KR101710949B1 - Apparatus for fire fighting in building - Google Patents

Abstract

The present invention relates to a fire suppression device, which installs a separate fire suppression device for suppressing a fire in a plurality of specific spaces inside a building in case of fire. Even if a problem occurs in a storage container which stores fire extinguishing substance necessary for the entire building, or in a transfer tube which transfers the fire extinguishing substance to be entirely connected to the inside of the building. The present invention provides the fire suppression device capable of spraying the fire extinguishing substance in the specific space.

Description

[0001] Apparatus for fire fighting in building [0002]

FIELD OF THE INVENTION The present invention relates to a fire suppression device for a building, and more particularly, to a fire suppression device in a specific space inside a building capable of prematurely suppressing a fire generated in a specific space in a building.

Recently, there have been frequent occurrences of fire in a building leading to large-scale human accidents.

This is because, in the case of a building with a large structure, even if a fire occurs, the recognition of the fire is delayed, and the path of evacuation is varied, so that a panic condition occurs in which a large number of people are moved at once.

Of course, after the large-scale disaster, many publicity is provided to educate and educate safety rules. In the case of newly built buildings, various fire extinguishing equipment is prepared for fire.

However, in most buildings, these fire extinguishers are still vulnerable to fire because they are often simply equipped with fire detectors and sprinklers.

On the other hand, in the case of a sprinkler installed in a building, the extinguishing material is transmitted to the sprinkler through the water supply line which is totally connected to the building. If some of the water supply lines are broken, the extinguishing material is not transmitted to a part of the sprinkler There is a problem.

In addition, when one reservoir storing extinguishing materials is disposed in the building, the extinguishing material contained in the reservoir is supplied to all the sprinklers in the building. In this case, there is a problem that the extinguishing material can not be supplied to some sprinklers through the water supply line .

Further, when a sprinkler installed in a specific space provided with important facilities or devices among the buildings can not spray the extinguishing material due to the above-described problems, a problem may arise and a countermeasure is needed.

Korean Patent Publication No. 10-2011-0044370

Disclosure of the Invention The present invention has been conceived to solve the above-mentioned problems, and it is an object of the present invention to provide a fire suppression device for entering a fire in a plurality of specific spaces inside a building, Or if there is a problem with the transport pipe that transfers the extinguishing material as a whole to the inside of the building. It is possible to provide a fire suppression device capable of injecting a fire extinguishing material into a specific space.

According to an embodiment of the present invention, there is provided a fire suppressing apparatus for suppressing a fire in a plurality of specific spaces inside a building, A first storage portion 810 and a second storage portion 820 in which a first fire extinguishing substance and a second fire extinguishing substance sprayed through the plurality of sprinklers 300 are respectively received, , At least one of the first extinguishing material and the second extinguishing material is supplied from at least one of the first accommodating portion 810 and the second accommodating portion 820 to the at least one of the plurality of sprinklers 300 A first pump 100 for supplying a first extinguishing substance and a second extinguishing substance, at least one of a first extinguishing substance and a second extinguishing substance from at least one of the first accommodating section 810 and the second accommodating section 820, One is supplied, The sprinklers (320, 340) except for the sprinklers (310, 330) to which the first and second extinguishing materials are supplied by the first pump (100) among the several sprinklers (300) The first pump 100, the second pump 200, the plurality of sprinklers 300, the first receiving portion 810, and the second receiving portion 810. The second pump 200 supplies the first and second digesting materials, And a solenoid valve (500, 600) disposed on a flow path between the first pump (100), the second pump (200), and the solenoid valve (500, 600) Wherein the first pump 100 and the second pump 200 are configured to receive at least one of the motor 110, the first extinguishing material, and the second extinguishing material, A cylinder (120), a cylinder (120), and a cylinder A first piston 141 reciprocating linearly in the cylinder 120 based on rotation of the first ball screw 131 and the second ball screw 132 and the first ball screw 131 and the second ball screw 132, And the second ball screw 132 and the second ball screw 132 rotate on the same axis and the first pump 100 and the second pump 200 rotate At least one of the first extinguishing material and the second extinguishing material accommodated in the cylinder 120 is connected to a sprinkler in fluid communication with one side of the cylinder 120 among the plurality of sprinklers 300, Or at least one of the first extinguishing material and the second extinguishing material is supplied to a sprinkler in fluid communication with the other side of the cylinder (120), and the first pump (100) and the second pump (200) And the control unit controls the plurality of detection sensors disposed in the plurality of specific spaces A fire state determination unit 1200 for determining whether or not a fire has occurred based on the fire information collected by the fire sensing unit 1100 and analyzing the type of fire based on the fire information collected by the fire sensing unit 1100, (1300) for driving a fire fighting apparatus installed in the plurality of specific spaces based on information analyzed and determined by the fire control unit (1200), and the fire fighting apparatus control unit (1300) And drives the motor 110 and the solenoid valve based on the detected fire occurrence and the type of fire.

