KR101799267B1 - Remote monitoring apparatus for testing the accuracy of gas concentration and speed detection - Google Patents

Abstract

The present invention relates to a remote monitoring apparatus for testing accuracy and speed of gas concentration detection of a gas detector. The remote monitoring apparatus of the present invention comprises: a test gas container for storing test gas; a gas detector for detecting the gas leaking from the test gas container and displaying a concentration value of the detected gas; an image acquirer for photographing the concentration value of the detected gas displayed via a display unit by the gas detector to acquire an image of the concentration value of the detected gas; and a tester terminal for receiving the image of the concentration value of the detected gas from the image acquirer, applying an image recognition algorithm to the received image of the concentration value of the detected gas to extract the concentration value of the detected gas, and processing the extracted concentration value of the detected value to generate information on the concentration of the detected gas, thereby providing a tester with the generated information on the concentration of the detected gas. According to the present invention, convenience for a tester who carries out a test on performance of a gas detector and reliability of performance evaluation can be enhanced.

Description

TECHNICAL FIELD [0001] The present invention relates to a remote monitoring apparatus for gas concentration detection accuracy and detection speed of a gas detector,

The present invention relates to a remote monitoring apparatus for gas concentration detection accuracy and detection speed testing of gas detectors. More particularly, the present invention relates to a remote monitoring apparatus capable of effectively performing a performance test on the gas concentration detection accuracy and the detection speed of the flammable and toxic gas detectors.

According to the prior art, as a means for the gas concentration detection accuracy and the detection speed test of the gas detector, the information that the tester visually displays on the visibility detector is set to detect the standard gas, After recording continuously changing measurement values with a camera or the like, a recorded image is reproduced again for in-depth analysis, and the numerical value is visually confirmed and recorded.

However, according to this method, there is a problem that the reliability of the tester performing the performance test of the gas detector is low and the reliability of the performance evaluation is low.

Korean Patent Laid-Open Publication No. 2001-0044597 (Published on June 5, 2001, entitled: Test Apparatus for Gas Detector)

The object of the present invention is to provide a remote monitoring apparatus for detecting the gas concentration of the gas detector and the detection speed of the gas detector which can improve the reliability of the tester for performing the performance test of the gas detector and the reliability of the performance evaluation.

In addition, the present invention is characterized in that, after a gas detector detects and displays a gas detection concentration value to be displayed using a camera, the gas detection concentration value image is transmitted to a tester terminal, It is a technical object to improve the convenience, test accuracy and speed of the tester in relation to the gas detector performance test by accurately recognizing the gas detection concentration value by applying the recognition algorithm.

In order to solve the above technical problem, a remote monitoring apparatus for gas concentration detection accuracy and detection speed test of a gas detector according to the present invention includes a test gas receiver accommodating a test gas, a gas detector for detecting a gas leaked from the test gas receiver, An image capturing device for capturing an image of a gas detection concentration value displayed by the gas detector and acquiring an image of a gas detection concentration value, a gas detection concentration value image transmitted from the image capturing device, And a tester terminal for extracting the concentration value and providing the tester to the information of the gas detection concentration generated by processing the extracted gas detection concentration value.

In the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the present invention, the gas detection concentration value extracting unit included in the tester terminal includes the gas detection concentration value image transmitted from the image acquisition apparatus An individual character image extracting unit for extracting individual character images included in the density value display region and storing the extracted individual character images as individual files, an individual character image extracting unit for extracting individual character images An individual character recognition unit for recognizing individual characters represented by the individual character images through comparison of similarities of reference images stored in advance in a reference image storage unit, and a gas detection concentration value for determining the gas detection concentration value by arranging the individual characters And a determination section.

In the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the present invention, reference images classified separately for each gas sensor model are stored in the reference image storage unit, The individual character images are extracted by comparing the reference images stored in correspondence with the specified gas detector model and the individual character images by specifying the gas detector models to which the individual character images extracted by the individual character image extracting unit belongs, And recognizes the individual characters represented by the characters.

In the remote monitoring apparatus for the gas-concentration detection accuracy and the detection speed test of the gas detector according to the present invention, the gas detection concentration value extractor may calculate the size of the individual character images extracted by the individual- And an image size adjusting unit for adjusting the size of the reference image stored in the storage unit to match the size of the reference images stored in advance.

