KR100580735B1 - Tester of thermal image system - Google Patents

Abstract

The present invention relates to an inspection apparatus of a thermal imaging apparatus.

After passing the light source from the light source into the barrel and reflecting it from the reflector at a predetermined distance, the image receiving unit of the thermal imaging device receives the light source, so that the image receiving unit receives the light source from the target light source at an infinite distance. Therefore, the thermal imaging apparatus can be inspected even in a limited space.

Thermal Imaging Device, Infinite Focus Light Source, Parabolic Mirror

Description

Inspection device of thermal imaging device {TESTER OF THERMAL IMAGE SYSTEM}

1 is a cross-sectional view of an inspection apparatus of a thermal imaging apparatus according to an exemplary embodiment.

2 is a plan view of an inspection apparatus of a thermal imaging apparatus according to an exemplary embodiment.

<Description of Symbols for Main Parts of Drawings>

10: light source unit 30: blocking unit

50: reflector 51: parabolic mirror

53: holder 55: reflector stand

70: receiver 71: thermal imaging device

72: vertical adjustment unit 73: fixed jig

75: rotary table 77: receiver base

80: control unit

The present invention relates to an inspection apparatus of a thermal imaging apparatus. More particularly, the light source from the light source unit passes through the light source into the barrel and is reflected by a reflector spaced a predetermined distance, thereby allowing the image receiving unit of the thermal imaging apparatus to accept the light source. The present invention relates to an inspection apparatus of a thermal imaging apparatus that has an effect such that an image receiving unit receives a light source from a target light source separated from a distance.

In general, a thermal imaging apparatus includes a thermal image receiving unit, an image display unit, a thermal imager, and a power control unit. The infrared ray of an object to be observed having a wavelength band of 8 to 12 μm far away is detected, detected and processed, and the signal is sent to an image display unit. The infrared signal to be observed is amplified and scaled by a thermal electronic unit, a power control unit, or the like, which performs an auxiliary function in the thermal device, and displays an image on the display unit, thereby allowing the observer to recognize the abnormality.

Conventionally, in order to align the optical system of the thermal imaging device and to test its performance, the tank is mounted on the turret in order to check the alignment and operation state. There is a problem in that the supply and demand of parts can be disrupted by claiming a product that can be removed and maneuvered by simple adjustment.

An object of the present invention is to solve such a conventional problem, by passing the light source from the light source to the inside of the barrel and then reflected by a reflector away from the predetermined distance, the image receiving unit of the thermal imaging device to receive this light source at an infinite distance The present invention provides an inspection apparatus of a thermal imaging apparatus to have an effect similar to that of an image receiving unit receiving a light source from a remote target light source.

The structure of the apparatus of the present invention for achieving the above object comprises a light source unit for making and emitting a light source in the infrared wavelength band; A blocking unit for minimizing external interference when the light source emitted from the light source passes; A reflection unit which receives the light source emitted from the blocking unit and reflects the light source into an infinite focus light source; A receiver which receives the infinite focus light reflected from the reflector and passed through again and measures the distance; And a control unit for supplying power to the light source unit and the receiving unit and controlling the same, and displaying the measured distance.

The receiver may include a thermal imaging apparatus configured to measure a distance from the light source by measuring a distance of the received light source; A vertical adjustment unit coupled to the side of the thermal imaging apparatus to adjust an up-and-down angle of light source reception of the thermal imaging apparatus; A fixing jig fixed to the thermal imaging apparatus by being coupled to a lower portion of the thermal imaging apparatus; A rotary table coupled to a lower portion of the fixing jig to adjust a light source reception left and right angles of the thermal imaging apparatus fixed by the fixing jig; It characterized in that it comprises a receiving unit pedestal for fixing the rotary table.

The light source unit is installed on the receiving unit pedestal, characterized in that located in front of the thermal imaging device.

The reflector includes: a parabolic mirror recessed inwardly to convert the light source emitted from the light source into an infinite focus light source; A fixing stand which is fixed by being combined with the parable mirror; It is characterized in that it comprises a reflector pedestal is installed in the lower portion of the holder to support the holder.

The blocking unit is a cylindrical shape that blocks external light and has a predetermined length, wherein one end is coupled to the receiver pedestal and the other end is coupled to the reflector pedestal.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a cross-sectional view illustrating an inspection apparatus of a thermal imaging apparatus according to an exemplary embodiment of the present invention, and FIG. 2 is a plan view of an inspection apparatus of a thermal imaging apparatus according to an exemplary embodiment of the present invention.

As shown in Figure 1 and 2, the configuration of the optical system inspection apparatus of the thermal imaging apparatus according to an embodiment of the present invention, the light source unit 10 for generating and emitting a light source of the infrared wavelength band; A blocking unit 30 for minimizing external interference when the light source emitted from the light source unit 10 passes; A reflection unit 50 which receives the light source from the blocking unit 10 and changes the light source into an infinite focus light source; A receiver 70 which receives the infinite focus light reflected from the reflector 50 and passed through the mirror again and measures this distance; It is characterized in that it comprises a control unit 80 for supplying power to the light source unit 10 and the receiving unit 70 and controlling it and displaying the measured distance.

