KR101754232B1 - Remote checking system in Apartment Fire - Google Patents

Abstract

The present invention relates to a remote firefighting inspection system for a multi-family house, and more particularly, to a remote firefighting inspection system for a multi-family house, in which a state of firefighting water supplied to a residence can be remotely checked in real time to perform a quick and accurate firefighting function in an emergency, The present invention relates to a remote firefighting inspection system of an apartment house improved to minimize noise generated during control and data processing while minimizing deterioration of the boards mounted in a high temperature.

Description

Remote checking system in Apartment Fire

The present invention relates to a remote firefighting inspection system for apartment houses in a fire fighting technology field. More particularly, the present invention relates to a remote firefighting inspection system for a residential house, And more particularly, to a remote firefighting inspection system of a multi-house which is improved to minimize noises generated during control and data processing while minimizing the deterioration of the boards mounted on the control unit for high temperature.

In the case of public housing complexes and large buildings such as conventional apartment complexes, it is required to continuously manage and improve fire safety facilities as the buildings are aged. There are more improved types of fire-fighting facilities in newly constructed high-priced buildings, but it is not easy to regularly manage fire-fighting facilities in existing old buildings or complexes.

In addition, there is a problem that many safety accidents are caused due to malfunction of old equipment.

On the other hand, in order to regularly and systematically manage the fire-fighting facilities through the existing infrastructure of the old buildings, it is also problematic to raise the labor cost of professional manpower and expenses.

Therefore, there is a need for more systematic safety management of firefighting facilities using existing infrastructure.

On the other hand, in the fire department, regular fire safety inspections are carried out according to the Fire Service Act. Such fire safety inspections are likely to be formalized.

It is also required that the fire safety control system can check the fire protection facilities of these buildings in real time.

Korea Patent Registration No. 10-1453164 (Apr. 14, 2014) 'Remote firefighting inspection system and method of apartment complex or building'

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a fire extinguishing system capable of quickly and accurately extinguishing a fire extinguishing function in an emergency, The present invention has a main object of the present invention to provide a remote firefighting inspection system of a multi-house which is improved to minimize the noise generated during control and data processing while minimizing the deterioration of the boards mounted in the control unit for high temperature.

As a means for achieving the above object, the present invention provides a fire-fighting device for fire-fighting equipment, comprising: a fire detector for detecting a state of each fire fighting equipment installed in a multi-family house to transmit a state detection signal; A plurality of sub-controllers (110) for controlling the operation of the hydraulic valve opening / closing; Controller 110 connected to each other through a pair of digital preliminary lines provided in the apartment house, receives and monitors the state detection signal from the sub-controller 110, and generates the operation control signal And a main controller (120) for transmitting to the sub-controller (110); The main controller 120 includes a memory unit 121 for a map DB for storing map information of a managed apartment, including a built-in memory, a tablet PC carried by a worker or an administrator under the control of the main controller 120, A wireless communication unit 122 for communicating with the main controller 120 through the wireless communication unit 122 and a main controller 120 receiving the status detection signal from the sub controller 110, And an alarm generating unit 124 for alarming the peripheral managers to recognize immediately when the abnormality occurs when the main controller 120 reads and emits an emergency bell or blinks the lamp. The sub controller 110 includes a fire controller 111 for receiving a detection signal of the fire fighting equipment and controlling the operation of the fire fighting equipment, a signal processor for signal processing the detection signal received from the fire controller 111, A signal processor 112 for receiving an operation control signal from the main controller 120 and performing signal processing on the received signal and a signal processor 112 for converting the signal processed by the signal processor 112 into a bidirectional signal and transmitting the signal to the main controller 120, And a signal converter 113 for receiving an operation control signal received from the signal processor 120 and transmitting the received operation control signal to the signal processor 112. The status detection signal is a power on / Off state signal of the sprinkler 40, the power on / off state signal of the sprinkler 40, the power on / off state signal of the sprinkler 40, the power on / Off control signal of the fire hydrant 20, the power on / off control signal of the hydrator 20, the power on / off control signal of the sprinkler 40, the power on / The sub controller 110 senses the water pressure of the hydrator 20 and the sprinkler 40 through a hydraulic pressure sensor to generate a state detection signal and outputs the generated state detection signal to the main controller 120 The main controller 120 controls the hydraulic valve opening and closing operations of the hydrants 20 and the sprinkler 40 by receiving an operation control signal from the main controller 120. The main controller 120 controls the hydraulic pressure The power source of the fire alarm 10 is turned off or the power of the fire hydrant 10 is turned off or the power of the sprinkler 40 is off, ON state, Configured to transmit the status detection signal to the control system of the fire department in a wired or wireless communication manner in order to make the fire fighting equipment remotely checkable by the fire department, A remote fire fighting inspection system of a fire fighting system comprising:

