KR100492189B1 - Discernment device for far distance fire confirmation - Google Patents

Abstract

The present invention relates to a far-field fire detection and identification device used for firefighting, and more particularly to a flame detector having a combination of ultraviolet (UV) and infrared (IR) sensors for detecting radiant energy radiated from a flame of a fire source. The present invention relates to a far-field fire detection identification device for greatly detecting a far fire by greatly increasing the fire detection capability and effectively monitoring a large area with a single detection device.

The present invention greatly improves the detection capability of the combined flame detector with limited detection capability, which enables early detection of long-distance fires, and can monitor large areas, effectively operating as a small number of detectors in facilities inside and outside the facility. It provides a remote fire detection identification device that can be used, and provides a remote fire detection identification device configured to allow dynamic monitoring in all directions around the installation post, away from static monitoring in one direction only. Long-distance fire, which allows the camera installed on the same axis as the direction of detection to operate to provide image information of the detection area so that identification and information storage at the control center can be easily judged. To provide a detection identification device,

The present invention is a composite flame detector (10) having an ultraviolet and infrared sensor, the sensor is formed to direct in the direction opposite to the direction of the flower source to form a parabolic light collecting plate (20) facing the sensor of the sensor is generated from the source Concentrates the light energy to focus on the sensor of the sensor, characterized in that the sensor 10 and the light collecting plate 20 is fixedly coupled to one mount (30).

Description

Discrete device for far distance fire confirmation

The present invention relates to a far-field fire detection and identification device used for firefighting, and more particularly to a flame detector having a combination of ultraviolet (UV) and infrared (IR) sensors for detecting radiant energy radiated from a flame of a fire source. The present invention relates to a far-field fire detection identification device for greatly detecting a far fire by greatly increasing the fire detection capability and effectively monitoring a large area with a single detection device.

In general, a fire detector used to detect a fire is mainly composed of a detector made of a bimetal of a constant temperature type that is exposed to the ceiling of a building.

However, the detector has a drawback that the fire can be detected only when the fire is spread to some extent, and thus the detection range is extremely narrow, and the detection range is extremely narrow, so that a plurality of facilities must be provided at regular intervals on the ceiling of the building.

In order to solve the problem of the constant temperature type bimetal fire detector, a flame detector which detects infrared rays and ultraviolet rays from radiant energy radiated from a flame as a fire source and outputs a fire detection signal when the detection conditions are satisfied is used.

Such a flame detector is provided with a perspective window 110 of the sensor for detecting infrared rays and ultraviolet rays as shown in Figure 1, respectively, in front of the flame detector enclosure 100, the interior of the enclosure 100 has a flame detection circuit The bracket 120 is fixed to the wall or the ceiling to form a drawer tube 130 to draw out the cable.

The detection angle of the conventional flame detector is known to be about 100 degrees and the detection distance is about 30 meters.

This detection capability has the advantage that the detection capability is slightly improved compared to the above-described prior art, and because the detection of the infrared and ultraviolet wavelengths generated from the fire source is detected, the malfunction rate is small and the fire detection is accurate.

However, when looking at the detection capability, even when the construction is directed to the monitoring area due to the limited detection angle and the detection distance, the blind spots may occur. To prevent such blind spots, it is required to install a large number of flame detectors in the construction design. If there is an obstacle, a problem arises in that detection cannot be accurately performed due to the limitation of the straight disturbance of the light and the inability to collect diffuse reflection.

The limit of the above detection capability is due to the difficulty in transmitting light energy in the wavelength range to drive the flame detector because the light energy generated from the fire source is physically drastically lowered by the air density when the detection distance is out of the maximum distance of 50 meters. However, the diameter of the see-through window of the enclosure is less than 30 mm, and the amount of light received is small. In particular, the amount of light entering into the diffuse reflection is limited to be accepted. On the other hand, in order to improve the detection sensitivity, it has been proposed to compensate the sensitivity by installing two sensors having different sensing characteristics as in the conventional Japanese Patent Application Laid-open No. Hei 6-290375. In order to complement the characteristic to be aimed at, it is installed by plural and the output is merged. In addition, as shown in Japanese Patent Application Laid-Open No. 8-338760, by using a combination of ultraviolet and infrared sensors, the circuit for processing the sensor output can be improved to reduce the malfunction rate and to quickly and accurately obtain a detection signal. Although proposals have been made, it has also been impossible to extend the detection range.

Therefore, even if such a flame detector is used, it is impossible to apply early detection of fire in outdoor facilities (oil tank, ammunition, factory equipment, etc.) in a large area depending on the detection radius and the limitation of the detection distance.

