KR101863530B1 - System for fire predict and maintenance using visible light and infrared ray thermal image - Google Patents

Abstract

The present invention relates to a fire prediction and maintenance system using visible light and infrared ray thermal images, comprising: a plurality of photographing members (100) for photographing visible light images and infrared ray thermal images of a monitoring object; a control unit (200) for storing the photographed visible light image and infrared ray thermal image data and transmitting the same to a management server (300) through wired and wireless communication; and a management server (300) for displaying the thermal images of the corresponding monitoring object on a display unit (310). Therefore, it is possible to improve the accuracy of predicting the possibility of fire occurrence.

Description

FIELD OF THE INVENTION [0001] The present invention relates to fire prediction and maintenance systems using visible and infrared thermal images,

The present invention relates to a fire prediction and preservation system using visible light and infrared infrared image, in which a visible light image and an infrared image of a monitored object are simultaneously measured and monitored to predict the possibility of a fire, And more particularly, to a fire prediction and conservation system using visible light and infrared thermography images.

Fires in various buildings (buildings, apartments, etc.), power plants (thermal power plants, nuclear power plants, etc.), factories (chemical plants, oil refineries, steel plants, etc.) Because it causes catastrophic damage to companies, public corporations and countries, various fire alarms and fire extinguishing systems are installed in these facilities.

However, the conventional fire alarm and fire extinguishing system is a fire alarm system, and there is a problem such as a malfunction of the fire sensor. Therefore, there is a need to develop a fire detection system based on a thermal image. Accordingly, 10-1462247 discloses a thermal image based smart fire detection system.

Such a thermal image-based smart fire detection system has a high-resolution camera 12 installed together with an infrared thermal imaging camera 11 at a place of installation so that image information of the two cameras can be displayed on a monitor The module 21 analyzes the image information in the image monitoring module and performs fire suppression using an automatic fire extinguisher 40 such as a sprinkler.

As a result, in order to construct a fire prediction monitoring system, it is necessary to purchase a commercial thermal image detector and a commercial visible light camera, which are the core measurement devices, and to insert two cameras into one protective case. After that, two camera signal lines are communicated to a separate server and operated to fire the program through the developed program on the server.

However, when two cameras (thermal image, visible light) are inserted into one protection case, the two camera makers are different, and since the appearance of the camera is each one of them, The size of the case is increased, and the cost of purchasing the camera is increased.

Therefore, it is difficult to install it in an electric switchboard or a precision machine inside a narrow space, and it should be installed in a wide place indoors and outdoors to monitor a target at a distance. At this time, when the fire monitoring camera is measured from a distance, the following problems arise.

The infrared area detector for measuring thermal infrared rays (8 to 14 um) in the thermal imaging camera 11 for fire monitoring is not available in the domestic market and is produced by some companies in advanced countries worldwide It is manufactured as a military confidential product, so the detector which can be used for private commercial use is approved for civil use only with less than 10 models with low resolution and low sampling rate. Therefore, thermal cameras that are sold on the market are sold with thermal-only cameras with a limited number of disclosed detectors.

If you buy such a low resolution commercial thermal imager and place it in a bulky protective case and install the protective case in a large area and monitor the target at a distance of more than 10m, the image information is not clear, so accurate temperature measurement it's difficult.

Therefore, it is impossible to detect whether a fire is generated if a fire is generated and a flame is large. However, it is impossible to perform fire prediction monitoring to measure a rise in temperature (temperature) immediately before a fire due to an overcurrent of an electric appliance.

In order to improve the purchase cost and the installation space of the server due to the server being installed separately as in the above-mentioned patent, Patent Document No. 2016-0010387 which integrates a thermal imaging camera, a visible light camera, and a video monitoring system Quot;

The above-mentioned patent is a system for interlocking fire monitoring and automatic fire extinguishing, and a functional system target of automatic fire suppression using an infrared detector is the same, but it is a server-integrated type.

However, the system is constructed by purchasing a commercial thermal imaging camera and a visible light camera. Since the protective case bulky is large, it is difficult to install it in a narrow space. Therefore, it is necessary to perform a long distance measurement. It still has a problem that it is difficult to precisely measure changes.

Registered Patent Publication No. 1462247 (2016.11.10, a smart fire detection system based on infrared thermography and an automatic fire extinguishing device interface platform) Published Japanese Patent Application No. 2016-0010387 (Feb. 21, 2017, Fire alarm and fire extinguishing system using thermal image fusion camera)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a method and apparatus for capturing a visible light image and an infrared radiographic image to be monitored, And it can be manufactured in a small volume, making it possible to install it easily in a place where the inner space such as a PC or a distribution board is small. Therefore, it is possible to use a visible light and an infrared thermal image And to provide a fire prediction and conservation system.

The present invention also relates to a method and a system for transmitting an inspection request message together with thermal image data and image data to a manager when the measured temperature of the deteriorated image is equal to or higher than a set temperature, System.

In addition, the present invention provides a fire prediction and preservation system using visible and infrared thermal images, which can more accurately diagnose the temperature of the deteriorated image in order to increase the discrimination power when the temperature range of the deteriorated image is distributed within a certain range .

