KR101638303B1 - spontaneousness rescue apparatus for vehicle - Google Patents

Abstract

Provided is a multi-purpose CCTV monitoring system in which a monitoring function to photograph and monitor surroundings, and a fire detection function to detect fire are implemented in an integrated manner; thereby facilitating installation and operation. The present invention relates to a CCTV monitoring system comprising: a plurality of fire detection CCTV cameras (100) configured to photograph a specific location; and a monitor (M) connected to the CCTV cameras (100) over a network (N). Each of the CCTV cameras (100) comprise: a body (10) installed under a ceiling of the specific location; a camera unit (20) installed in the body (10) in an integrated manner, and configured to photograph the surroundings; first, second, and third infrared detection units (30, 40, 50) installed around the body (10), detecting infrared rays emitted in a corresponding direction, and generating respective temperature signals corresponding to the wavelengths of the infrared rays; a comparison unit (60) which compares the temperature signals generated by the respective first, second, and third infrared detection units (30, 40, 50); and a fire signal generation unit (70) which generates a fire signal when a difference between a temperature corresponding to one of the temperature signals compared by the comparison unit (60) and temperatures corresponding to other two temperature signals is equal to or greater than a preset comparison value, or when temperatures corresponding to the three temperature signals are equal to or greater than a preset absolute value.

Description

[0001] Spontaneousness rescue apparatus for vehicle [

The present invention relates to a multi-purpose CCTV monitoring system, and more particularly, to a multi-purpose CCTV monitoring system capable of not only monitoring but also fire detection.

Generally, a CCTV monitoring system is composed of a CCTV camera on a ceiling of a factory or a building, and a monitor installed at a remote place through the CCTV camera and a wired / wireless network, and can monitor a plant or a building through a monitor from a remote place. This CCTV monitoring system is getting more popular as the construction price is lowered.

On the other hand, in factories or buildings, fire detectors are mandatory to detect fire situations. Such fire detectors include a differential fire detector that detects the changing heat, a warm fire detector that operates when the ambient temperature is set to a predetermined temperature Detectors, and smoke detectors that detect smoke.

The differential fire extinguisher is operated when the ambient temperature rises above a certain rate per unit time, typically when the temperature rise per minute occurs above 15 ° C. The temperature-controlled fire detector operates using a bimetallic bending property at a given temperature, typically 70 ° C. Smoke-type smoke detectors operate when smoke above a certain concentration occurs.

The above-mentioned differential smoke detectors or warm-temperature fire detectors must be legally installed when a building is newly constructed and expanded. A prior art related thereto is disclosed in Japanese Patent Laid-Open No. 10-2009-0082800 under the name fire detection system.

However, a heat-activated fire detector is a situation in which the fire is quite advanced when the fire detector is actually activated, as the fire situation in the monitoring area is considerably advanced and the ambient air temperature is significantly higher than usual. The proper response was delayed and many property damage occurred.

In addition, it was difficult to know exactly the cause of the fire when a fire occurred. In this case, there was a problem that there was a lot of difficulty in estimating the insurance amount from the fire insurance company.

It is an object of the present invention to provide a multi-purpose CCTV monitoring system which is easy to install and operate by integrating a surveillance function for shooting and monitoring the surroundings and a fire detection function for detecting a fire, The purpose is to provide.

It is another object of the present invention to provide a multi-purpose CCTV monitoring system capable of promptly detecting an initial situation in which a fire occurs, enabling rapid response, and enabling fire monitoring in a wide area.

It is still another object of the present invention to provide a multi-purpose CCTV monitoring system capable of identifying the cause of a fire by selectively photographing a point where a fire occurs.