The fire suppression device is provided with four sprinklers including a first sprinkler 310, a second sprinkler 320, a third sprinkler 330 and a fourth sprinkler 340, A first flow path 410 and a third flow path 430 for connecting the other side with the first sprinkler 310 and the third sprinkler 330, A second flow path 420 and a third flow path 440 connecting the first sprinkler 320 and the fourth sprinkler 340. The first flow path 410, the second flow path 420, The first solenoid valve 610, the second solenoid valve 620, the third solenoid valve 630 and the fourth solenoid valve 640 for opening and closing the flow path are respectively connected to the first and second solenoid valves 430 and 440, Respectively.

A first cross flow path 710 for movement of extinguishing material between the first sprinkler 310 and the fourth sprinkler 340 and a second cross flow path 710 for moving the extinguishing material between the second sprinkler 320 and the third sprinkler 330 And a second cross flow path 720 for movement of the second cross flow path 720.

A first auxiliary valve 730 disposed on the first cross flow path 710 and a second auxiliary valve 740 disposed on the second cross flow path 720.

The first pump 100 or the second pump 200 may further include restoring means 150 for supporting at least one of the first piston 141 and the second piston 142.

According to the embodiment of the present invention, even if fire extinguishing material in the storage is exhausted or fire damage occurs in the transfer pipe in which the fire extinguishing material is moved, Since the sprinkler can spray the extinguishing material, it is possible to prevent damage to important facilities and devices.

1 is a circuit diagram of an embodiment of a fire suppression device (hereinafter referred to as 'this device') in a specific space inside a building according to the present invention.
Figure 2 is a circuit diagram for another embodiment of the present apparatus.
Fig. 3 is a plan view of the pump in this apparatus, and Fig. 4 is a sectional view taken along the line AA in Fig.
5 and 6 are circuit diagrams for explaining the flow of extinguishing material according to a situation in an embodiment of the present apparatus.
Figs. 7 and 8 are circuit diagrams for explaining the flow of extinguishing material according to a situation in another embodiment of the present apparatus. Fig.
9 is a block diagram showing a main configuration of the control unit in the apparatus.
10 to 12 are detailed block diagrams of the main configuration of Fig.

Hereinafter, the configuration and operation according to the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description with reference to the accompanying drawings, the same reference numerals denote the same elements regardless of the reference numerals, and redundant description thereof will be omitted. The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

Hereinafter, one embodiment of the present apparatus will be described with reference to FIG. 1 is a circuit diagram for one embodiment of the present apparatus.

Referring to FIG. 1, the apparatus is for suppressing a fire in a plurality of specific spaces inside a building, and includes a plurality of sprinklers 300, a first receiving portion 810, a second receiving portion 820, 1 pump 100, a second pump 200, solenoid valves 500 and 600, and a control unit

The sprinkler 300 serves to extinguish a flame generated in a facility or an apparatus disposed in a specific space by spraying a fire extinguishing material into a plurality of specific spaces inside the building.

In particular, a plurality of sprinklers may be provided in one specific space, and one or more sprinklers may be provided in a plurality of specific spaces. Hereinafter, as shown in FIG. 1, four sprinklers, that is, a first sprinkler 310, The second sprinkler 320, the third sprinkler 330, and the fourth sprinkler 340 will be described.

The first accommodating portion 810 and the second accommodating portion 820 are all configured to accommodate extinguishing materials, and it is preferable to accommodate extinguishing materials of different components depending on the kind of the fire.

For example, the first accommodating portion 810 accommodates extinguishing materials effective for extinguishing electric fires, and the second accommodating portion 820 accommodates extinguishing materials effective for general fire extinguishing.