As a result, lukewarm responses to disaster prevention surveillance of a wide range of facilities depend on closed-loop cameras or the personnel of patrols.

The present invention has been made to solve the problems of the prior art as described above has the following object.

The present invention greatly improves the detection capability of the combined flame detector with limited detection capability, which enables early detection of long-distance fires, and can monitor large areas, effectively operating as a small number of detectors in facilities inside and outside the facility. This is to provide a possible remote fire detection identification device.

The present invention is to provide a remote fire detection identification device made to be capable of dynamic monitoring in all directions around the installation post, away from the form of static monitoring in one direction only.

According to the present invention, when a fire is detected, a camera provided on the same axis as the detection direction is operated to provide image information of a detection area so that identification and information storage at a control center can be easily determined to determine the analysis and response of the fire. It is to provide a distance fire detection identification device made to be able to.

The present invention made to achieve the object as described above is a composite flame detector having an ultraviolet and infrared sensor, and formed to direct the detector in the direction opposite to the direction of the flower source to form a parabolic light collecting plate facing the sensor of the detector By condensing the light energy generated from the fire source to focus on the sensor of the sensor, and by combining the sensor and the light collecting plate fixed to one mount.

The mount may be of a fixed type or may have a built-in drive so that it can swing forward and in position.

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

In the far-field fire detection and identification device of the present invention, as shown in FIG. 2, in the combined flame detector having an infrared sensor and an ultraviolet sensor, the sensors 12 and 14 of the detector 10 are opposite to the direction of the flower source. And a parabolic light collecting plate 20 facing the sensors 12 and 14 of the sensor 10 to condense light energy generated from a fire source and focus the sensor on the sensor 10. In this case, the sensor and the light collecting plate are fixedly coupled to one mount 30.

The parabolic light collecting plate 20 is manufactured to match the focal length with the sensors 12 and 14 of the sensor 10. The larger the aperture, the greater the detection distance and the detection angle, and of course, the parabolic light collecting plate 20 does not increase infinitely.

In addition, the light collecting plate 20 may be formed of a glass material having a coating curvature or a predetermined curvature so as to at least have excellent reflection efficiency.

The present invention may be modified as shown in FIGS. 3 and 4.

This is achieved by coupling and forming a fallopian tube-type secondary light collector 22 on the front of the sensor 20 to increase the light collecting efficiency of the reflected light of the parabolic light collecting plate 20.

In addition, the present invention may be modified as shown in Figs.

This is achieved by hermetically coupling a tertiary condenser 24 made of a transparent cover 244 having a plurality of focus lenses 240 and 242 formed at the center of the secondary condenser 22 at the center thereof, and the mount 30. It is made by adding a rotation drive device for driving the motor 360 degrees in all directions to the front, it can be made by fixedly coupled to the imaging camera 60 installed so as to point on the same axis and the sensor 10.

The inner surface of the secondary concentrator 22 has a function of collecting light energy flowing into at least diffuse reflection with a sensor, thereby having a far fire detection capability, and the third concentrator 24 also focuses on the condenser 20. It is very useful to improve the detection ability because the efficiency of focusing the light energy is concentrated to the sensor through the convex lens and the focus lens (240, 242) having.

Looking at the operation of the present invention constituting the technical configuration as described above in more detail as follows.

When a fire is ignited in a specific monitoring area, ultraviolet and infrared wavelengths, which are specific wavelength bands of light energy generated from a fire source, are emitted, and the light energy is transmitted to the infrared and ultraviolet sensors 12 and 14 of the detector 10 through the light collecting plate 20. ) Will generate a fire detection output.

Here, the operation of the fire detection sensor will be understood by a known circuit and a detailed description thereof will be omitted.

According to the experimental results of the present inventors, when the light collecting plate 20 is configured, it is confirmed that the detection capability is remarkably improved as compared with the case of configuring only the conventional detector.

In addition, when the secondary condenser 22 is additionally installed, it is useful for focusing diffusely reflected light energy even when obstacles exist on a straight line from the fire source to interfere with direct light, and thus fire detection can be performed even in a surveillance area with many obstacles.

In addition, when the transparent cover 244 having the focus lenses 240 and 242 are hermetically coupled to the front of the secondary light collector 22, the light energy focused from the collecting plate 20 is collected from the focus lens to the sensor. By focusing, the far fire detection capability is further doubled, and at the same time, the transparent cover 244 serves to prevent contamination of the sensor surface, thereby facilitating management of the facility.

