KR20120056723A - Infrared rays floodlight - Google Patents

Abstract

PURPOSE: An infrared ray projector is provided to improve directivity of infrared rays emitted to outside by arranging a back mirror between an LED module and a lens and adjusting radiation angle and range of the infrared rays. CONSTITUTION: An accommodation space(111) is formed inside a case(110). An LED module(120) is arranged at the accommodation space and generates infrared rays. A back mirror(140) is arranged at the front side of the LED module and refracts the infrared rays emitted from the LED module. A lens(130) secondly refracts the infrared rays passing through the back mirror and emits the infrared rays. A radiating unit(150) emits heat transferred from the LED module.

Description

Infrared Emitter Using Reflector {INFRARED RAYS FLOODLIGHT}

The present invention relates to an infrared light emitter that works in conjunction with CCTV, a reflector disposed between the LED module and the lens to adjust the irradiation angle and the range emitted from the lens during the infrared irradiation in the LED module to improve the straightness It relates to an infrared light emitter using.

In general, an infrared emitter is installed together with a surveillance camera (CCTV) to serve to enable the surveillance camera to shoot in low light by irradiating infrared light from the infrared emitter at night without a light source.

As shown in FIG. 1, the infrared light emitter has a dual lens structure in which the primary lens 20 and the secondary lens 25 are sequentially disposed in front of the LED module 15 that generates infrared light. Accordingly, the infrared rays emitted from the LED module are refracted by linear light having a predetermined width through the primary lens, and then spread through the secondary lens at a predetermined angle.

However, such a conventional infrared light emitter scans the front after the infrared light generated by the LED module reduces the radiation angle through the primary lens and the secondary lens. Thus, the radiation angle of the infrared light passing through the two lenses sequentially is usually Because it is 20 degrees to 40 degrees, it is possible to survey the near area, but due to the wide radiation angle, it is impossible to investigate the far area due to the straightness.

Accordingly, in order to irradiate the remote area, at least five lenses may be sequentially disposed to improve the straightness by narrowing the radiation angle of the infrared rays projected to the outside. However, in the case of using a plurality of lenses as described above, production costs are inevitably increased due to the high price of the lenses themselves, and the internal structure is complicated during installation, making manufacturing difficult and the overall size of the lenses being large.

In addition, the radiation angle of the infrared rays generated by the LED module is typically 120 degrees, because a plurality of lenses sequentially arranged at a predetermined interval is limited in size, some of the infrared rays generated from the LED module are disposed in front The original light loss that does not reach the lens is generated (dotted line in Figure 1).

Moreover, the linearity of infrared rays is improved in the process of passing through several lenses in sequence, but about 8% light loss occurs every time the lens is hit and refracted. There was a problem that can not fall.

The present invention is to solve the above problems, by placing a reflector between the LED module and the lens as a light emitting source by adjusting the radiation angle of the infrared radiation emitted to the outside to improve the straightness infrared using a reflector that can be photographed in a remote area To provide a floodlight.

In addition, the present invention is to move the infrared light generated in the LED module penetrates through the inside of the reflector so that all the infrared light generated in the LED module is refracted toward the lens side infrared emitter using a reflector that can prevent the occurrence of the original light loss. To provide.

In addition, the present invention is simple by arranging a single reflector between the LED module and the lens as a light emitting source to improve the straightness of the infrared radiation emitted from the outside, the structure is simple and can reduce the production cost, compact size by reducing the overall size of the product To provide an infrared emitter using a reflector that can be customized.

The present invention to achieve the above object is a case having a receiving space therein; An infrared generator disposed in the accommodation space to generate infrared rays when power is applied; A reflector disposed in front of the infrared generating unit and configured to penetrate a moving path through which the infrared rays pass so as to primarily reduce the radiation angle of the infrared rays through refraction; And a lens disposed in front of the reflector to secondly deflect infrared rays passing through the reflector and to be emitted to the outside, wherein the moving passage has a curved surface whose cross-sectional area gradually increases along the traveling direction of the infrared rays. It provides an infrared light emitter using a reflector characterized in that it is provided.

Preferably, the curved surface may be formed as a parabola that is left and right symmetric with respect to the central axis.

Preferably, the infrared ray refracted once through the reflector may be disposed in front of the reflector so as to enter the lens.

