera (CCTV) to display an image. It is a kind of lighting that can be obtained.

In addition, the infrared emitter captures moving objects through the temperature sensor to irradiate infrared rays, and has a function of automatically switching to black and white or color mode at night by adopting a CDS sensor.

1, a conventional infrared floodlight 10 is shown.

As shown, the conventional infrared light emitter 10 includes a main body 11 and a front portion 12 formed on the front surface of the main body 11 and having a plurality of lenses 13.

The lenses 13 formed on the front part 12 are arranged in a circular shape, and the lenses 13 have a dual lens structure, and the internal structure thereof is aspherical lens 13a and aspherical lens 13b as shown in FIG. 2. Is installed to maintain a certain interval.

In addition, an infrared lamp 14 is positioned at one side of the lens 13, and the infrared light emitted from the infrared lamp 14 passes through a spherical lens 13a inside the lens 13 as shown in FIG. 2. After being refracted by the linear light of, it is irradiated (light: 15) so as to spread out at an angle through the aspherical lens 13b again.

The light emitted from the infrared lamp 14 and the irradiation of light through the lens 13 are irradiated through a plurality of lenses 13 in a circular shape, as shown in FIG. 3, and the infrared rays 15 are light spread out from each other. The overlapping portions 16 and 17 are formed.

In the overlapping portion of the formed light, as shown in FIG. 4, when the image of the subject is acquired, the portion 15 and the overlapping portions 16 and 17 that do not overlap the light appear as donuts. Due to the overlap of the illuminance, the image quality is deteriorated such that unnecessary lines in the donut shape are expressed in the acquired image.

The present invention has been made to solve the above problems, an object of the present invention is to operate in conjunction with a camera (CCTV) in the infrared light emitter used to facilitate the monitoring of low illumination area, each of the infrared irradiation It is to provide an infrared light emitter which limits the irradiation angle and the range emitted from the lens to exclude the interference or superposition of light so that the quality of the obtained image is excellent.

The present invention for achieving the above object is coupled to the main body of the rectangular shape, the first lens mounting portion is mounted with a plurality of aspherical lenses are arranged so that the spherical portion to the front toward the rectangle; And a second lens mounting portion to which an infrared lamp is installed so as to correspond to the aspherical lens of the first lens mounting portion, respectively, and a lens portion having a built-in spherical lens is mounted in the uppermost row and the lowest horizontal row of the infrared lamp. The top and bottom horizontal rows of the lens mounting section are dual lens mounting sections in which the aspherical lens and the spherical lens of the lens section are installed together, and the middle row of the first lens mounting section is divided into the aspherical lens mounting section in which only the aspherical lens is installed alone. It has one feature.

In addition, the present invention is characterized in that the aspherical lens formed on the first lens mounting portion is composed of three horizontally, 12 vertically four lines.

In another aspect, the present invention is characterized in that the lens unit is mounted in total, three in the uppermost horizontal row of the second lens mounting portion, three in the lowest horizontal row.

In addition, the present invention is characterized in that the front plate formed with a flexible glass (Flexy glass) is further formed on the front surface of the first lens mounting portion.

As described above, the present invention provides a technical effect that the quality of the obtained image is excellent by limiting the irradiation angle and range emitted from each lens during infrared irradiation to exclude interference or overlap of light.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

5 is an external configuration diagram of an infrared light emitter according to the present invention, Figure 6 is an exploded perspective view of the infrared light emitter according to the present invention.

As shown, the infrared light emitter 100 of the present invention has a large rectangular body 110, a front plate 120, a first lens mounting unit 130, a second lens mounting unit 140, and a heat sink ( 150 and PCB 160.

Looking more closely at this,

The front plate 120 is installed on the front of the main body 100, and forms a flexible glass 121 in a quadrangular shape to block the exposure of light (red) to the outside during infrared irradiation.

The first lens mounting portion 130 has a quadrangular aspherical lens 131 is mounted, the aspherical lens 131 is disposed so that the spherical portion is directed to the front, as shown in FIG.

In addition, the aspherical lenses 131 formed on the first lens mounting unit 130 may be configured in a total of 12 by forming three horizontally and four vertically.

An infrared lamp 141 is installed on the second lens mounting part 140 to correspond to the aspherical lens 131 of the first lens mounting part 130, and the top and bottom horizontal rows of the infrared lamp 141 are installed in the second lens mounting part 140. The lens units 142 are mounted, respectively.