According to an aspect of the present invention, there is provided a display device including a thermal image detector (130) and a visible light detector (140) facing each other in the same direction, A plurality of photographing members (100) for photographing an image; The infrared ray image data and the infrared ray image data which are respectively installed in the plurality of image sensing members 100 and are photographed by the thermal image detector 130 and the visible light detector 140, 300; A management server 300 for converting each part of the monitored object into a temperature based on the thermal image data received from the controller 200 and displaying the thermal image of the monitored object on the display unit 310 together with the captured image Wherein the photographing member 100 includes two detector mounting holes 111 spaced apart from each other on a front surface thereof for mounting the thermal image detector 130 and the visible light detector 140, The mounting hole 111 is formed to have an inclined edge 112 extending from the inside to the outside and a binding groove 113 is formed at the rear edge so that one side of the substrate 210 constituting the control unit 200 is fitted and fixed. (110); The board 210 fitted into the binding groove 113 is fitted into the cap 110 while being inserted into the inside through the front opening and connected to the management server 300 and the control unit 200 And a housing 120 in which a cable hole 121 is formed to allow a cable to pass through the cable 120. The management server 300 controls the temperature of the thermal image data received from the controller 200 In the case of the distribution, the temperature range is divided into 5 to 20 times by amplifying the thermal image data to increase the color discrimination power.

When the maximum temperature among the temperatures converted from the thermal image data received from the controller 200 is higher than a predetermined temperature, the management server 300 transmits infrared thermal image data and visible light of the monitored object to the manager terminal 320 Image data and an inspection request message can be transmitted.

According to the fire prediction and maintenance system using the visible light and the infrared thermal image of the above configuration, the visible light image of the monitoring object and the infrared thermal image can be monitored together to accurately diagnose the deterioration. It is possible to manufacture a small size that can be mounted in one place, so that the use range can be greatly widened as compared with the conventional deterioration diagnosis apparatus, and furthermore, accurate diagnosis can be made by subdividing the deteriorated temperature temperature, It is effective.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a fire prediction and maintenance system using visible light and infrared radiographic images according to the present invention;
2 is a perspective view showing the photographing member according to the present invention,
Fig. 3 is a sectional view of Fig. 2,
FIG. 4 is a view showing a coupling structure of a cap and a substrate of an image pickup member according to the present invention,
5A to 5C are diagrams showing a display unit displaying images and thermal images transmitted from a photographing member installed in each place according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fire prediction and maintenance system using a visible light and an infrared thermal image according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in the figure, the fire prediction and maintenance system using visible light and infrared infrared image according to the present invention includes a photographing member 100 installed on one side with a thermal image detector 130 and a visible light detector 140 facing in the same direction, And a management server 300 receiving data from the control unit 200 and displaying thermal images and image information transmitted to the display unit 300, .

The photographing members 100 are installed at selected places, and a plurality of photographing members 100 are provided. The photographing members 100 are installed at the corresponding places and photograph infrared images and visible light images of the monitored objects and transmit them to the control unit.

The thermal image detector 130 is a sensor unit that infrared-photographs a thermal image of a monitored object and transmits the thermal image data to a control unit. The visible light detector 140 photographs the image of the monitored object as a normal high-resolution camera And transmits the image data to the control unit.

In the present invention, since the thermal image detector and the visible light detector are installed in one photographing member and are connected to the control unit, the volume of the camera can be minimized compared with a camera separately provided with a separate control unit .

The control unit 200 includes a substrate 210 and receives thermal images and image data captured from the thermal image detector 130 and the visible light detector 140 and stores the thermal images and image data. And transmits the data to the mobile terminal 300.

Preferably, the control unit 200 is connected to the management server by wired communication rather than by wireless communication. The control unit 200 receives RS information from a control unit installed in the plurality of photographing members at the management server, To transmit data.

The management server 300 converts the thermal image data received from the control unit 200 into a temperature corresponding to a thermal image of each part of the monitored object and stores the thermal image of the monitored object in a visible light image And is displayed on the display unit 310 together.

At this time, the information displayed on the display unit 310 may be displayed by arranging image data on one side thereof together with a thermal image of the monitored object, or displaying the thermal image of the monitored object on the display unit 310, The image corresponding to the corresponding portion can be displayed on the screen.

Therefore, the manager can monitor both the thermal image and the visible light image of all the places where the imaging member is installed, thereby diagnosing the possibility of fire as well as overheating. It is also possible to predict the occurrence of fire in advance, .

In the meantime, when the temperature range of the thermal image data received from the controller 200 is distributed over a predetermined interval, the management server 300 of the present invention subdivides the temperature range of the thermal image data into 5 to 20 times, So as to be displayed.

The reason for doing this is to make it easy to discriminate the temperature deviation of each part because the temperature deviation of each part can not be easily discriminated by the deterioration phase even if the deterioration phase temperature range is within a certain range.

For example, when the temperature range is within the range of 50 占 폚, the color expressed similarly can be further subdivided so that the temperature deviation of each part can be easily discriminated.