In order to achieve the above object, a multi-purpose CCTV monitoring system according to the present invention includes a plurality of fire detection CCTV cameras 100 for capturing a specific place, a plurality of CCTV cameras 100 and a network N, 1. A CCTV monitoring system comprising a monitor (M)
The CCTV camera 100 includes a body 10 installed on a ceiling of a specific place; A camera module 21 for taking an image of the surroundings, a first rotation part 22 for rotating the camera module 21 in the forward and backward directions with respect to the body part 10, A camera unit 20 having a second rotation unit 23 for rotating the first rotation unit 22 with respect to the body 10 by 360 degrees; Three first, second and third infrared ray detecting units 30 (see FIG. 1) for detecting infrared rays radiated in a specific direction and generating temperature signals corresponding to the infrared ray wavelengths, respectively, 40) (50); A comparing unit 60 for comparing the temperature signals generated by the first, second and third infrared ray detecting units 30, 40 and 50; If the temperature corresponding to one temperature signal among the temperature signals compared by the comparator 60 is different from the temperature corresponding to the other two temperature signals by a predetermined comparison set value or more, A fire signal generating unit (70) for generating a fire signal for operating a ceiling sprinkler when a preset absolute setting value or more is reached; And the first and second rotary parts 22 and 23 are operated so that the camera module 21 can be directed to the infrared ray sensing part side that generates a temperature signal corresponding to the highest temperature when the fire signal is generated, And a photographing angle variable signal generating section (80) for generating a signal for varying the photographing angle of the camera module (21); The first, second and third infrared detectors 30, 40 and 50 are movably supported around the base 11 of the body part so that the first, second and third infrared detectors 30, And a guide rail 15 is installed in an annular shape so that the infrared ray sensors 31, 41 and 51 can be symmetrically positioned or oriented toward one side of the body 10.

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The alarm signal generator 90 may further include an alarm signal generator 90 for generating an alarm signal when the fire signal is generated.

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The first infrared ray sensor 30 may include a first infrared ray sensor 31 for detecting infrared rays to be irradiated and a second infrared ray sensor 31 for detecting only infrared rays of a specific latitude range A pair of first sidewalls 32 formed on both sides of the first infrared sensor 31 and a first inclined bottom end supporting the first infrared sensor 31 obliquely between the pair of first sidewalls 32 33); The second infrared ray sensor 40 includes a second infrared ray sensor 41 for detecting infrared rays that are moved in a direction different from the direction of the first infrared ray detector 30, A pair of second sidewalls 42 formed on both sides of the second infrared sensor 41 and a second infrared sensor 41 between the pair of second sidewalls 42 And a second ramp end (43) supporting the ramp at an angle; The third infrared ray sensing unit 50 includes a third infrared ray sensor 51 for sensing infrared rays to be emitted from the first and second infrared ray sensing units 30 and 40, (51) formed on both sides of the third infrared sensor (51) so that only the infrared rays of a specific latitude range can be irradiated to the third infrared ray sensor (51) and the third infrared ray sensor And a third inclined base end 53 supporting the infrared sensor 51 obliquely.

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According to the present invention, it is possible to install and operate easily by integrating a surveillance function for shooting and monitoring the surroundings and a fire detection function for detecting a fire, which is installed in a specific place of a building or a large building.

In addition, it detects fire immediately and generates a fire signal. Therefore, it is possible to cope immediately in the initial condition of fire, and it is possible to monitor fire in a wide area by employing three first, second and third infrared ray sensing units.

The camera module 21 tracks and records the point where the fire occurred, thereby identifying the cause of the fire.

1 is a schematic block diagram of a multi-purpose CCTV monitoring system according to the present invention;
FIG. 2 is an exploded perspective view illustrating the CCTV camera of FIG. 1,
3 is a block diagram illustrating the configuration of the CCTV camera of FIG. 2;
FIG. 4 is a plan view of the body of the CCTV camera of FIG. 2,
5 is a sectional view taken along the line VV 'in Fig. 4,
6 is a view for explaining application of a guide rail for moving the first, second and third infrared ray sensing units to the CCTV camera of FIG. 2;

Hereinafter, a multi-purpose CCTV monitoring system according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic block diagram of a multi-purpose CCTV monitoring system according to the present invention.

The multi-purpose CCTV monitoring system according to the present invention includes a plurality of CCTV cameras 100 for photographing a specific place such as a factory or a large building, a monitor (not shown) connected to the plurality of CCTV cameras 100 via a network N M), and the monitor M provides visual information to the monitoring personnel within the monitoring center. At this time, the CCTV camera 100 has the same configuration, and one CCTV camera will be described as an example for easy explanation.

FIG. 2 is an exploded perspective view illustrating the CCTV camera of FIG. 1, FIG. 3 is a block diagram of the CCTV camera of FIG. 2, and FIG. 4 is a plan view of the body of the CCTV camera of FIG. FIG. 5 is a sectional view taken along the line V-V 'of FIG. 4, and FIG. 6 is a view for explaining the application of a guide rail for moving the first, second and third infrared detectors to the CCTV camera of FIG.

