KR101785392B1 - Device for prevention of fires smoke and method for prevention of fires smoke using the same - Google Patents

Abstract

The present invention provides a building firefighting device having an evacuator. The building firefighting device having an evacuator comprises: a fire detection part installed in an indoor space of a building, and detecting a fire occurrence location; a human body detection part disposed on the indoor space, and detecting the presence of a survivor at the fire occurrence location; an exit path formation part calculating an exit path connecting a location of the survivor and a location of an exit of the building, when the survivor presents at the fire occurrence location; and an evacuator blocking a smoke caused by the fire from being flowing into an exit region formed with the calculated exit path. Also, the present invention provides a building firefighting method using the building firefighting device.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a disaster prevention system for buildings,

[0001] The present invention relates to a building fire prevention disaster apparatus having a smoke and a building fire prevention disaster prevention method using the same, and more particularly, The escape route connecting the escape route from the survivor location is calculated and the smoke in the escape area for forming the escape route is discharged to the outside and the smoke is prevented from flowing into the escape area The present invention relates to a building fire prevention and disaster prevention apparatus having a smoke capable of forming an air film, and a building fire prevention disaster prevention method using the same.

Generally, there are various types of fire suppression facilities, but except for special circumstances such as oil fires, electric fires, etc., fire fighting equipment using water is the most economical and effective to evolve most general fires.

A water fire fighting system requires a device that receives water from a water tank or a water supply pipe and emits it from a jetting section. To this end, a fire pump must be installed in the water fire fighting system.

A pump is a device that applies mechanical energy obtained from a driving device such as an electric motor or an internal combustion engine to a liquid or gas and transports the liquid or gas through the pipe to a high or a long distance or at a high speed.

Especially, the fire pump has been developed and developed as a structure that allows fire extinguishing agents such as water and halogen compounds to be transported through a fire hose of a fire truck or a fire pipe of a building and to be jetted at a certain pressure from a nozzle.

On the other hand, although the fire risk of a building is large, it is unlikely that a fire will actually occur. Therefore, it is very likely that the designed fire pump is not used or used once or twice during the useful life of a decade-long building.

In addition, sprinklers and the like are installed in such a manner that they are exposed to the inside of the room, and serve only to spray only the water of fire during the actual molding.

Conventionally, a fire extinguishing device can be housed in a ceiling, and when a fire occurs, it is lowered to a fire occurrence position to spray fire water, thereby suppressing the fire, and developing a facility capable of efficiently discharging the smoke generated by the fire to the outside However, there is a need to develop a ventilation technology that allows a survivor to freely escape from the smoke by checking the state of the survivor remaining in the room in real time.

A prior art document related to the present invention is Korean Patent Registration No. 10-1711046.

An object of the present invention is to provide a fire extinguishing system that detects an area where a fire has occurred when a fire occurs and calculates an escape route connecting the exit from the survivor location when there is a survivor in the detected fire area, And a fire extinguisher capable of forming an air film so as to discharge smoke from the escape region to be formed outside and to prevent smoke from flowing into the escape region, and a firefighting and disaster prevention method using the same .

In order to attain the above object, the present invention provides a building fire prevention disaster apparatus provided with smoke.

The building fire fighting and disintegrating apparatus having the smoke includes a fire sensing unit installed in an indoor space of a building and sensing a fire occurrence position; A human body sensing unit disposed in the indoor space for sensing whether a survivor is present in the fire occurrence position; An escape route forming unit for calculating an escape route connecting the location of the survivor to the location of the exit of the building when there is a survivor at the fire occurrence location; And a sidewall for blocking smoke from entering the escape region formed by the calculated escape route.

The human body detecting unit includes a camera for capturing an image of the fire occurrence position and a determiner for detecting presence or absence of the survivor in the captured image.