The remote monitoring device for the gas concentration detection accuracy and the detection speed test of the gas detector according to the present invention is characterized in that the tester terminal includes a communication unit for receiving the gas detection concentration value image from the image acquisition device, A gas detection concentration value extraction unit for extracting the gas detection concentration value by applying an image recognition algorithm and the gas detection concentration value extracted by the gas detection concentration value extraction unit to generate the gas detection concentration information, And a gas detection concentration information generation / provision unit for providing the gas detection concentration information to the tester.

The remote monitoring apparatus for the gas-concentration detection accuracy and the detection speed test of the gas detector according to the present invention further comprises a lighting device for illuminating a display unit provided in the gas detector.

In the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the present invention, the gas detector includes a detection unit for detecting the gas leaked from the test gas receiver, and a gas detection concentration value And a display unit for displaying the display unit.

In the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the present invention, the image acquisition apparatus and the tester terminal communicate with each other by a wired communication method or a wireless communication method.

According to the present invention, it is possible to provide a remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector, which can improve the convenience of the tester performing the gas detector performance test and the reliability of the performance evaluation.

In addition, after the gas detection value detected by the gas detector is photographed using the camera, the gas detection concentration value image is transmitted to the tester terminal, and the tester terminal transmits the image detection algorithm to the gas detection concentration value image By accurately recognizing the gas detection concentration value by applying it, it is possible to improve the convenience and the test accuracy and speed of the tester relating to the gas detector performance test.

1 is a block diagram functionally showing a remote monitoring apparatus for gas-concentration detection accuracy and detection speed test of a gas detector according to an embodiment of the present invention,
2 is a diagram showing an exemplary configuration of a gas detection concentration value extracting unit included in a tester terminal according to an embodiment of the present invention,
3 is a diagram for explaining a specific operation of the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the embodiment of the present invention,
4 is a diagram for explaining a specific operation of the gas detection concentration value extracting unit included in the tester terminal according to an embodiment of the present invention,
5 is a diagram illustrating an actual system configuration of a remote monitoring apparatus for gas-concentration detection accuracy and detection speed testing of a gas detector according to an embodiment of the present invention,
FIG. 6 is a top view of a performance testing apparatus including a gas analyzer for testing and a gas detector, according to an embodiment of the present invention,
FIG. 7 is a diagram for explaining a specific operation example of a remote monitoring apparatus for a gas-concentration detection accuracy and a detection speed test of a gas detector according to an embodiment of the present invention in connection with an actual system configuration.

It is to be understood that the specific structural or functional description of embodiments of the present invention disclosed herein is for illustrative purposes only and is not intended to limit the scope of the inventive concept But may be embodied in many different forms and is not limited to the embodiments set forth herein.

The embodiments according to the concept of the present invention can make various changes and can take various forms, so that the embodiments are illustrated in the drawings and described in detail herein. It should be understood, however, that it is not intended to limit the embodiments according to the concepts of the present invention to the particular forms disclosed, but includes all modifications, equivalents, or alternatives falling within the spirit and scope of the invention.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The terms may be named for the purpose of distinguishing one element from another, for example, without departing from the scope of the right according to the concept of the present invention, the first element may be referred to as a second element, The component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between. Other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, the terms "comprises" or "having" and the like are used to specify that there are features, numbers, steps, operations, elements, parts or combinations thereof described herein, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, parts, or combinations thereof.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the meaning of the context in the relevant art and, unless explicitly defined herein, are to be interpreted as ideal or overly formal Do not.

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

1 is a block diagram functionally showing a remote monitoring apparatus for gas concentration detection accuracy and detection speed test of a gas detector according to an embodiment of the present invention.

Referring to FIG. 1, a remote monitoring apparatus for gas-concentration detection accuracy and detection speed testing of a gas detector according to an embodiment of the present invention includes a test gas receiver 10, a gas detector 20, an image acquisition device 30, A lighting device 40, and a tester terminal 50.