As shown in the figure, the CCTV camera 100 constituting the multi-purpose CCTV monitoring system according to the present invention includes a body 10 installed on a ceiling R at a specific place such as a building or a factory; A camera unit (20) integrated with the body part (10) for photographing the surroundings; Three first, second and third infrared ray detecting units 30 and 40 installed around the body 10 for detecting infrared rays radiated from the corresponding direction and generating temperature signals corresponding to the infrared rays, (50); A comparison unit 60 for comparing the temperature signals generated by the first, second and third infrared ray detection units 30, 40, and 50; If the temperature corresponding to one temperature signal among the temperature signals compared by the comparator 60 is different from the temperature corresponding to the other two temperature signals by a predetermined comparison set value or more, A fire signal generating unit (70) for generating a fire signal when a predetermined absolute set value or more is reached; A shooting angle variable signal generator 80 for generating a signal for varying the shooting angle of the camera unit 20 so as to face the infrared ray sensing unit side that generates a temperature signal corresponding to the highest temperature when the fire signal is generated, ; And an alarm signal generating unit (90) for generating an alarm signal when a fire signal is generated.

As shown in Fig. 2, the body 10 is provided on a ceiling of a plant or a large building, which is a room to be monitored. The body 10 includes a base 11 having a first coupling end 11a formed at its edge, And a dome-shaped cover 12 formed with a second coupling end (not shown) coupled to the end 11a. The first coupling end 11a is formed by forming a thread on the edge side of the base 11 and the second coupling end is formed on the inner circumferential surface of the cover 12 by a plurality of And a thread is formed. The cover 12 is made of a transparent material such as transparent plastic or polycarbonate which transmits infrared light so that infrared rays can be radiated from the outside to the first, second and third infrared ray detecting units 30, 40 and 50 .

The camera unit 20 is connected to a remote monitor M via a network such as the Internet and an administrator monitors an image photographed by the camera unit 20 via the monitor M. [

In addition, when the fire occurs, the camera unit 20 can change the shooting angle to the side where the fire has occurred. 2 and 4, the camera unit 20 includes a camera module 21 for photographing the surroundings, a camera module 21 for rotating the camera module 21 in the front-rear direction with respect to the body 10, And a second rotation part 23 that rotates the first rotation part 22 by 360 ° with respect to the body part 10. With this structure, by the operation of the first and second rotating parts 22 and 23, the camera module 21 can monitor and photograph all areas.

For reference, the photographing angle of the camera module 21 employed in the CCTV camera is generally about 60 degrees, and even if there is the wide angle function, it does not exceed 90 degrees. Therefore, the photographing angle of the camera module 21 is limited, and thus, the first and second rotating parts 22 and 23 are employed to photograph a wide area.

The first, second and third infrared ray detecting units 30, 40 and 50 detect the infrared ray generated at a point where a fire occurs and are installed on the base 11 of the body 10.

All the materials generate infrared rays of the corresponding wavelength depending on the temperature. Therefore, the infrared wavelength generated at the point where the fire occurs and the infrared wavelength generated at the place where the fire is not generated are different, and when the fire occurs, Is immediately different.

The present invention employs the first, second and third infrared ray detecting units 30, 40, and 50 for independently detecting infrared rays in a specific direction, thereby enabling reliable fire detection as well as specifying a point at which a fire occurs .

4, the first infrared ray sensor 30 includes a first infrared ray sensor 31 for detecting infrared rays to be irradiated and a second infrared ray sensor 31 for detecting only infrared rays of a specific latitude range A pair of first sidewalls 32 formed on both sides of the first infrared sensor 31 and a first inclined bottom end supporting the first infrared sensor 31 obliquely between the pair of first sidewalls 32 33).

4, the second infrared ray detector 40 includes a second infrared ray sensor 41 for detecting an infrared ray to be moved in a direction different from that of the first infrared ray detector 30, A pair of second side walls 42 formed on both sides of the second infrared ray sensor 41 so that only the infrared ray of a specific latitude range can be irradiated to the second infrared ray sensor 41 and the second infrared ray sensor 41 between the pair of second side walls 42 41) at an oblique angle.

4, the third infrared ray detector 50 includes a third infrared ray sensor 51 for detecting an infrared ray to be moved in a direction different from that of the first and second infrared ray detectors 30 and 40, A pair of third side walls 52 formed on both sides of the third infrared ray sensor 51 and a pair of second side walls 52 formed between the pair of third side walls 52 so that the third infrared ray sensor 51 can irradiate only infrared rays of a specific latitude range And a third inclined end portion 53 supporting the third infrared ray sensor 51 obliquely.

The first, second and third infrared sensors 31, 32, 43, and 53 are disposed on the first, second and third side walls 32, 42, 52, (41) 51 to detect the infrared ray.