Wherein the ventilation part includes an air supply device for supplying pressure air, air supply pipes installed at a ceiling part of the indoor space for flowing the pressure air supplied from the air supply device, Closing valves for opening and closing the flow of the pressurized air, and a control unit for controlling the opening and closing of the pressurized air, Position information of the injection holes is set, and a controller for controlling opening and closing of the opening and closing valves.

Here, the controller controls opening and closing operations of the open / close valves to open the injection holes corresponding to positions included in the escape region using the position information of the injection holes to inject the pressure air.

Wherein the discharge pipes are provided at the bottom of the indoor space with one end exposed to the indoor space, and the discharge pipes include a pump for receiving a control signal from the controller and forcibly sucking the smoke formed in the indoor space and discharging the smoke to the outside .

Particularly, in the bottom portion, a plurality of evacuation spaces are formed.

The plurality of evacuation spaces include a predetermined size space formed at a plurality of locations of the bottom portion and a sliding door that opens and closes the space portion in response to a control signal from the controller.

A sensor for detecting the existence of the survivor is installed at the upper end of the sliding door by sensing the weight of the survivor when the fire occurs.

Wherein the controller is configured to open the space part using the sliding door when the survivor is present by the sensor to enable entry of the survivor,

After the survivor enters the space, smoke formed in the space is discharged to the outside by using an air blower installed at the bottom of the space, and the sliding door is closed.

The controller forcibly supplies oxygen to the space portion using an oxygen supply device.

In addition, concentration sensors are installed in the ceiling portion of the indoor space to measure the concentration of smoke generated due to the fire and transmit the measured concentration to the controller.

In each of the injection holes of the refractory, each of the injectors for injecting the pressurized air is provided.

Each of the injectors includes an injector body and a rotary motor for rotating the injector body.

The controller drives the rotary motor such that the measured concentration is directed to a target position that is equal to or higher than a predetermined reference concentration to rotate the injector body of each of the injectors,

Each of the auxiliary pumps installed in each of the air supply pipes is driven to inject the pressure air to the target position through the injectors so that the jetting pressure of the pressurized air is increased to a predetermined jetting pressure.

According to another aspect of the present invention, there is provided a fire detection system comprising: a fire detection step of detecting a fire occurrence position using a fire detection unit installed in an indoor space of a building; A human body detecting step of detecting the presence of a survivor at the fire occurrence position using a human body detecting unit disposed in the indoor space; An escape route forming step of using the escape route forming section to calculate an escape route connecting the position of the survivor and the position of the exit of the building when there is a survivor at the fire occurrence position; And a ventilation step of blocking the inflow of the smoke caused by the fire into the escape area formed by the calculated escape route using the smoke,

A camera for acquiring an image of the fire occurrence position in the human body detection step and a determiner for detecting presence or absence of the survivor in the captured image,

An air feeder for supplying pressure air; an air supply pipe installed at a ceiling portion of the indoor space for flowing the pressure air supplied from the air feeder; Closing valves for opening and closing the flow of the pressurized air, and a control valve for controlling the flow of the pressurized air to the indoor space, The position information of the injection holes is set, and a controller for controlling the opening and closing of the open / close valves is used,

Wherein the controller controls opening and closing operations of the opening and closing valves to open the injection holes corresponding to positions included in the escape region using the position information of the injection holes,

The control unit receives the control signal from the controller by using the discharge pipes whose ends are exposed from the bottom of the indoor space to the indoor space and the pump installed on the discharge pipes and forcibly sucks the smoke formed in the indoor space, To provide a disaster prevention method for building fire.

According to the present invention, when a fire occurs, an area where a fire has occurred is detected, and if there is a survivor in the detected fire area, an escape route connecting the exit from the survivor location is calculated and an escape route is formed It is possible to form an air film so as to discharge the smoke in the escape region to the outside and to block the inflow of the smoke into the escape region.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view showing a building-fire disaster prevention system equipped with smoke of the present invention; Fig.
FIG. 2 is a view illustrating a process of forming an escape route through the escape route forming unit according to the present invention.
3 is a perspective view showing an evacuation space according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily carry out the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Hereinafter, the term "an upper (or lower)" or a "top (or lower)" of the substrate means that any structure is disposed or arranged in any manner, as long as any structure is provided or disposed in contact with the upper surface .