That is, when the kind of fire is confirmed by a control unit to be described later, the control unit controls the first pump 100 and the second pump 200 to be described later, at least one of the first storage unit 810 and the second storage unit 820 It is preferable to control the solenoid valves 550 and 560 connected to the first accommodating part 810 and the second accommodating part 820 so that the extinguishing material accommodated in the first accommodating part 810 and the second accommodating part 820 can be supplied.

The first pump 100 receives at least one of the first extinguishing material and the second extinguishing material from at least one of the first accommodating part 810 and the second accommodating part 820, A bi-directional linear pump driven by a motor 110. The bi-directional linear pump is a bi-directional linear pump that performs a function of supplying a first extinguishing material and a second extinguishing material to at least one of them.

The second pump 200 receives at least one of the first extinguishing material and the second extinguishing material from at least one of the first accommodating part 810 and the second accommodating part 820, The first and second extinguishing materials are supplied to at least one of the sprinklers 320 and 340 except for the sprinklers 310 and 330 to which the first extinguishing material and the second extinguishing material are supplied by the first pump 100, Directional linear pump driven by a motor 110. The bi-directional linear pump is a bi-directional linear pump.

A flow path 300 for the movement of extinguishing material is formed between the first pump 100 and the plurality of sprinklers 200 and between the second pump 200 and the plurality of sprinklers 300.

1, a first flow path 410 is formed between one side of the first pump 100 and the first sprinkler 310, and the other side of the first pump 100 and the third sprinkler 330 A third flow path 430 is formed.

A second flow path 420 is formed between one side of the second pump 200 and the second sprinkler 320 and a fourth flow path 420 is formed between the other side of the second pump 200 and the fourth sprinkler 340. [ 440) are formed.

The first solenoid valve 610 and the second solenoid valve 610 for opening and closing the flow path respectively are connected to the first flow path 410, the second flow path 420, the third flow path 430 and the fourth flow path 440, 620, a third solenoid valve 630, and a fourth solenoid valve 640, respectively.

1, one side of the flow path communicating with the first accommodating portion 810 and the first pump 100 and the second pump 200 are connected to the first accommodating portion 810 and the second accommodating portion 810, And a sixth flow path branched from the other side of the fifth flow path may be formed, the sixth flow path may be connected to the first pump 100, the seventh flow path may be connected to the second pump 200).

At this time, solenoid valves (550, 510, 520) for controlling the movement of the first extinguishing material may be respectively disposed in the fifth, sixth and seventh channels.

Likewise, a flow path may be formed in fluid communication with the second accommodating portion 820 and the first pump 100 and the second pump 200, respectively. As shown in FIG. 1, one side of the second accommodating portion 820 And a ninth and a tenth flow paths branched from the other side of the eighth flow path may be formed, the ninth flow path may be connected to the first pump 100, the tenth flow path may be connected to the second And may be connected to the pump 200.

At this time, solenoid valves 560, 530, and 540 that control the movement of the second extinguishing material may be respectively disposed in the eighth, ninth, and tenth flow paths.

Each of the solenoid valves mentioned above is opened and closed based on the control of a control unit to be described later, so that the flow of the extinguishing material in each flow passage can be controlled.

Hereinafter, another embodiment of the present apparatus will be described with reference to FIG. 2 is a circuit diagram of another embodiment of the present apparatus.

As shown in FIG. 2, another embodiment of the present apparatus further includes a first cross flow path 710 and a second cross flow path 720 in comparison with an embodiment of the present apparatus shown in FIG.

Specifically, the first cross flow path 710 is a flow path formed between the first sprinkler 310 and the fourth sprinkler 340 so that the extinguishing material can move, and the second cross flow path 720 is connected to the second sprinkler 320 And the third sprinkler (330).

The first cross flow path 710 and the second cross flow path 720 can transmit the sprinkler-side extinguishing material that does not require the spraying of the extinguishing material to the sprinkler side requiring spraying of the extinguishing material. I will.

At least one of the first cross flow path 710 and the second cross flow path 720 may be provided with an auxiliary valve for controlling the movement of the fluid. The first cross flow path 710 and the second cross flow path 720 It is preferable that the first and second auxiliary valves 730 and 740 are disposed in the first and second auxiliary valves 730 and 740, respectively.

Hereinafter, the pump 100 and the pump 200 will be described in more detail with reference to FIGS. 2 and 3. Fig. 3 is a plan view of the pump in this apparatus, and Fig. 4 is a cross-sectional view taken along line A-A in Fig.