Further comprising a check window 210 connected to the digesting pipe 200 at a lower end of the digesting pipe 200 through which a part of the extinguishing pipe 200 is connected and screwed together, A main opening / closing valve 220 is installed on the fire extinguishing pipe 200 in the upper portion and a fixed boss BOS is integrally formed in the fire extinguishing pipe 200 in the direct lower portion where the inspection window 210 is installed A fixing bolt 240 passing through the lower end of the detour guide block 230 constituting the inspection window 210 is bolted through the center of the fixing boss BOS, A check connecting chamber 250 is formed on the opposite side of the opening and a fluid circulation passage 260 is formed in the fixing bolt 240. The check valve 250 is provided on the opposite side of the check connection chamber 250, And four circles (90 degrees) are formed around the circumference of the fluid ring (260) The lower end of the flow spring 280 is fixed on the fixed boss BOS and the lower end of the flow spring 280 is fixed on the fixed boss BOS, The inspection connection chamber 250 is connected to an external inspection pipe 290 and the external inspection pipe 290 is provided with a check valve 300 And a water supply check controller 310 is further installed on the outer circumferential surface of the upper digestion pipe 200 of the inspection window 210. The water supply check controller 310 is configured to be capable of wireless communication with the main controller 120, A water supply sensor 320 is installed in a part of the external check pipe 290 to check the presence or absence of water flowing through the external check pipe 290. The water supply check controller 310 is connected to the main check valve 290, (220), the check valve (300), and the water supply sensor (320) are electrically connected And air control;

The map DB memory unit 121, the wireless communication unit 122, the display unit 123 and the alarm generating unit 124 are mounted on the housing 2130 in a board form to constitute the control unit 100;

The housing 2130 includes a rectangular frame 2132 and a front door 2134 is hingedly fixed to one side of the fixing frame 2132 so as to be openable and closable on the front face of the fixed frame 2132, And a bottom plate 2140 is fixed to the lower surface of the fixed frame 2132. The bottom plate 2140 is fixed to the lower surface of the fixed frame 2132 An upper plate 2142 is fixed to a ceiling facing the bottom plate 2140 and an air suction hole 2138a in the form of a rectangular slit is formed in both side plates 2138. A filter And an indirect cooling unit 2150 is installed on the upper surface of the upper plate 2142. The indirect cooling unit 2150 has a lower portion communicating with the housing 2130 through the upper plate 2142, A suction chamber 2152 in the form of an open rectangular box, Shaped blowing pipe 2154 through which a lower end of the hook shape is inserted and fixed, a blowing fan 2156 installed at the upper end of the blowing pipe 2154, and an exhaust hole 2158 formed in the hook-shaped horizontal portion 2158 of the blowing pipe 2154 And a plurality of outlets 2162 formed on the upper surface of the rear chamber 2152 on a position equivalent to the exhaust hole 2160;

A plurality of radiating fins 2170 are further formed on the inner surfaces of the front door 2134 and the side plates 2138. The front doors 2134 and the side plates 2138 are formed to have a hollow portion 2172 therein, A plurality of openings 2174 communicating with the hollow portion 2172 are formed on the outer surfaces of the front door 2134 and the side plate 2138 to increase the heat radiation performance;

A sound absorbing sheet 2180 is further attached to the inner side surface of the side plate 2138 along the periphery of the side where the heat radiation fins 2170 are not formed so as not to interfere with the heat dissipating fin 2170, A circular polypropylene knitted fabric 2182 knitted repeatedly at a spacing in the longitudinal direction when knitted over the knitted fabric 2100, and the polypropylene knitted fabric 2182 is flattened in the radial direction to form a double layer The PET film 2184 is needle-punched so that a plurality of needle holes are formed on the outer surface of the polypropylene fabric 2182, To thereby reduce the noise of the remote control system.