According to the present invention as described above, by arranging a reflector between the LED module and the lens as a light emitting source to reduce the irradiation angle of the infrared rays emitted to the outside has the advantage that it is possible to shoot the remote area by improving the straightness.

In addition, the present invention has the effect that the infrared rays generated by the LED module is moved through the interior of the reflector, all the infrared rays generated by the LED module is refracted toward the lens to prevent the original loss.

In addition, the present invention is simple by arranging a single reflector between the LED module and the lens as a light emitting source to improve the straightness of the infrared radiation emitted from the outside, the structure is simple and can reduce the production cost, compact size by reducing the overall size of the product There is an effect that can be harmonized.

1 is a view schematically showing a radiation path of infrared rays emitted from a conventional infrared light emitter having a dual lens structure.
Figure 2 is an external perspective view showing an infrared light emitter according to the present invention.
3 is a cross-sectional view showing the internal configuration of FIG.
Figure 4 is a schematic view showing the radiation path of the infrared radiation emitted from the infrared light emitter according to the present invention.

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

In order to facilitate understanding of the present invention, the same reference numerals will be used to denote the same constituent elements even if they are shown in different drawings.

The infrared light emitter 100 according to the preferred embodiment of the present invention adjusts the radiation angle of the infrared rays emitted from the infrared generator by arranging a reflector 140 having a curved surface formed as a parabola between the infrared generator and the lens 130. By improving the straightness and increasing the radiation distance, CCTV has a technical feature to enable the shooting of remote areas.

The infrared light emitter 100 includes a case 110, an infrared ray generator, a reflector 140, and a lens 130.

The case 110 is provided with an accommodation space 111 therein to have a predetermined length, and the accommodation space 111 includes the infrared generator, the reflector 140, the lens 130, and the like. It will provide a space to be installed within.

The case 110 is open at both ends so that the components can be easily assembled in the accommodation space 111, and the open both ends are detachably coupled to the front cover 112 and the rear cover 114, respectively. Make it easy to replace.

In this case, the front cover 112 is formed through the center portion so that the infrared rays emitted from the lens 130 passes immediately to be emitted to the outside, the front of the lens 130 disposed on the foremost side of the receiving space 111. The lens 130 is prevented from being separated to the outside by contacting the side to support the lens 130.

In addition, the rear cover 114 is formed through the coupling hole 116 is inserted into the connector 180 to receive power from the outside in the central area.

At this time, the front cover 112 and the rear cover 114 which are respectively coupled to the front and rear of the case 110 is provided with a sealing member 118 to prevent moisture such as rainwater from penetrating into the inside. desirable.

The infrared generating unit emits infrared rays when the power is applied so that the CCTV can take an image even in the dark night, the LED module 120 or LED lamp (hereinafter, ' LED module 'collectively.) .

The rear side of the LED module 120 is provided with a heat dissipation unit 150 to absorb the heat generated during the operation of the LED module 120 to quickly cool. In addition, a PCB 160 electrically connected to the LED module 120 and a cable is disposed at the rear side of the heat dissipation part 150 to supply power supplied through the connector 180 to the LED module 120. To be delivered to the side.

Here, the heat dissipation unit 150 is made of a metal material having good thermal conductivity such as aluminum, so as to quickly discharge the heat transferred from the LED module 120.

The reflector 140 is disposed in front of the LED module 120 and serves to primarily reduce the radiation angle of the infrared rays by refracting the infrared rays emitted from the LED module 120. Such a reflector 140 is formed through the movement passage 142 in parallel with the traveling direction of the infrared light so that the infrared light emitted from the LED module 120 can pass through. The movement path 142 is formed through the central portion of the reflector 140 to have a curved surface that gradually increases the cross-sectional area. Here, the curved surface is preferably provided as a parabolic surface symmetrical left and right with respect to the central axis so as to reduce the radiation angle by refracting the introduced infrared rays.

As described above, since the moving passage 142 through which the infrared rays pass through is formed in the center portion of the reflecting mirror 140, all the infrared rays introduced into the moving passage 142 by being completely surrounded by the curved surface are moved. Passes straight through the passage 142 or hits the curved surface and is then refracted.

At this time, the LED module 120 is the end side of the reflector 140 through the holder 170 so that all the infrared rays generated by the LED module 120 can be moved to the moving passage 142 side in more detail. It is arranged to be inserted into the end side of the movement passage 142. As a result, all infrared rays emitted from the LED module 120 are emitted toward the movement path 142 formed in the reflector 140, and are disposed in front of the reflector 140 after being deflected by hitting the curved surface to reduce the radiation angle. The lens 130 is moved to the side.