The test gas receiver 10 performs the function of receiving the test gas. The test gas receiver 10 is provided with a leak port for leaking the test gas to the outside, and the test gas leaks to the outside in a state in which the leakage amount is controlled through the leak port. For example, the test gas receiver 10 may be provided in a state of being fixed and supported in a frame through a support, a fixing device, or the like. In addition, for example, the test gas receiver 10 may be a glass flask, and may be configured to receive a test gas from a gas storage container connected to a gas storage container provided outside the frame through a connection pipe have.

The gas detector 20 detects the gas leaking from the test gas receiver 10 and displays the gas detection concentration value at a visual numerical value.

For example, the gas detector 20 may be configured to include a detecting unit 22 and a display unit 24. [

The detecting section (22) performs a function of a sensor for detecting a gas leaked from the test gas receiver (10).

The display unit 24 performs a function of visually displaying the gas detection concentration value detected by the detection unit 22 by digitizing it.

The illumination device 40 illuminates the display unit 24 provided in the gas detector 20 to assist the image acquisition device 30 to acquire a clear image.

The image acquiring device 30 acquires the gas detection concentration value image by photographing the gas detection concentration value displayed by the gas detector 20 through the display section 24 and transmits the obtained gas detection concentration value image to the tester terminal 50 As shown in Fig.

The tester terminal 50 receives the gas detection concentration value image from the image acquisition device 30, extracts the gas detection concentration value by applying the image recognition algorithm to the received gas detection concentration value image, And provides the tester with the gas detection concentration information generated by processing the gas detection concentration information.

For example, the tester terminal 50 may include a communication unit 52, a gas detection concentration value extraction unit 54, and a gas detection concentration information generation / provision unit 56.

The communication unit 52 performs a function of receiving a gas detection concentration value image through communication with the image acquisition device 30. [ For example, the image acquisition device 30 and the tester terminal 50 may be configured to communicate by a wired communication method or a wireless communication method.

The gas detection concentration value extraction unit 54 performs a function of extracting the gas detection concentration value by applying an image recognition algorithm to the gas detection concentration value image transmitted from the image acquisition device 30 through the communication unit 52. [

2, which shows an exemplary configuration of the gas detection concentration value extraction unit 54 included in the tester terminal 50, the gas detection concentration value extraction unit 54 includes a concentration value display region extraction unit 510, An individual character image extracting unit 520, an image size adjusting unit 530, an individual character recognizing unit 540, a gas detection concentration value determining unit 550, and a reference image storing unit 560.

The concentration value display region extracting unit 510 extracts a concentration value display region included in the gas detection concentration value image transmitted from the image capturing apparatus through a wire or wireless communication method. For example, the concentration value display region extracted by the concentration value display region extracting unit 510 can be stored as a file.

The individual character image extracting unit 520 extracts individual character images included in the concentration value display region extracted by the concentration value display region extracting unit 510 and stores the individual character images as individual files. For example, the individual character image extracting unit 520 retrieves density value display area files extracted and stored by the density value display area extracting unit 510, and stores the objects included in the density value display area files, that is, ~ 9), point,%, LEL, VOL, PPM can be re-extracted by one character and saved as a file. As a specific example, if the concentration of the gas detector 20 is 0.124% VOL, regions are set in the order of 0, ".", 1, 2, 4, Can be stored.

The image size adjustment unit 530 performs a function of matching the sizes of the individual character images extracted by the individual character image extraction unit 520 with the sizes of reference images stored in the reference image storage unit 560 in advance.

In the reference image storage unit 560, reference images classified separately for each gas detector model are stored. For example, the shape of the concentration display number of the display unit 24 provided in the gas detector 20 to be the concentration test object is previously captured in the respective images from 0 to 9, ".",%, LEL, VOL, PPM (For example, 2cm * 2cm) and a black-and-white image of 860 * 860 pixels or more, and can be stored in a file. If you want to measure several kinds of gas detectors, you can make a pattern image of the number of the concentration indicator of gas detectors by model of each maker and save them. Through this process, different density display forms are stored in the reference image storage unit 560 for each model of each maker.

The individual character recognition unit 540 recognizes the individual characters represented by the individual character images by comparing the individual character images stored in the individual files with the reference images stored in the reference image storage unit 560 in advance.