The lens unit 142 has a spherical lens 143 mounted therein, as shown in a side cross-sectional view of the lens unit illustrated in FIG. 8.

The spherical lens 143 may be configured in various forms.

The six lens units 142 having the spherical lenses 143 are mounted in the uppermost row of the second lens mounting unit 140 and three in the lowest row of rows.

In addition, the rear surface of the second lens mounting portion 140 is a heat dissipation plate 150, a cooling fan, a PCB 160, which is installed with the electronic device is not shown, the front plate 120 and the first lens mounting portion 130 ) And the second lens mounting portion 140 are coupled to each other to correspond to each other, and the main body 110 is mounted thereto.

As shown in FIG. 9, the infrared light emitter 100 configured as described above is based on the first lens mounting unit 130, and the top and bottom horizontal columns are formed by the aspherical lens 131 and the lens unit 142. The dual lens mounting sections S1 and S3 in which the spherical lens 143 is installed together, and the middle (2 rows and 3 rows) rows of the first lens mounting unit 130 are provided with only the aspherical lens 131 alone. It is divided into aspherical lens mounting section S2.

First, looking at the infrared light irradiated by the dual lens mounting section (S1) (S3), as shown in FIG. 10, the infrared light emitted from the infrared lamp 141 of the second lens mounting unit 140 is inside the lens unit 142. After the light is refracted by the linear light having a predetermined width through the spherical lens 143, it is irradiated to spread through the aspherical lens 131 of the first lens mounting unit 130 at a predetermined angle (45130).

In addition, looking at the infrared rays irradiated by the aspherical lens mounting section (S2), as shown in FIG. 10, the infrared rays irradiated from the infrared lamp 141 of the second lens mounting portion 140 is an aspheric lens of the first lens mounting portion 130 ( 131 is irradiated to spread a certain angle (25 ().

The present invention utilizes the same principle as above, and is irradiated from an infrared ray of 45 degrees from the dual lens mounting sections S1 and S3 positioned above and below, and from an aspherical lens mounting section S2 located therebetween. As the infrared rays of 25 ° angle are irradiated at the same time, the area where the subjects are interfered with each other is minimized, and the area where the subject is reflected is evened. Provide effect.

According to the present invention, the irradiation distance and range of the infrared light irradiated through the infrared light emitter 100 has a 45 ° angle of irradiation range from 200 meters to 200m, as shown in FIG. 11, from 200m to 300m After that, it will have a range of 25 degrees.

1 is an external view of a conventional infrared floodlight,

2 and 3 is a view showing the infrared irradiation range of the conventional infrared floodlight,

4 is a view showing an image obtained by irradiating a conventional infrared light emitter,

5 is an external configuration diagram of an infrared floodlight according to the present invention,

6 is an exploded perspective view of an infrared floodlight according to the present invention;

7 is a cross-sectional side view of an essential part of a first lens mounting unit according to the present invention;

 8 is a side sectional view of a lens unit according to the present invention;

9 shows a mounting section of a lens according to the invention,

10 is a view showing the infrared irradiation range of the infrared floodlight according to the present invention,

11 is a view showing the infrared irradiation distance and range of the infrared floodlight according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: infrared light emitter 110: main body

120: front panel 121: plexiglass

130: first lens mounting portion 131: aspherical lens

140: second lens mounting portion 141: infrared lamp

142: lens 143: spherical lens

150: heat sink 160: PCB

Claims (4)

In combination with the body of the square shape, A first lens mounting portion to which a plurality of aspherical lenses are disposed so that the spherical portion faces forward in a quadrangular shape; And An infrared lamp is installed to correspond to the aspherical lens of the first lens mounting part, and the second lens mounting part includes a lens part in which a spherical lens is built in the uppermost row and the lowest horizontal row of the infrared lamp. The top and bottom horizontal rows of the first lens mounting portion are dual lens mounting sections in which an aspherical lens and a spherical lens of the lens portion are installed together, and the middle row of the first lens mounting portion is an aspheric lens mounting section in which only the aspherical lens is installed alone. An infrared light emitter, characterized in that the distinction. The method of claim 1, And an aspherical lens formed on the first lens mounting portion comprising three horizontally and twelve four vertically. The method of claim 1, And six lens units in total, three in the uppermost horizontal row of the second lens mounting unit and three in the lowest horizontal row. The method of claim 1, And a front plate formed with flexi glass on the front surface of the first lens mounting portion.

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