An annular guide rail 15 for independently and independently supporting the first, second, and third infrared detectors 30, 40, and 50 may be installed around the base 11 of the body part. In this case, by moving the first, second and third infrared ray detecting units 30, 40 and 50 along the guide rails 15, the first, second and third infrared ray sensors 31, 41, And can be positioned symmetrically with respect to the portion 10, or positioned toward one side. By varying the positions of the first, second and third infrared detectors 30, 40 and 50, the fire monitoring area can be varied. For example, when the angle formed by the first, second, and third infrared ray detecting units 30, 40, and 50 is about 180 ° with respect to the center of the body, the first, second, and third infrared ray detecting units 30 (40) (50), it is possible to turn the fire surveillance area forward to about 180 degrees.

The comparator 60 compares the temperature signals generated in the first, second and third infrared detectors 30, 40 and 50 in real time.

The fire signal generating unit 70 generates a fire signal when the temperature corresponding to one temperature signal among the temperature signals compared by the comparing unit 60 is different from the temperature corresponding to the remaining two temperature signals by a value equal to or larger than the comparison set value, And generates a fire signal when the temperatures corresponding to the signals become equal to or higher than the absolute set value.

For example, when a fire occurs in a direction corresponding to the first infrared ray detector 30, the temperature of the fire point is higher than the ambient temperature, so infrared rays having wavelengths different from those of the surrounding are generated. The infrared ray generated at the point of fire occurrence is irradiated to the first infrared ray detection unit 30 and the infrared ray at the point where no fire is generated is irradiated to the second and third infrared ray detection units 40 and 50, The temperature signals generated in the first, second and third infrared ray detecting units 30, 40, and 50 are compared with each other in the comparing unit 60. At this time, the temperature difference generated between the temperature corresponding to the temperature signal generated by the first infrared ray detection unit 30 and the temperature corresponding to the temperature signal generated by the second and third infrared ray detection units 40 and 50, Value, for example, equal to or greater than 40 ° C., the fire signal generating unit 70 determines that a fire has occurred and generates a fire signal.

Or fire is generated at the lower side of the CCTV camera 100, infrared rays generated at the fire point may be irradiated to all of the first, second, and third infrared ray detection units 30, 40, and 50. In this case, the first, second and third infrared detectors 30, 40 and 50 generate three temperature signals, and the temperature difference between the temperatures corresponding to these three temperature signals is 40 ° C The fire signal generating unit 70 can not determine that a fire has occurred. In order to solve this problem, the temperatures corresponding to the three temperature signals generated in the first, second and third infrared detectors 30, 40 and 50 are set to an absolute set value, for example, The fire signal is generated. These fire signals are sent to a receiver (not shown) to be used for fire monitoring or as a signal to activate a ceiling sprinkler (not shown).

That is, when the temperature difference corresponding to one and two temperature signals among the temperature signals generated in the first, second, and third infrared ray detection units 30, 40, 50 is equal to or greater than the comparison set value, It is determined that a fire has occurred when the temperature corresponding to the temperature signal generated in all of the three infrared ray detection units 30, 40, and 50 is equal to or greater than the absolute set value.

As a reference, since a conventional differential type detector or a warm temperature type detector generates a fire signal when ambient air is heated to a set temperature or higher in the event of a fire, when a fire signal is actually generated, a fire is considerably advanced, In many cases.

On the other hand, according to the present invention, infrared rays irradiated to the first, second and third infrared ray detection units 30, 40, 50 are independently sensed and compared with each other to determine whether or not the fire is present. Compared to a fire detector, it can instantly detect when a fire occurs and respond accordingly in the early stages of a fire.

Although not described in the present invention, an amplifying circuit for amplifying a temperature sensing signal generated in the first, second and third infrared ray detecting units 30, 40 and 50 and a microcomputer for performing a comparison operation are built in to be.

When the fire signal is generated, And generates a signal for varying the photographing angle of the camera unit 20 so as to face the infrared sensor side that generates the temperature signal corresponding to the highest temperature.

For example, when a fire occurs in a direction corresponding to the first infrared ray detection unit 30 and a fire generation signal is generated, the temperature of the first infrared ray detection unit 30 is detected by the second and third infrared ray detection units 40, Is higher than the temperature on the side of the fire detector 50, it is possible to specify the point where the fire occurred. In this case, the photographing angle variable signal generating unit 80 operates the first and second rotating units 22 and 23 so that the camera module 21 faces the first infrared ray detecting unit 30, It is possible to photograph the generated point, and the captured image can be used to identify the cause of the fire.