For example, after the individual character recognition unit 540 identifies the gas detector model to which the individual character images extracted by the individual character image extraction unit 520 belong, And recognizes the individual characters represented by the individual character images by comparing the similarity of the individual character images with each other.

The gas detection concentration value determination unit 550 performs a function of determining the gas detection concentration value by arranging individual characters.

The gas detection concentration information generation / provision unit 56 processes the gas detection concentration value extracted by the gas detection concentration value extraction unit 54 to generate gas detection concentration information, and provides the generated gas detection concentration information to the tester .

3 is a diagram for explaining a specific operation of the remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector according to the embodiment of the present invention.

3, in step S10, the test gas contained in the test gas receiver 10 is leaked while adjusting the leakage amount.

In step S20, the detection unit 22 provided in the gas detector 20 detects the gas leaked from the test gas receiver 10.

In step S30, a process of visually displaying the gas detection concentration value detected by the detection unit 22 of the display unit 24 provided in the gas detector 20 is performed.

In step S40, a process of illuminating the display unit 24 provided in the gas detector 20 is performed.

In step S50, a process of capturing the gas detection concentration value displayed by the image capturing device 30 through the display unit 24 and acquiring the gas detection concentration value image is performed.

In step S60, the process of transmitting the gas detection concentration value image to the tester terminal 50 is performed by the image acquisition device 30. [

In step S70, a process of receiving the gas detection concentration value image from the image capturing device 30 is performed by the communication section 52 provided in the tester terminal 50. [

In step S80, the gas detection concentration value extracting unit 54 provided in the tester terminal 50 performs a process of extracting the gas detection concentration value by applying the image recognition algorithm to the gas detection concentration value image.

4, the specific operation of the gas detection concentration value extracting unit 54 will be described below as an example.

In step S810, the concentration value display region extracting unit 510 included in the gas detection concentration value extracting unit 54 receives the gas detection concentration value image from the image capturing apparatus in a wired or wireless communication manner, A process of extracting a density value display area included in the image is performed. For example, the concentration value display region extracted by the concentration value display region extracting unit 510 can be stored as a file.

In step S820, the individual character image extraction unit 520 included in the gas detection concentration value extraction unit 54 extracts the individual character images included in the concentration value display region extracted by the concentration value display region extraction unit 510 Extracting and storing them as individual files is performed. For example, in step S820, the individual character image extracting unit 520 retrieves density value display area files extracted and stored by the density value display area extracting unit 510, and extracts the objects , Numbers (0 ~ 9), points,%, LEL, VOL, PPM, etc. can be extracted again by one character and saved as a file. As a specific example, if the concentration of the gas detector 20 is 0.124% VOL, regions are set in the order of 0, ".", 1, 2, 4, Can be stored.

In step S830, the image size adjusting unit 530 included in the gas detection concentration value extracting unit 54 calculates the sizes of the individual character images extracted by the individual character image extracting unit 520 in the reference image storing unit 560 A process of matching the size of the reference images stored in advance is performed. In the reference image storage unit 560, reference images classified separately for each gas detector model are stored. For example, the shape of the concentration display number of the display unit 24 provided in the gas detector 20 to be the concentration test object is previously captured in the respective images from 0 to 9, ".",%, LEL, VOL, PPM (For example, 2cm * 2cm) and a black-and-white image of 860 * 860 pixels or more, and can be stored in a file. If you want to measure several kinds of gas detectors, you can make a pattern image of the number of the concentration indicator of gas detectors by model of each maker and save them. Through this process, different density display forms are stored in the reference image storage unit 560 for each model of each maker.

In step S840, the individual character recognition unit 540 included in the gas detection concentration value extraction unit 54 compares the individual character images stored in the individual files with the reference images stored in the reference image storage unit 560 in advance A process of recognizing the individual characters represented by the individual character images is performed. For example, in step S840, the individual character recognition unit 540 identifies a gas detector model to which individual character images extracted by the individual character image extraction unit 520 belong, and then stores The individual characters represented by the individual character images can be recognized by comparing the similarity between the reference images and the individual character images.

In step S840, the process of determining the gas detection concentration value by sequentially arranging the individual characters recognized by the gas detection concentration value determination unit 550 included in the gas detection concentration value extraction unit 54 is performed.