According to the present invention, the state of the fire-fighting water supplied to the apartment house can be remotely checked in real time, and the effect of performing the fire-fighting function quickly and accurately in an emergency can be obtained.

In addition, it is possible to minimize noise generated during control and data processing while minimizing deterioration of the boards mounted on the control unit used for control in a state exposed to high temperature.

FIG. 1 is a block diagram of a remote firefighting inspection system of a multi-family housing complex or a building according to an embodiment of the present invention.
2 is a detailed configuration diagram of a sub-controller according to an embodiment of the present invention.
FIG. 3 is a flowchart of a remote fire prevention inspection method for a multi-family housing complex or a building according to an embodiment of the present invention.
FIG. 4 is an exemplary partial cross-sectional view illustrating an installation example of a water supply status check window according to an embodiment of the present invention.
5 is an exemplary view of a fire detector according to an embodiment of the present invention.
6 is an exemplary view of a water pump according to an embodiment of the present invention.
7 is an exemplary view showing a housing constituting the appearance of the control unit of the present invention.
Figure 8 is an illustration of an indirect cooler applied to Figure 7;
9 is an exemplary sectional view of the side plate applied to Fig.
10 is an exemplary view showing an example in which a sound absorbing sheet is attached to an inner surface of a side plate applied to Fig.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

Prior to a specific description of the present invention, the remote fire fighting inspection system basically includes the contents of the above-mentioned Registration No. 1453164 as it is.

For example, referring to FIG. 1, the apartment house remote fire fighting inspection system according to an embodiment of the present invention includes a control unit 100 including a plurality of sub-controllers 110 and a main controller 120, (100) is installed in a remote control room (not shown).

In addition, the control unit 100 controls the sub-controller 110 attached to the fire-fighting equipment such as the fire alarm 10 and the fire hydrant 20 installed in the building, The main controller 120 is configured to transmit a state detection signal of the fire fighting equipment and the main controller 120 can monitor the state of each fire fighting equipment or whether normal operation is possible in real time.

In addition, since the sub controller 110 and the main controller 120 are configured to be connected using a pair of digital preliminary wires installed in a common house, there is an advantage that a separate network is not required.

Thus, it is easy to construct an old building or an apartment.

The control unit 100 includes a plurality of chips, i.e., board-shaped control elements, such as a memory DB 121 for a map DB, which will be described later, A display unit 122, an alarm generating unit 124, and the like.

In this case, the memory unit 121 for the map DB, the wireless communication unit 122, the display unit 123, the alarm generating unit 124, and the like are usually mounted on a thick plate constituting the housing 2130, And the like.

On the other hand, the main controller 120 can remotely control the operation of the drencher 30 or the opening and closing of the firewall 50 according to a fire detection or the like. Therefore, it is very advantageous to cope with the fire in the first place. However, since the drencher 30 or the firewall 50 is installed in a building, it corresponds to the case of a building. In the present invention, the drencher 30 or the firewall 50 may be absent , And because it can be applied to buildings, it will be explained for the sake of convenience.

On the other hand, the main controller 120 is configured to transmit the state detection signal of each fire fighting equipment to the fire fighting system (not shown) of the fire department, thereby facilitating the fire safety inspection of the fire department, There is an induction effect.

The main controller 120 includes a memory unit 121 for a map DB, a wireless communication unit 122, a display unit 123, an alarm generating unit 124 ).

At this time, the map DB memory unit 121 is a place where the location of the apartment house connected to the main controller 120 and the sub-controller installation location of the floor are stored and stored.

In this case, since all the sub-controllers are assigned unique numbers, it is possible to immediately check which position the sub-controller is by analyzing the signals transmitted from the sub-controllers.

The wireless communication unit 122 is a communication device that enables wireless communication with a tablet PC carried by a worker or an administrator through an Internet network.