Furthermore, the present invention is not limited to a configuration that does not include any other configuration between the substrate and any configuration provided or disposed on (or under) the substrate.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a building and fire prevention system provided with a smoke generator according to the present invention will be described with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view showing a building-fire disaster prevention system equipped with smoke of the present invention; Fig. FIG. 2 is a view illustrating a process of forming an escape route through the escape route forming unit according to the present invention. 3 is a perspective view showing an evacuation space according to the present invention.

1 to 3, the building fire prevention system with smoke of the present invention comprises a fire detection unit 100 installed in an indoor space 1 of a building and sensing a fire occurrence position, A human body sensing unit 200 disposed in the space 1 for sensing the presence or absence of a survivor at the fire occurrence position, and a human body detection unit 200 for detecting the location of the survivor and the exit of the building, An escape route forming unit 300 for calculating an escape route to be connected to the escape route, and a zigzag 400 for blocking smoke from entering the exit area formed by the calculated escape route.

The human body detection unit 200 includes a camera 210 for capturing an image of the fire occurrence position and a determiner 220 for detecting presence or absence of the survivor in the captured image.

The quadruple portion 400 includes an air supply device 410 for supplying pressure air and an air supply device 400 installed in the ceiling portion 2 of the indoor space 1 for flowing the pressure air supplied from the air supply device 410 The air supply pipes (420) are installed in the ceiling (2) of the indoor space (1) and are arranged in a lattice pattern. The air supply pipes are connected to the ends of the air supply pipes (420) Closing valves 440 installed on the air supply pipes 420 for opening and closing the flow of the pressurized air and a control unit 440 for controlling the positions of the injection holes 430 And a controller 450 for controlling the opening and closing of the opening / closing valves 440.

Here, the controller 450 uses the position information of the injection holes 430 to open the injection holes 430 corresponding to positions included in the escape region, Controls the opening and closing operations of the valves 440.

Discharge tubes 500, one end of which is exposed in the interior space 1, are disposed in a bottom portion 3 of the indoor space 1, and the discharge tubes 500 are connected to the controller 450, And is connected to a pump 510 for forcibly sucking the smoke formed in the indoor space 1 and discharging the smoke to the outside.

Particularly, in the bottom part 3, a plurality of evacuation space parts 600 are formed.

The plurality of evacuation spaces 600 may include a space 610 having a predetermined size formed at a plurality of positions of the bottom portion and a sliding door 640 for opening and closing the space 610 in response to a control signal from the controller 450. [ (620).

A sensor 630 is provided at the upper end of the sliding door 620 to sense the existence of the survivor by sensing the weight of the survivor when the fire occurs.

The controller 450 may open the space 610 by using the sliding door 620 driven by the linear motor 621 when the sensor 630 exists the survivor, Enabling the entry of survivors,

After the survivor enters the space, the air blower 640 installed at the bottom of the space part 610 discharges the smoke formed in the space part 610 to the outside, and the sliding door 620, Lt; / RTI >

The air blower 640 includes a plurality of exhaust holes 641 formed at the bottom of the space 610, a smoke discharge pipe 642 connected to the exhaust holes 641, And a discharge pump 643 which is installed on the discharge pipe 642 and is driven under the control of the controller 450 to discharge the smoke to the outside.

Also, the controller 450 forcibly supplies oxygen to the space portion 610 by using the oxygen supply device 650. [

The oxygen supply device includes a plurality of supply holes 651 formed at the bottom of the space 610, an oxygen supply pipe 652 connected to the supply holes 651, And a supply pump 653 driven by the control of the controller 450 to supply oxygen of the outside air to the space portion.