The pumps 100 and 200 of the apparatus are cylinder type linear pumps driven by a motor 110 and specifically include a motor 110, a cylinder 120, a first ball screw 131, 2 ball screw 132, a first piston 141, and a second piston 142, as shown in FIG.

The first ball screw 131 and the second ball screw 132 are disposed on one side and the other side of the cylinder 120 and rotate in the cylinder 120 based on the driving of the motor 110, The piston 141 and the second piston 142 make a linear reciprocation in the cylinder 120 based on the rotation of the first ball screw 131 and the second ball screw 132.

Specifically, the first ball screw 131 and the second ball screw 132 are formed with threads on the outer circumferential surface thereof, and the first ball screw 131 and the second ball screw 132 are disposed to correspond to the first ball nut 131 The first ball screw 131 and the second ball screw 132 are formed on the inner circumferential surface of the second ball nut 181 and the second ball nut 182 so that the first ball screw 131 and the second ball screw 132 are engaged with the first ball nut 181, And the nut 182 are screwed together.

When the first ball screw 131 and the second ball screw 132 are rotated by the motor 110, the first ball nut 181 and the second ball nut 182 are rotated in the direction of the length of the cylinder 120 The first piston 141 and the second piston 142 which are supported by the first ball nut 181 and the second ball nut 182 are reciprocated in the cylinder 120, .

The first ball screw 131 and the second ball screw 132 rotate on the same axis. Specifically, the shaft for transmitting the rotational force of the motor 110 is connected to the first ball screw 131 and the second ball screw 132, (132).

The first ball screw 131 and the second ball screw 132 rotate at the same speed.

When the first ball screw 131 and the second ball screw 132 are rotated in one direction by the driving of the motor 110, the first piston 141 and the second piston 142 move in one direction of the cylinder 120 And supplies the extinguishing material accommodated in one side of the cylinder 120 to at least one of the first sprinkler 210 or the second sprinkler 220 by discharging the extinguishing material through the first outlet 161. [

When the first ball screw 131 and the second ball screw 132 are rotated in the other direction by the driving of the motor 110, the first piston 141 and the second piston 142 move in the direction of the cylinder 120 And discharges extinguishing material accommodated in the other side of the cylinder 120 through the second outlet 162 to the at least one of the third sprinkler 230 or the fourth sprinkler 240.

That is, the first ball screw 131 and the second ball screw 132 are rotated by the rotation of the motor 110 such that the first piston 141 and the second piston 142 can linearly move in the same direction Must rotate.

The pumps 100 and 200 of the apparatus may further include restoring means 150 for supporting at least one of the first piston 141 and the second piston 142.

4, the restoring means 150 serves as a kind of return spring. In particular, as shown in FIG. 4, the restoring means 150 is provided between the first inner end of the cylinder 120 and the first piston 141, It is possible to maintain the first piston 141 and the second piston 142 appropriately supported in the cylinder 120 by disposing the restoration means 150 between the end portion and the second piston 142.

It is also possible to integrally form the first accommodating portion 510 and the second accommodating portion 520 with the pumps 100 and 200. In this case, the first accommodating portion 510 and the second accommodating portion 520 520 and the pumps 100, 200 will be formed integrally with the pumps 100, 200 as well.

Further, since the pumps 100 and 200 of the present apparatus are controlled by the control unit as described above, as shown in FIG. 3, a connection terminal for receiving a signal from the control unit and a power terminal for driving the motor, (170) may be provided.

Hereinafter, the movement of extinguishing materials according to the driving of the pumps 100 and 200 will be described with reference to FIGS. 5 and 6. Figures 5 and 6 are circuit diagrams illustrating the flow of extinguishing media according to the situation in one embodiment of the present apparatus

Referring to FIG. 5, the flow of extinguishing material when the extinguishing material is supplied to the first sprinkler 310 or the second sprinkler 320 will be described.

If the control unit determines that the first sprinkler 310 and the second sprinkler 320 need to inject the extinguishing material on the basis of the fire occurrence and the fire occurrence position input from the fire state determination unit 1200 of the control unit, The protective equipment control unit 1300 controls the operation of the first pump 100 and the second pump 200. [

More specifically, the control unit drives the motor 110 of the first pump 100 to rotate the first ball screw 131 and the second ball screw 132 in one direction, thereby rotating the first piston 141 and the second piston 141 in one direction of the cylinder 120.