In step S90, the gas detection concentration information generation / provision unit 56 provided in the tester terminal 50 processes the extracted gas detection concentration value to generate gas detection concentration information, and sends the generated gas detection concentration information to the tester Is provided.

Hereinafter, the actual system configuration environment of this embodiment will be described.

FIG. 5 is a diagram illustrating an actual system configuration of a remote monitoring apparatus for a gas-concentration detection accuracy and a detection speed test of a gas detector according to an embodiment of the present invention, and FIG. 6 illustrates, in an embodiment of the present invention, 7 is a graph showing the gas concentration detection accuracy of the gas detector according to the embodiment of the present invention and the specific operation of the remote monitoring apparatus for the detection speed test of the gas detector according to the embodiment of the present invention Fig. 8 is a diagram for describing an example in connection with an actual system configuration.

5 to 7, a procedure for remote sensing of the gas sensor accuracy and detection speed is as follows: (1) In a gas container, a gas is injected into a glass flask through a stainless steel pipe and a hose; (2) ③ The LCD display displayed on the gas detector is photographed with a camera, and the real-time image is transmitted to a notebook or the like of the tester by a wired / wireless communication method. ④ The tester is transmitted from the remote to the notebook Monitor the real-time image (concentration value), extract the concentration value reflected in the image form in the image, convert it into numerical value, and graph it.

For example, the gas can be a standard gas, which can be individually charged into the vessel, such as methane, propane, carbon monoxide, ammonia, and hydrogen sulphide. Seven gas concentrations can be produced proportionally within the range of 0% to 100% LEL for each gas and charged into each vessel. Since there are 7 kinds of concentration of 5 kinds of gas, it can be charged to 35 gas containers by concentration of each gas. When testing by each concentration, gas container can be replaced and connected.

For example, detection rate = total measurement time-image transmission time-glass tube passing time, accuracy = (actual concentration-standard concentration) / standard concentration × 100, and error rate (% FS) Full scale value) / full scale value 占 100.

An example of the actual configuration of the apparatus for testing the gas detector performance will be described below.

As shown in FIG. 6, the blue color of the glass flask was prepared so as to be arranged diagonally above and below the glass flask, one set being fixed as a support, and the other one being made to be used as a glass flask having a length of 200 mm A 300 mm glass flask can also be fabricated in a variable shape for fabrication.

Variable supports and green color can be made of semicircular or elliptical ends of the support that support the glass tube and the ends can be made of clamps with rubber O-rings and other glass tubes can be replaced. . ≪ / RTI >

The gas detector is made of a material (aluminum or the like) which does not cause poisoning or deformation from flammable or toxic gas, and is placed so as to be balanced with the outlet of the glass flask and the suction part of the detector, The position and height can be made as appropriate.

As the configuration for image acquisition, a high-performance industrial camera, two illumination devices, and an interface means may be provided.

The camera (2 sets) captures the gas concentration data displayed on the LCD display during the gas concentration detection test of domestic and overseas gas detectors, and transmits the video information to the notebook of the tester through the wired or wireless communication interface .

It is preferable to use a camera which provides a high level of resolution so that the gas concentration data displayed on the LCD display of the gas detector can be photographed as moving images and the density data in the moving image can be converted into numbers.

The illumination device 40 provides illumination suitable for camera exposure conditions.

The camera should be fixed to the stand, and the stand can be constructed with a structure that can be fixed and separated from the performance test apparatus frame described above.

The gas vessel is a set of four vessels, each of which can be a steel or aluminum vessel for storing methane, propane, carbon monoxide and ammonia, respectively. For example, the ammonia container may be made of aluminum.

The gas container and its components may consist of a regulator for injecting gas into a glass flask, stainless steel tubing, and a rubber hose.

Thin stainless steel piping is a pipe connected to a regulator and a rubber hose attached to a gas container and may have a structure fixed to a performance test apparatus frame before being connected to a rubber hose.

The rubber hose is used for connecting the glass flask with the piping of the gas container, and gas hose may be applied.

As shown in FIG. 7, the remote monitoring system includes a tester terminal such as a notebook equipped with an image display and a number conversion program.