Although not shown in the drawings, the ceiling portion 2 of the indoor space 1 is spaced from the ceiling portion 2 to measure the concentration of smoke generated due to the fire, (Not shown) for transferring the image data to the image sensor 450.

Injectors (not shown) for injecting the pressurized air are installed in the injection holes 430 of the refractory.

Each of the injectors includes an injector body and a rotary motor for rotating the injector body.

The controller 450 may drive the rotary motor to rotate the injector body of each of the injectors such that the measured concentration is directed to a target position that is equal to or higher than a predetermined reference concentration.

It is also possible to drive each of the auxiliary pumps (not shown) provided in each of the air supply pipes 420 so that the injection pressure of the pressurized air is increased to the set injection pressure so as to be injected to the target position through the injectors .

On the other hand, in the building fire prevention method of the present invention, the building fire prevention < Desc / Clms Page number 2 >

Since the constituent numbers of the building fire fighting and disinfection apparatus having the smoke are the same as those described above, the constituent numbers will be omitted.

According to another aspect of the present invention, there is provided a fire prevention method for a building, comprising: a fire detection step of detecting a fire occurrence position using a fire detection unit installed in an indoor space of a building; A human body detecting step of detecting the presence of a survivor at the fire occurrence position using a human body detecting unit disposed in the indoor space; An escape route forming step of using the escape route forming section to calculate an escape route connecting the position of the survivor and the position of the exit of the building when there is a survivor at the fire occurrence position; And a ventilation step of blocking the inflow of the smoke due to the fire into the escape region formed by the calculated escape route using the smoke.

In the human body detection step, a camera for capturing an image of the fire occurrence position and a determiner for detecting the existence of the survivor in the captured image are used.

An air feeder for supplying pressure air; an air supply pipe installed at a ceiling portion of the indoor space for flowing the pressure air supplied from the air feeder; Closing valves for opening and closing the flow of the pressurized air, and a control valve for controlling the flow of the pressurized air to the indoor space, , Position information of the injection holes is set, and a controller for controlling the opening and closing of the opening and closing valves is used.

The controller controls opening and closing operations of the open / close valves to open the injection holes corresponding to positions included in the escape region by using the position information of the injection holes and inject the pressure air.

The control unit receives the control signal from the controller by using the discharge pipes whose ends are exposed from the bottom of the indoor space to the indoor space and the pump installed on the discharge pipes and forcibly sucks the smoke formed in the indoor space, To provide a disaster prevention method for building fire.

According to the above-described configuration and operation, in the embodiment of the present invention, when a fire occurs, the fire area is detected, and when there is a survivor in the detected fire area, An air passage may be formed to calculate the escape route and to discharge the smoke in the escape area that forms the escape route to the outside and to block the inflow of the smoke into the escape area.

Although the concrete embodiments of the building fire prevention and disaster prevention apparatus and the fire prevention and disaster prevention method provided with the smoke of the present invention have been described above, it is apparent that various modifications can be made without departing from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

It is to be understood that the foregoing embodiments are illustrative and not restrictive in all respects and that the scope of the present invention is indicated by the appended claims rather than the foregoing description, It is intended that all changes and modifications derived from the equivalent concept be included within the scope of the present invention.

1: Indoor space
100:
200: Human body detection unit
300: escape path forming part
400:

Claims (5)