At this time, the extinguishing material contained in one side of the cylinder 120 is discharged to the first flow path 410 through the first outlet 161 by the pressure generated by the first piston 141.

At this time, the first solenoid valve 610 opens the first flow path 410 by the electronic control device so that the extinguishing material moves from the first pump 100 to the first sprinkler 310.

Similarly, the operation of the second pump 200 and the second solenoid valve 620 is also controlled by the control unit, so that the fluid moves from the second pump 200 to the second sprinkler 320, The detailed contents are the same as the moving contents of the extinguishing material between the first pump 100 and the first sprinkler 310.

It is possible to supply the extinguishing material to the first sprinkler 310 and the second sprinkler 320 through the above process.

Conversely, the flow of the fluid in the case where the extinguishing material is supplied to the third sprinkler 330 and the fourth sprinkler 340 will be described with reference to FIG.

If the control unit determines that the third sprinkler 330 and the fourth sprinkler 340 need to inject the extinguishing material on the basis of the fire occurrence and the fire occurrence position input from the fire state determination unit 1200 of the control unit, The protective equipment control unit 1300 controls the operation of the first pump 100 and the second pump 200. [

More specifically, the control unit drives the motor 110 of the first pump 100 to rotate the first ball screw 131 and the second ball screw 132 in the other direction to rotate the first piston 141 and the second piston 141 in the direction of the other side of the cylinder 120.

At this time, the extinguishing material contained in the other side of the cylinder 120 is discharged to the third flow path 430 through the second outlet 162 by the pressure generated by the second piston 142.

At this time, the third solenoid valve 630 opens the third flow path 430 by the control unit so that the extinguishing material moves from the first pump 100 to the third sprinkler 330.

Similarly, the operation of the second pump 200 and the fourth solenoid valve 640 is also controlled by the control unit, so that the extinguishing material moves from the second pump 200 to the fourth sprinkler 340, The details of the movement of the extinguishing material between the first pump 100 and the third sprinkler 330 are the same.

It is possible to supply the extinguishing material to the third sprinkler 330 and the fourth sprinkler 340 through the above process.

The fluid may be simultaneously supplied to the first sprinkler 310 and the second sprinkler 320 or the third sprinkler 330 and the fourth sprinkler 340 as described above. 200 can be independently driven and accordingly the first pump 100, the second pump 200 and the solenoid valves 610, 620, 630, 640 disposed on each flow path are appropriately controlled as needed, The first sprinkler 310 and the fourth sprinkler 340 can simultaneously transmit the extinguishing material or the second sprinkler 320 and the third sprinkler 340 330 to simultaneously extinguish the extinguishing material.

Hereinafter, the movement of the extinguishing material according to other embodiments of the present invention will be described with reference to FIGS. 7 and 8. FIG. Figs. 7 and 8 are circuit diagrams for explaining the flow of extinguishing material according to a situation in another embodiment of the present apparatus. Fig.

As described above, another embodiment of the present apparatus includes a first cross flow path 710 for moving the extinguishing material between the first sprinkler 310 and the fourth sprinkler 340, And a second cross flow path 720 for movement of extinguishing material between the first sprinkler 320 and the third sprinkler 330.

7, the extinguishing material supplied to the side of the first sprinkler 310 by the first cross flow path 710 can be transmitted to the side of the fourth sprinkler 340, and on the other hand, The extinguishing material supplied to the sprinkler 340 side can be transmitted to the first sprinkler 310 side.

8, the extinguishing material supplied to the third sprinkler 330 side by the second cross flow path 720 can be transmitted to the second sprinkler 320 side, and on the contrary, the second sprinkler 320 side So that the supplied extinguishing material can be transmitted to the third sprinkler 330 side.

As a result, it becomes possible to transmit the extinguishing material on the side of the sprinkler which requires no injection of the extinguishing substance to the side of the sprinkler requiring the extinguishing of the extinguishing substance by the first crossing passage 710 and the second crossing passage 720.

Furthermore, it is possible to maximize the above-mentioned effects by appropriately controlling the auxiliary valves 730 and 740 for controlling the opening and closing of the first cross flow path 710 and the second cross flow path 720.

Hereinafter, the control unit of the apparatus will be described in detail with reference to FIGS. 9 to 12. FIG. FIG. 9 is a block diagram showing a main configuration of the control unit in the present apparatus, and FIGS. 10 to 12 are detailed configuration block diagrams of the main configuration in FIG.