The lens 130 is disposed in front of the reflector 140 to refract the infrared ray primarily refracted by the reflector 140 to reduce the radiation angle and then emit it to the outside. The lens 130 may be configured in various forms such as a spherical lens or an aspherical lens that is commonly used. As described above, the lens 130 is disposed at the front side of the reflector 140 and is supported by the front cover 112 and disposed in the accommodation space 111.

At this time, the lens 130 disposed on the front side of the reflector 140 is in a position where the infrared rays hit the parabolic surface 142a only once while passing through the moving passage 142 and then be refracted to directly enter the lens 130. It is preferable to arrange. That is, all the light including the infrared light is generated by the optical loss of approximately 8% each time the refraction occurs, in the present invention, the infrared ray introduced into the lens 130 hits the parabolic surface 142a a minimum number of times the lens 130 This is to minimize the light loss through refraction by allowing it to flow straight into.

When the infrared light emitter 100 of the present invention configured as described above is supplied with power through the connector 180 and the power is applied from the PCB 160 to the LED module 120 side, the infrared light is generated from the LED module 120. The infrared rays generated by the LED module 120 are emitted to the outside through the moving passage 142 and the lens 130 of the reflector 140 in sequence as shown in FIG. That is, all the infrared rays generated by the LED module 120 passes through the movement passage 142 to move toward the lens 130 disposed on the front side. At this time, some of the infrared rays emitted from the LED module 120 (dashed line in Figure 4) is moved directly to the lens 130 side, the infrared rays other than the infrared rays directly moved to the lens 130 side (in Figure 4 The solid line part is collided with the parabolic surface 142a of the reflector 140 after the emission and refracted, and then moves toward the lens 130. Due to this, the infrared rays are reduced to an radiation angle of about 8 to 10 degrees by the refraction occurring while passing through the lens 130 after the radiation angle is limited to about 30 degrees while passing through the movement path of the reflector 140. do.

Accordingly, since the infrared rays emitted to the outside are irradiated at a radiation angle of about 8 to 10 degrees, the linearity of the infrared rays is greatly improved, and the infrared rays can be irradiated to the distant region.

According to the present invention as described above, by placing a reflector between the LED module and the lens as a light emitting source to reduce the radiation angle of the infrared radiation emitted to the outside to improve the straightness there is an advantage that can be taken in the remote area.

In addition, the present invention has the effect that all the infrared rays generated from the LED module is refracted toward the lens by passing the infrared light generated by the LED module passes through the parabolic surface to prevent the original light loss.

In addition, the present invention is simple by arranging a single reflector between the LED module and the lens as a light emitting source to improve the straightness of the infrared radiation emitted from the outside, the structure is simple and can reduce the production cost, compact size by reducing the overall size of the product There is an effect that can be harmonized.

While the foregoing is directed in detail to a particular embodiment of the invention with reference to the drawings, it is not intended to limit the invention to this specific construction. Those skilled in the art will be able to easily modify or change without departing from the technical spirit described in the claims below. However, equivalents, replacements, and substitutes through such simple design modifications or modifications are all clearly stated in advance within the scope of the present invention.

100: infrared floodlight 110: case
111: accommodation space 112: front cover
114: rear cover 116: coupling hole
118: sealing member 120: LED module
130 lens 140 reflector
142: moving passage 142a: parabolic surface
150: heat dissipation unit 160: PCB
170: holder 180: connector

Claims (3)

A case having an accommodation space therein;
An infrared generator disposed in the accommodation space to generate infrared rays when power is applied;
A reflector disposed in front of the infrared generating unit and configured to penetrate a moving path through which the infrared rays pass so as to primarily reduce the radiation angle of the infrared rays through refraction; And
It includes; a lens disposed in front of the reflector for refracting the infrared rays passing through the reflector secondary and emits to the outside;
The moving path is an infrared light emitter using a reflector, characterized in that it has a curved surface gradually increasing the cross-sectional area along the traveling direction of the infrared. The method of claim 1,
The curved surface is an infrared light emitter using a reflector, characterized in that formed in a parabola symmetrical left, right with respect to the central axis. The method of claim 1,
And an infrared light emitter, which is once refracted through the reflector, is disposed in front of the reflector so as to flow into the lens unit.

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