A fire detection unit installed in an indoor space of the building and detecting a fire occurrence position;
A human body sensing unit disposed in the indoor space for sensing whether a survivor is present at the fire occurrence position;
An escape route forming unit for calculating an escape route connecting the location of the survivor to the location of the exit of the building when there is a survivor at the fire occurrence location; And
And a sidewall for blocking smoke from entering the escape region formed by the calculated escape route,
Wherein,
An air supply device for supplying pressure air,
Air supply pipes installed at a ceiling portion of the indoor space for flowing the pressure air supplied from the air supply unit,
Spray holes arranged in a ceiling portion of the indoor space and arranged in a lattice pattern and connected to the ends of the air supply pipes to spray the pressure air into the indoor space;
Closing valves for opening and closing the flow of the pressurized air,
And a controller for setting the position information of the injection holes and controlling opening and closing of the opening / closing valves,
The controller comprising:
Controls opening and closing operations of the opening and closing valves to open the ejection holes corresponding to positions included in the escape region and inject the pressure air using the position information of the ejection holes,
Wherein the discharge pipes are provided at the bottom of the indoor space with one end exposed to the indoor space, and the discharge pipes include a pump for receiving a control signal from the controller and forcibly sucking the smoke formed in the indoor space and discharging the smoke to the outside Connected,
In the bottom portion, a plurality of evacuation spaces are formed,
Wherein the plurality of evacuation spaces include a predetermined size space formed at a plurality of positions of the bottom portion and a sliding door that opens and closes the space portion in response to a control signal from the controller,
A sensor for detecting the existence of the survivor is installed at the upper end of the sliding door by sensing the weight of the survivor when a fire occurs,
Wherein the controller is configured to open the space using the sliding door to enable entry of the survivor when the sensor determines that the survivor exists,
After the survivor enters the room, the air formed in the space is discharged to the outside by using an air blower installed on the floor of the space, the sliding door is closed,
Wherein the controller forcibly supplies oxygen to the space portion by using an oxygen supply device.
The method according to claim 1,
The human-
A camera for acquiring an image of the fire occurrence position,
And a determiner for detecting presence or absence of the survivor in the acquired image. ≪ RTI ID = 0.0 > 18. < / RTI >
delete delete [Claim 5 is abandoned upon payment of registration fee.] A fire detection step of detecting a fire occurrence position using a fire detection unit installed in an indoor space of a building;
A human body detecting step of detecting the presence of a survivor at the fire occurrence position using a human body detecting unit disposed in the indoor space;
An escape route forming step of using the escape route forming section to calculate an escape route connecting the position of the survivor and the position of the exit of the building when there is a survivor at the fire occurrence position; And
And a ventilation step of blocking the inflow of smoke caused by the fire into the escape area formed by the calculated escape route using the smoke,
In the human body detection step,
A camera for acquiring an image of the fire occurrence position, and a determiner for detecting presence or absence of the survivor in the captured image,
In this step,
An air supply device for supplying pressure air,
Air supply pipes installed at a ceiling portion of the indoor space for flowing the pressure air supplied from the air supply unit,
Spray holes arranged in a ceiling portion of the indoor space and arranged in a lattice pattern and connected to the ends of the air supply pipes to spray the pressure air into the indoor space;
Closing valves for opening and closing the flow of the pressurized air,
Wherein a position information of the injection holes is set and a controller for controlling the opening and closing of the opening and closing valves is used,
The controller comprising:
Controls opening and closing operations of the opening and closing valves to open the ejection holes corresponding to positions included in the escape region and inject the pressure air using the position information of the ejection holes,
The control unit receives the control signal from the controller by using the discharge pipes whose ends are exposed from the bottom of the indoor space to the indoor space and the pump installed on the discharge pipes and forcibly sucks the smoke formed in the indoor space, Lt; / RTI >
In the bottom portion, a plurality of evacuation spaces are formed,
Wherein the plurality of evacuation spaces include a predetermined size space formed at a plurality of positions of the bottom portion and a sliding door that opens and closes the space portion in response to a control signal from the controller,
A sensor is installed at the upper end of the sliding door to detect the presence of the survivor by detecting the weight of the survivor when a fire occurs,
Wherein the controller is configured to open the space using the sliding door to enable entry of the survivor when the sensor determines that the survivor exists,
After the survivor enters the room, the air formed in the space is discharged to the outside by using an air blower installed on the floor of the space, the sliding door is closed,
Wherein the controller forcibly supplies oxygen to the space portion using an oxygen supply device.

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