9, the control unit of the apparatus includes a fire sensing unit 1100 for collecting fire information through a plurality of sensing sensors that are located in a specified space, A fire status determination unit 1200 for determining whether or not a fire has occurred, analyzing a type of fire and a location of a fire, and a fire status determination unit 1200 for determining a fire status of the fire based on the information analyzed and determined by the fire status determination unit 1200, A power equipment controller 1400 for collecting information on power facilities in the building, analyzing the power state to control the supply of emergency power, and sending an emergency signal, A wireless communication unit 1500 for transmitting information through a fire sensing unit, a fire status determination unit, a protection equipment control unit, and a control unit of a power facility control unit wirelessly; Flow, it receives information such as the progress of the fire, and normal or abnormal operation of the protection device may be configured to include a monitoring integrated server unit 1600 that.

The fire sensing unit 1100 may include a plurality of sensors for sensing an environmental change disposed in the divided areas a to j partitioned into a plurality of divided spaces.

10, a gas sensor 1110 for sensing a gas in a building, a temperature sensor 1120 for sensing a temperature in a partitioned area in the building, a sensor for detecting the presence or absence of toxic substances in the building, And a toxic substance detection sensor 1130 for detecting a toxic substance.

The gas sensor 1110 may include a CO2 sensor, a 02 sensor, a CO sensor, and the like. The temperature sensor 1120 may be a well-known sensor that detects the temperature in the building, and may include a sensing device such as a flame sensor Or may be implemented to be interlocked.

Further, the toxic substance detection sensor 1130 may be a PH sensor, a DO sensor, an ORP sensor, or the like. The plurality of sensor groups are distributed evenly in the partition area of the building shown in FIG. 6, and the change of the state of the corresponding area is detected in real time, and the integrated server unit 1600 and the fire state determination unit 1200, To the protection equipment control unit 1300.

The fire status determination unit 1200 can determine the fire occurrence status in the partition area based on the transmission information of the fire sensing unit 1100 and further can determine and analyze the progress status of the fire in a short time .

Specifically, the fire status determiner 1200 includes a fire analyzer 1210 for comparing the sensed information sensed by the fire sensor 1100 with predetermined fire occurrence and type criterion information, A fire type determination unit 1220 for determining the type of fire through the type of the gas, the type of the toxic substance, and the temperature information provided by the fire sensing unit when the fire analysis unit 1210 determines that the fire is a fire, And a fire position determination unit 1230 that determines the ignition position and the progress area of the fire through the area including the sensor group provided with the corresponding information in real time when it is determined as a fire in the analysis unit 1210 have.

The fire analysis unit 1210 compares the sensed information sensed by the fire sensing unit 1100 with predetermined fire occurrence and type criterion information to determine whether or not the fire has occurred. The determination of whether or not such a fire is not a single route, but rather a complex environmental information is collected and compared with predetermined information so that the user can quickly judge whether or not the fire is accurate.

For example, when a gas such as CO is detected from a gas detection sensor 1110 that detects a gas in a building and a temperature sensed by a plurality of temperature sensors 1120 distributed in an area adjacent to the area is detected in another partition area It is judged whether or not the temperature can be seen as a fire in comparison with the temperature of the predetermined fire judgment, and it is possible to judge occurrence of fire through the detection of toxic substances in the gas detection type do.

The fire analysis unit 1210 determines whether or not a fire has occurred, defines fire as occurring in the divided area, divides the fire occurrence area into a fire area, a diffusion area, and a diffusion expected area, (1600).

Based on the analysis information, the integrated management server unit 1600 defines a dangerous area in the partition area of the building, and at the same time, a safety path (a staircase, a movable elevator, a place of evacuation of the shortest path) It is broadcasted by broadcasting.

For example, the analysis of the fire analysis section analyzes the temperature variation in the interior of the ignition area and the adjacent compartment, and analyzes the internal and external fires at a single point in the compartment area. .

In the fire type determination unit 1220, when the fire analysis unit 1210 determines that a fire has occurred, the fire type determination unit 1220 determines the type of occurrence of the fire, the rate of diffusion, , And the result is calculated by judging whether the generated fire is general fire, oil fire, chemical fire, electric fire or gas fire.