On the other hand, in addition to the modified embodiment of the present invention, when the turning drive device 50 driven by the electric force in the mount 30 is installed 360 degrees around the installation location of the remote fire detection identification device of the present invention It is possible to monitor a large area of fire while turning, so that a small facility can monitor a large area.

For example, the swing drive device 50 may include various structures such as a ring gear-type swing device combining a motor and a reduction gear, and the swing drive device may be selectively applied from a known technology, and thus, detailed description thereof is omitted. .

In the case where the fire detection device is swiveling omnidirectionally, as shown in the modified embodiment, the fire detection device is started by this output, especially when a fire detection output is generated, and is installed to face the same axis as the detector 10. It is possible to obtain information on the authenticity of the fire area through the image recording camera 60 as an image, and at the same time to control the light collecting plate 20 in a stationary state to obtain a more accurate fire detection information, image recording It also works to reduce the burden of information storage because it is only taken when a fire is detected.

The sensor 10 and the parabolic light collecting plate 20 may be formed to face the central axis horizontally as illustrated, as well as the detector 10 may be formed to be biased to one side of the central axis of the light collecting plate 20. Only the focal axis between the collecting tube and the sensor sensor is maintained, and this opposite axis can be varied depending on the curvature of the parabolic light collecting plate.

On the other hand, the present invention does not emit a detection output to a light source having a thermal radiation energy, such as normal visible light, electric light, like, malfunctions due to condensation can be excluded.

According to the present invention as described in detail above, the weak light energy of the diffuse reflection wavelength band is reflected and transmitted to other facilities around, compared to the prior art, which is difficult to detect due to the presence of obstacles on the linear axis through which light energy radiated from the source is transmitted It is possible to detect the fire by condensing light, and it is possible to detect the fire precisely by condensing, so that the response speed of the detector is greatly increased, and it is possible to condense the light energy radiated from the far source by parabolic light collecting plate. Therefore, the detection range can be extended to hundreds and thousands of meters, and the horizontal rotation of the detection unit can be extended horizontally and all around, so that the fire detection range of one detection device can be greatly increased. It can be effective.

In addition, when the secondary tertiary condenser is added, the efficiency of focusing the weak light energy is increased, so that the above-described fire detection capability can be improved. As an occupied facility, it is an excellent invention that can be applied more effectively to various disaster prevention facilities such as an oil depot, a warehouse, a hangar, a maintenance window, a base window, a defense facility or an air defense facility.

1 is an external view showing a conventional fire flame detector.

Figure 2 is a basic block diagram showing a remote fire detection identification device according to the present invention.

3 is a block diagram showing a far-field fire detection identification device showing another modification of the present invention.

4 is an enlarged perspective view showing an extracting device of FIG. 3 according to the present invention;

5 is a block diagram showing a far-field fire detection and identification device showing another modification of the present invention.

6 is an enlarged perspective view showing an extracting device of FIG. 5 according to the present invention;

7 is an exploded view showing a light collecting device configured in a flame detector.

** Description of symbols for the main parts of the drawing **

10: detector 20: light collecting plate

22: secondary condenser 30: mount

50: swing drive device 60: camera

Claims (6)

In the combined flame detector that detects the light energy of the fire source detected by the sensor with a built-in infrared (IR) sensor and ultraviolet (UV) sensor, The sensors 12 and 14 of the detector 10 are formed to be directed in a direction opposite to that of the flower source, A parabolic light collecting plate 20 is formed to face the sensors 12 and 14 of the detector 10 to condense light energy generated from a fire source and focus the sensor on the sensor 10. Long range fire detection identification device characterized in that the fixed and coupled to the sensor and the light collecting plate to one mount (30). The method of claim 1, wherein the parabolic light collecting plate 20 is made to match the focal length with the sensors 12, 14 of the sensor 10, any of the glass material reflecting plate having a coating or constant curvature for the reflection efficiency is increased. Long range fire detection identification device, characterized in that consisting of one. The apparatus of claim 1, wherein a fallopian tube-type secondary light collector 22 is formed to be coupled to the front surface of the detector 20 to increase the light collecting efficiency of the reflected light of the parabolic light collecting plate 20. . The method of claim 3, wherein a plurality of focus lenses 240 and 242 are formed at the front end of the secondary light collector 22 to seal the third light collector 24 made of a transparent cover 244 to be hermetically coupled to each other. Distance fire detection identification device. The remote fire detection and identification device according to any one of claims 1, 3, and 4, further comprising a turning drive device 50 that is electrically driven in the horizontal direction by 360 degrees in the mount 30. . The apparatus of claim 5, wherein the image photographing camera (60) installed to face the same axis as the detector (10) is fixedly coupled to the mount.