And can be produced by a tool or a program that transmits a moving image of the gas detector concentration measured in real time.

Videos with measured gas concentrations can be displayed in real time on the notebook.

The function of converting the density data included in the moving image into numerical values can be implemented by a program.

It is possible to display the gas detector concentration value converted into numerical value in real time graph.

You can also save the converted data as a text (.txt) file, implement it in Matlab to read and plot the saved file, and provide the source (xxx.m).

As described in detail above, according to the present invention, there is provided a remote monitoring device for the gas concentration detection accuracy and the detection speed test of the gas detector which can improve the reliability of the tester for performing the gas detector performance test and the reliability of the performance evaluation .

In addition, after the gas detection value detected by the gas detector is photographed using the camera, the gas detection concentration value image is transmitted to the tester terminal, and the tester terminal transmits the image detection algorithm to the gas detection concentration value image By accurately recognizing the gas detection concentration value by applying it, it is possible to improve the convenience and the test accuracy and speed of the tester relating to the gas detector performance test.

10: Test gas receiver
20: Gas detector
22:
24:
30: Image acquisition device
40: Lighting device
50: Tester terminal
52:
54: gas detection concentration value extracting section
56: gas detection concentration information generation / provisioning
510: density value display region extracting section
520: Individual character image extracting unit
530: Image size adjustment unit
540: Individual character recognition unit
550: gas detection concentration value determination unit
560: Reference image storage unit

Claims (8)

A test gas receiver containing a test gas;
A gas detector for detecting a gas leaked from the test gas receiver and displaying a gas detection concentration value;
An image acquiring device for acquiring a gas detection concentration value image by photographing a gas detection concentration value displayed by the gas detector;
And a tester terminal for extracting the gas detection concentration value from the gas detection concentration value image transmitted from the image acquisition device and providing the gas detection concentration information generated by processing the extracted gas detection concentration value to the tester,
Wherein the gas detection concentration value extracting unit included in the tester terminal comprises:
A concentration value display region extracting unit for extracting a concentration value display region included in the gas detection concentration value image transmitted from the image capturing apparatus;
An individual character image extracting unit for extracting individual character images included in the density value display area and storing the individual character images as individual files;
An individual character recognition unit for recognizing the individual characters represented by the individual character images by comparing the individual character images stored in the individual files and the reference images stored in the reference image storage unit separately classified by the gas sensor model; And
And a gas detection concentration value determination unit for determining the gas detection concentration value by arranging the individual characters,
Wherein the individual character recognizing unit comprises:
Wherein the individual character image extraction unit extracts the individual character images from the individual character images by comparing the reference images stored in correspondence with the specified gas detector model and the individual character images, Wherein the recognition unit recognizes individual characters represented by the gas concentration of the gas sensor. delete delete The method according to claim 1,
Wherein the gas detection concentration value extracting section
Further comprising an image size adjusting unit for adjusting the size of the individual character images extracted by the individual character image extracting unit to the size of the reference images stored in the reference image storing unit. And a remote monitoring device for the detection speed test. The method according to claim 1,
The tester terminal
A communication unit for receiving the gas detection concentration value image from the image acquisition device;
A gas detection concentration value extraction unit for extracting the gas detection concentration value by applying an image recognition algorithm to the gas detection concentration value image; And
And a gas detection concentration information generation / provision section for processing the gas detection concentration value extracted by the gas detection concentration value extraction section to generate the gas detection concentration information and providing the generated gas detection concentration information to the tester And a remote monitoring device for the gas concentration detection accuracy and detection speed test of the gas detector. The method according to claim 1,
Further comprising an illuminating device for illuminating a display part of the gas detector. The remote monitoring device for the gas concentration detecting accuracy and the detection speed test of the gas detector. The method according to claim 1,
The gas detector
A detecting unit for detecting a gas leaked from the test gas receiver; And
And a display unit for displaying the gas detection concentration value detected by the detection unit. The remote monitoring apparatus for the gas concentration detection accuracy and the detection speed test of the gas detector. The method according to claim 1,
Wherein the image capturing device and the tester terminal communicate with each other by a wire communication method or a wireless communication method.

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