The receiver 70 includes: a thermal imaging apparatus 71 measuring a distance between the light source unit 10 by measuring a distance of the received light source; A vertical adjustment unit 72 coupled to the side of the thermal imaging device 71 to adjust an up-and-down angle of light source reception of the thermal imaging device 71; A fixing jig 73 which is coupled to a lower portion of the thermal imaging device 71 to fix the thermal imaging device 71; A rotary table 75 that is coupled to a lower portion of the fixing jig 73 and adjusts a light source reception left and right angles of the thermal imaging apparatus 71 fixed by the fixing jig 73; It characterized in that it comprises a receiver 77 for fixing the rotary table (75).

The light source unit 10 is installed on the receiver pedestal 77 and is positioned in front of the thermal imaging apparatus 71.

The reflector 50 includes: a parabolic mirror 51 having a concave shape that is recessed inwardly to change the light source emitted from the light source unit 10 into an infinite focus light source; A fixing table 53 which is fixed by being combined with the parabolic mirror 51; It is characterized in that it comprises a reflector pedestal 55 is installed in the lower portion of the holder 53 to support the holder 53.

The blocking unit 30 is a cylindrical shape having a predetermined length to block external light, and one end is coupled to the receiving unit pedestal 77 and the other end is coupled to the reflector pedestal 55. .
The controller 80 uses a conventional computer configuration.

The operation of the inspection apparatus of the thermal imaging apparatus according to the preferred embodiment of the present invention by the above configuration is as follows.

First, the thermal imaging apparatus 71 to be tested is fixed to the fixture jig 73 of the receiver 70 and aligned by adjusting the directions of the vertical adjusting unit 72 and the rotary table 75. Subsequently, when the controller 80 inputs power to the light source unit 10 and the receiver 70, the light source unit 10 emits an infrared light source toward the reflector 50. Subsequently, the light source emitted from the light source unit 10 enters into the barrel through which external light is blocked, and then enters the parabolic mirror 51 of the reflector 50 away from the light source unit 10 by a predetermined distance. At this time, since the light source emitted from the light source unit 10 is reflected by the parabolic mirror 51 as parallel light, the light source unit 10 is converted into an infinite focus light source and passes through the interior of the blocking unit 30 to block external noise and unnecessary light. 70 is received by the thermal imaging device 71. Subsequently, the thermal imaging apparatus 71 analyzes the incoming light source, measures the distance from the light source unit 10, passes the data to the controller 80, and the controller 80 displays this.

Therefore, the optical test apparatus of the thermal imaging apparatus parabolic mirrors the light source generated by the light source unit 10 located in front of the receiving unit 70 in place of the method to place the object at a real infinite distance in the optical system test of the conventional thermal imaging apparatus to recognize this By 51, the thermal imaging apparatus 71 can recognize an object located at an infinite distance so that the optical system inspection of the thermal imaging apparatus can be performed within a limited space.

As described above, the present invention passes the light source from the light source into the barrel and reflects it from the reflector at a predetermined distance, and then the image receiving unit of the thermal imaging apparatus receives the light source. By having the same effect as receiving, it is possible to perform the inspection of the thermal imaging apparatus within a limited space.

Claims (5)

A light source unit for making and emitting a light source having an infrared wavelength band; A blocking unit for minimizing external interference when the light source emitted from the light source passes; A reflection unit which receives the light source emitted from the blocking unit and reflects the light source into an infinite focus light source; A receiver which receives the infinite focus light reflected from the reflector and passed through again and measures the distance; And a control unit for supplying power to the light source unit and the receiving unit, controlling the same, and simultaneously displaying the measured distances. The method of claim 1, wherein the receiving unit A thermal imaging apparatus measuring a distance from the light source unit by measuring a distance of the received light source; A vertical adjustment unit coupled to the side of the thermal imaging apparatus to adjust an up-and-down angle of light source reception of the thermal imaging apparatus; A fixing jig fixed to the thermal imaging apparatus by being coupled to a lower portion of the thermal imaging apparatus; A rotary table coupled to a lower portion of the fixing jig to adjust a light source reception left and right angles of the thermal imaging apparatus fixed by the fixing jig; And a receiver pedestal for fixing the rotating table. The light source of claim 1 or 2, wherein the light source unit It is installed on the receiving unit pedestal and the inspection apparatus of the thermal imaging apparatus, characterized in that located in front of the thermal imaging apparatus. The method of claim 1, wherein the reflector A parabolic mirror concave inwardly for converting the light source emitted from the light source into an infinite focus light source; A fixing stand which is fixed by being combined with the parable mirror; And a reflector pedestal installed on the bottom of the holder to support the holder. The method of claim 1 or 2, wherein the blocking unit And a cylindrical shape having a predetermined length to block external light, one end of which is coupled to the receiver pedestal, and the other end of which is coupled to the reflector pedestal.

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