In addition, assuming that the circuit is constructed so that the first thermal image is realized with 300 colors, if the thermal image captured by the thermal image detector has a temperature deviation of less than 30 colors, it is difficult to distinguish the naked eye By making the colors within 30 colors more subdivided, it is possible to easily discriminate the temperature deviation.

When the mouse cursor is placed on the thermal image displayed on the display unit 310, the management server 300 is preferably controlled to display the temperature of the corresponding part on the screen.

That is, the administrator can check whether the part is overheated only by the color of the corresponding part, but the manager can accurately recognize the temperature by displaying the temperature because the corresponding part can not recognize the exact temperature.

Therefore, it is possible to confirm beforehand whether the temperature of the relevant part is close to the set temperature to be inspected. If the temperature is close to the set temperature, it is possible to perform the inspection in advance or perform other measures immediately, have.

Here, even if the administrator does not check the temperature, the management server 300 compares the maximum temperature among the temperatures converted from the thermal image data transmitted from the controller 200 to a preset temperature, and if the temperature is higher than the preset temperature, Image data and image data of the object to be monitored and an inspection request message are transmitted to the controller 320.

Accordingly, the manager can immediately check the place where the photographing member is installed, the part such as the distribution board, and prevent the fire from occurring.

The photographing member 100 of the present invention includes a cap 110 and a housing 120 for installation of a thermal image detector, a visible light detector, and a control unit.

The cap 110 is formed with two detector mounting holes 111 spaced apart from each other for mounting the thermal image detector 130 and the visible light detector 140. The detector mounting hole 111 is formed on the inner side A binding groove 113 is formed at the rear edge of the substrate 210 so that one side of the substrate 210 constituting the control unit 200 is inserted and fixed.

The substrate 210 is fixed so as to be fixed with silicon or the like while being sandwiched by the coupling groove 113. The substrate 110 is fixed to the detector mounting hole 111 with a lens portion of a thermal image detector and a visible light detector.

The housing 120 is fitted into the cap 110 with the substrate 210 inserted into the coupling groove 113 inserted through the opening of the housing 120 into the coupling groove 113.

That is, the housing 120 is configured such that the thermal image detector and the visible light detector are not exposed to the outside as well as the control unit. In the rear surface, the cable connecting the management server 300 and the controller 200 is passed through the cable hole (Not shown).

According to the present invention configured as described above, it is possible to constitute the image pickup member provided with the thermal image detector and the visible light detector in a small volume, so that the inner space such as the distribution panel or the control box can be installed in the narrow electric device, It is a very useful invention that enables to precisely monitor the condition of overheated parts of places or electric circuits that occur from time to time, so that the possibility of fire can be predicted and taken immediately.

100: photographing member 110: cap
111: Detector mounting hole 112:
113: coupling groove 120: housing
121: Cable hole 130: Thermal image detector
140: Visible light detector 200:
210: substrate 300: management server
310: display unit 320: administrator terminal

Claims (5)

A plurality of image sensing members (100) installed on one side of the thermal image detector (130) and the visible light detector (140) so as to face in the same direction, respectively installed in the selected locations to image a visible light image and infrared infrared image of the monitored object;
The infrared ray image data and the infrared ray image data which are respectively installed in the plurality of image sensing members 100 and are photographed by the thermal image detector 130 and the visible light detector 140, 300;
A management server 300 for converting each part of the monitored object into a temperature based on the thermal image data received from the controller 200 and displaying the thermal image of the monitored object on the display unit 310 together with the captured image ), ≪ / RTI >
The imaging member 100 is formed with two detector mounting holes 111 spaced from each other on the front surface for mounting the thermal imaging detector 130 and the visible light detector 140, A cap 110 having a coupling groove 113 formed at one edge of the substrate 210 so as to be extended from the inner side to the outer side and having one side of the substrate 210, ;
The board 210 fitted into the binding groove 113 is fitted into the cap 110 while being inserted into the inside through the front opening and connected to the management server 300 and the control unit 200 And a housing 120 having a cable hole 121 formed therein to allow a cable to pass therethrough,
When the temperature range of the thermal image data received from the controller 200 is distributed over a predetermined interval, the management server 300 divides the temperature range by 5 to 20 times to amplify the thermal image data, A fire prediction and maintenance system using visible and infrared thermal images.
The method according to claim 1,
When the thermal image of the monitored object is displayed on the display unit 310, the management server 300 arranges the image data received from the control unit on one side of the deteriorated image so that the image data is displayed together, or only the thermal image And the image corresponding to the corresponding portion is displayed on the screen when the deteriorated image displayed in the displayed state is displayed on the screen.
3. The method according to claim 1 or 2,
Wherein the management server (300) displays a temperature of a corresponding portion of a mouse cursor on a thermal image displayed on the display unit (310) on a screen.
The method of claim 3,
When the maximum temperature among the temperatures converted from the thermal image data transmitted from the controller 200 is higher than a predetermined temperature, the management server 300 transmits the visible light image of the monitored object and the infrared image Data and an inspection request message are transmitted to the fire prediction and maintenance system using the visible and infrared thermal image.
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