At the same time, information on the ignition material (structure, equipment, products) of the diffusion region and the diffusion expected region adjacent to the ignition region is received from the integrated management server to predict that the kind of fire will be changed, And transmits it to the integrated management server.

The fire position determination unit 1230 synthesizes the fire occurrence area (present), the expected fire spread area, and the fire type variation information in the fire analysis unit 1210 and the fire type determination unit 1220, The location of the fire is identified in real time and transmitted to the integrated management server.

The protection device control unit 1300 receives information on the origin and diffusion path of the fire from the integrated management server, activates the fire protection facility on the progress path of the fire, automatically releases the relief to the evacuation path And the like.

11, the protection apparatus control unit 1300 controls the protection shutter unit A or the shutoff shutter unit 1200 to block the fire spread in the fire occurrence area determined by the fire state determination unit 1200 A fire extinguishing means 1310 for driving the fire extinguishing plate driving unit B and a fire extinguishing means suitable for driving the shut-off shutter unit A or the fire extinguishing plate driving unit B, A flame reinforcement blocking unit 1320 that is reinforced and operated, a relief mask disposed in an area adjacent to the fire generating unit, and a relief shoe driving unit 1330 for opening a relief provided with a simple relief device .

In this case, the flame reinforcement blocking unit 1320 may include a flame retardant selection unit 1322 for selecting one or more suitable flame retardants according to the type of fire determined by the fire type determination unit 1220, And a flameproof material input unit 1325 for opening the accommodated storage unit to diverge the flame retardant mixed into a single or a mixture of two or more.

When the control unit is specifically applied to the present apparatus, the protection apparatus control unit 1300 controls the motor 110 and the solenoid 130 based on the fire occurrence and the fire type detected by the fire state determination unit 1200, By driving the valve 400, even if the fire extinguishing material in the reservoir is exhausted or the fire extinguishing material is damaged in the case of a building fire, Since the sprinkler can spray the extinguishing material, it is possible to prevent damage to important facilities and devices.

In addition, in the embodiment of the present invention, the configuration of the power facility controller 1400 shown in FIG. 9 includes a power state analysis unit 1410 for analyzing the power supply and the power failure state in the partition area as shown in FIG. 12 Respectively.

In this case, a large number of people move to the expected evacuation route. If the power in the direction is not supplied, the damage can be increased. Thus, the emergency power supply 1420 can safely evacuate Allow the power on the safety path to be advanced through the emergency power battery.

Of course, it also includes an emergency signal sending unit 1430 that allows the safety path to be transmitted through voice and beacon. Also, the emergency signal sending unit can be driven by the emergency power source, thereby enhancing stability.

In the above-described embodiments of the fire suppression device in the specific space inside the building according to the above-described embodiment of the present invention, the term " part " used in various configurations according to the present invention includes hardware such as software or FPGA or ASIC Component, and 'part' performs some role. However, 'part' is not meant to be limited to software or hardware. &Quot; to " may be configured to reside on an addressable storage medium and may be configured to play one or more processors. Thus, by way of example, 'parts' may refer to components such as software components, object-oriented software components, class components and task components, and processes, functions, , Subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, and variables. The functions provided in the components and components may be further combined with a smaller number of components and components or further components and components. In addition, the components and components may be implemented to play back one or more CPUs in a device or a secure multimedia card.

In the foregoing detailed description of the present invention, specific examples have been described. However, various modifications are possible within the scope of the present invention. The technical idea of the present invention should not be limited to the embodiments of the present invention but should be determined by the equivalents of the claims and the claims.

100: first pump
200: Second pump
300: Sprinkler
400: Euros
500, 600: Solenoid valve
710: first crossing passage
720: the second crossing passage
810:
820:

Claims (5)