The alarm signal generating unit 90 generates an alarm signal such as a warning sound or warning light when a fire signal is generated so that the surrounding people can respond to the fire situation immediately. To this end, a speaker 91 for generating a warning sound and a high-luminance LED warning light 92 for generating warning light periodically or aperiodically are provided outside the body 10.

Thus, the multi-purpose CCTV monitoring system of the present invention can be easily installed and operated by integrating a surveillance function for shooting and monitoring the surroundings and a fire detection function for detecting a fire, which is installed in a specific place of a building or a large building This is possible.

Also, since a fire signal is generated by detecting a fire immediately, it is possible to take immediate action in the initial state of fire, and by adopting the three first, second and third infrared ray detecting units 30, 40 and 50, Fire monitoring of the area is possible.

The camera module 21 tracks and records the point where the fire occurred, thereby identifying the cause of the fire.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

100 ... CCTV camera
10 ... body part 11 ... base
11a ... First coupling end 12 ... Cover
20 ... camera part 21 ... camera module
22 ... first rotating portion 23 ... second rotating portion
30, 40, 50, ..., 2,3 infrared ray detecting units 31, 41, 51 ... first, second and third infrared ray sensors
32, 42, 52 ... first, second and third sidewalls 33, 43, 53 ... first,
60 ... comparator 70 ... fire signal generator
80: photographing angle variable signal generating unit 90: alarm signal generating unit

Claims (6)

There is provided a CCTV monitoring system including a plurality of fire detection CCTV cameras 100 for photographing a specific place and a monitor M connected to the plurality of CCTV cameras 100 through a network N, (100)
A body part 10 installed on a ceiling of a specific place;
A camera module 21 for taking an image of the surroundings, a first rotation part 22 for rotating the camera module 21 in the forward and backward directions with respect to the body part 10, A camera unit 20 having a second rotation unit 23 for rotating the first rotation unit 22 with respect to the body 10 by 360 degrees;
Three first, second and third infrared ray detecting units 30 (see FIG. 1) for detecting infrared rays radiated in a specific direction and generating temperature signals corresponding to the infrared ray wavelengths, respectively, 40) (50);
A comparing unit 60 for comparing the temperature signals generated by the first, second and third infrared ray detecting units 30, 40 and 50;
If the temperature corresponding to one temperature signal among the temperature signals compared by the comparator 60 is different from the temperature corresponding to the other two temperature signals by a predetermined comparison set value or more, A fire signal generating unit (70) for generating a fire signal for operating a ceiling sprinkler when a preset absolute setting value or more is reached; And
When the fire signal is generated, the first and second rotation units 22 and 23 are operated so that the camera module 21 can be directed to the infrared sensor unit side for generating a temperature signal corresponding to the highest temperature, And a photographing angle variable signal generating section (80) for generating a signal for varying the photographing angle of the module (21);
The first, second and third infrared detectors 30, 40 and 50 are movably supported around the base 11 of the body part so that the first, second and third infrared detectors 30, And guide rails 15 which are symmetrically positioned or oriented toward one side of the body portion 10 are annularly provided on the body portion 10 in a state in which the three infrared sensors 31, Multipurpose CCTV monitoring system. delete delete The method according to claim 1,
Further comprising an alarm signal generator (90) for generating an alarm signal when the fire signal is generated. The method according to claim 1,
The first infrared ray sensor 30 includes a first infrared ray sensor 31 for detecting infrared rays to be irradiated, a first infrared ray sensor 31 for irradiating only infrared rays of a specific latitude range, A pair of first sidewalls 32 formed on both sides of the first sidewall 32 and a first inclined edge 33 supporting the first infrared sensor 31 obliquely between the pair of first sidewalls 32 ;
The second infrared ray sensor 40 includes a second infrared ray sensor 41 for detecting infrared rays that are moved in a direction different from the direction of the first infrared ray detector 30, A pair of second sidewalls 42 formed on both sides of the second infrared sensor 41 and a second infrared sensor 41 between the pair of second sidewalls 42 And a second ramp end (43) supporting the ramp at an angle;
The third infrared ray sensing unit 50 includes a third infrared ray sensor 51 for sensing infrared rays to be emitted from the first and second infrared ray sensing units 30 and 40, (51) formed on both sides of the third infrared sensor (51) so that only the infrared rays of a specific latitude range can be irradiated to the third infrared ray sensor (51) and the third infrared ray sensor And a third inclined end (53) for supporting the infrared sensor (51) obliquely.
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