1. A fire suppression device for suppressing a fire generated in four areas, which are a plurality of specific spaces inside a building,
The first sprinkler 310, the second sprinkler 320, the third sprinkler 330, and the fourth sprinkler 340, which are disposed in the first, second, third, and fourth regions, respectively, );
A first receiving portion 810 and a second receiving portion 820 receiving a first extinguishing material and a second extinguishing material sprayed through at least one of the first sprinkler 310 to the fourth sprinkler 340;
The first sprinkler 310 and the third sprinkler 330 may receive at least one of the first extinguishing material and the second extinguishing material from at least one of the first accommodating part 810 and the second accommodating part 820, A first pump (100) for supplying at least one of a first extinguishing material and a second extinguishing material to at least one of the first extinguishing material and the second extinguishing material;
At least one of the first extinguishing material and the second extinguishing material is supplied from at least one of the first accommodating part 810 and the second accommodating part 820 and the second sprinkler 320 and the fourth sprinkler 340 A second pump 200 for supplying at least one of the first extinguishing material and the second extinguishing material to at least one of the first and second extinguishing materials;
A flow path formed between the first pump 100, the second pump 200, the plurality of sprinklers 300, the first accommodating portion 810, and the second accommodating portion 820, ;
A solenoid valve disposed on the flow path; And
And a control unit for controlling driving of the first pump (100), the second pump (200), and the solenoid valve,
The first pump (100) and the second pump (200)
A motor 110;
A cylinder (120) configured to receive at least one of the first digesting material and the second digesting material;
A first ball screw 131 and a second ball screw 132 disposed on one side and the other side of the cylinder and rotating based on driving of the motor;
A first piston 141 and a second piston 142 linearly reciprocating in the cylinder 120 based on rotation of the first ball screw 131 and the second ball screw 132;
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The first ball screw 131 and the second ball screw 132 rotate on the same axis,
The first digestion material and the second digestion material are extinguishing materials of mutually different components,
The first pump 100 and the second pump 200 are independently driven,
The flow path includes:
A first flow path and a third flow path respectively connecting one side and the other side of the first pump 100 to the first sprinkler 310 and the third sprinkler 330;
A second flow path and a fourth flow path connecting the one side and the other side of the second pump 200 to the second sprinkler 320 and the fourth sprinkler 340, respectively;
A fifth passage in which one side is connected to the first accommodating portion 810;
A sixth flow path and seventh flow path branched from the other side of the fifth flow path and connected to the first pump 100 and the second pump 200, respectively;
An eighth passage in which one side is connected to the second accommodating portion (820);
A ninth flow path and a tenth flow path branched from the other side of the eighth flow path and connected to the first pump 100 and the second pump 200, respectively;
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A first solenoid valve to a tenth solenoid valve for opening and closing the flow path are disposed on the first to eighth flow paths, respectively,
The control unit may include a fire sensing unit 1100 for collecting fire information through a plurality of sensing sensors disposed in the plurality of specific spaces, a control unit 1100 for controlling the plurality of specific spaces based on the fire information collected by the fire sensing unit 1100, A fire state determiner 1200 for determining whether a fire has occurred in which space and analyzing the fire type, and a fire extinguisher installed in the plurality of specific spaces based on the information analyzed and determined by the fire state determiner 1200 (1300) for driving the robot arm
The fire status determination unit 1200 includes a fire analysis unit 1210 for comparing the sensed information sensed by the fire sensing unit 1100 with predetermined fire generation and type reference information to determine whether or not the fire is generated; A fire type determination unit 1220 for determining the type of fire through the type of the gas, the type of the toxic substance, and the temperature information provided by the fire sensing unit when the fire analysis unit 1210 determines that the fire is a fire; And a fire position determination unit 1230 for determining a fire position and an ongoing area of the fire through a region including a sensor group to which the corresponding information is provided in real time when the fire analysis unit 1210 determines that it is a fire ,
The protection device control unit 1300 controls the first pump 100 and the second pump 200 based on the ignition position and the progress area of the fire detected by the fire state determiner 1200, , At least one of the first solenoid valve to the fourth solenoid valve is driven,
The protection device control unit 1300 drives at least one of the fifth to tenth solenoid valves based on the type of fire determined by the fire type determination unit 1220,
The flow path includes a first cross flow path 710 for movement of extinguishing material between the first sprinkler 310 and the fourth sprinkler 340 and a second cross flow path 710 between the second sprinkler 320 and the third sprinkler 330. [ Further comprising a second cross-flow channel (720) for movement of the extinguishing medium,
Further comprising a first auxiliary valve 730 disposed on the first cross flow path 710 and a second auxiliary valve 740 disposed on the second cross flow path 720,
The first receiving portion 810 and the second receiving portion 820 are formed integrally with the first pump 100 and the second pump 200,
And the fifth solenoid valve to the tenth solenoid valve are integrally formed with the first pump 100 and the second pump 200.
delete delete delete The method according to claim 1,
The first pump (100) or the second pump (200)
Further comprising restoring means (150) for supporting at least one of the first piston (141) and the second piston (142).

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