Therefore, when a fire is detected or a specific emergency signal is transmitted to a registered tablet PC of a worker or an administrator or a designated related worker under the control of the main controller 120, map information about the corresponding apartment house and each sub- And the operator or the manager can quickly move to the corresponding position by referring to the map information.

The display unit 123 is a means for displaying a state detection signal on a screen of a specific type so that the main controller 120 receiving the state detection signal from the sub controller 110 monitors the state detection signal.

In addition, the alarm generating unit 124 may be provided with a means for warning the surrounding administrators to recognize immediately when the abnormality occurs in the detection signal or the status signal, such as when the main controller 120 reads an emergency bell or flashes a lamp, to be.

Hereinafter, the detailed configuration will be described.

The sub-controller 110 may be configured to perform a state detection of each of the fire fighting equipment 10 to 50 installed in the apartment or building and transmit the state detection signal.

Here, the status detection signal includes a power on / off status signal of the fire alarm 10, a power on / off status signal and a light on / off status signal of the fire hydrant 20, a power on / off status signal of the drencher 30 An on / off state signal of the sprinkler 40, a power on / off state signal of the sprinkler 40, and an open / close state signal of the firewall 50.

Such a state detection signal can be detected / determined from the presence or absence of a power supply signal input from each of the fire fighting equipment 10 to 50.

Meanwhile, the main controller 120 may be configured to receive and monitor the status detection signal from the sub-controller 110. [ In this case, monitoring is performed through the display unit 123 mounted on the control unit 100. [

That is, the state of each fire fighting equipment 10 to 50 can be displayed through the display unit 123. [

If there is an abnormality in the state, the alarm can be configured to be notified to the administrator through a separate lamp or an alarm sound, which is performed through the alarm generating unit 124 in accordance with the control signal of the main controller 120.

In addition, the main controller 120 can be configured to control operation remotely when there is a problematic fire fighting equipment among the fire fighting equipment 10 to 50. [

In addition, even when a fire is detected through the smoke alarm 10, it can be configured to control the operation of each fire fighting equipment 10 to 50 remotely.

The main controller 120 may generate an operation control signal for the fire fighting equipment 10 to 50 for remote control and transmit the operation control signal to the sub controller 110.

The sub controller 110 is configured to receive the operation control signal transmitted from the main controller 120 and to control the operation of the fire fighting equipment 10 to 50.

At this time, the operation control signal includes a power on / off control signal of the fire alarm 10, a power on / off control signal of the hydrant 20 and a light on / off control signal, A power on / off control signal of the sprinkler 40, a power on / off control signal of the firewall 50, or an open / close operation control signal.

That is, when the power is turned off in the smoke alarm 10 or the lamp of the fire hydrant 20, the power can be switched to the normal operation state remotely through the power on control signal.

In addition, it is preferable that when the fire occurs, even when the drencher 30 or the sprinckle 40 does not operate, it can be controlled to be forcibly remotely operated.

In addition, even in the case of the firewall 50, it can be configured to control operation of opening and closing remotely.

In addition to the power state, the sub-controller 110 senses the water pressure of the hydrant 10, the drencher 20, or the sprinkler 40 through the hydraulic pressure sensor, generates a state sensing signal, To the main controller 120. [

At this time, the sub controller 110 is preferably configured to receive the operation control signal from the main controller 120 and to control the hydraulic valve opening / closing operation of the hydrator 10, the drencher 20, or the sprinkler 30 .

Even when the hydraulic pressure valve opening / closing operation is not possible, it is possible to know whether the hydraulic pressure valve of the drencher 20 or the sprinckle 40 is locked or not through the hydraulic pressure sensor.

On the other hand, the main controller 120 may be configured to transmit the status detection signal to a fire department system (not shown) of the fire department via a wired or wireless communication method.

Therefore, the fire department can carry out the fire safety check more easily and systematically manage the old fire fighting facilities.

In addition, the main controller 120 is configured to automatically transmit a fire detection signal of the fire alarm 10 to a fire fighting system system (not shown) so that the fire alarm can be automatically and quickly reported.

2, the sub-controller 110 may include a fire controller 111, a signal processor 112, and a signal converter 113.

The fire controller 111 is connected to the fire fighting equipment 10 to 50 and is configured to receive a power signal or a water pressure signal from the fire fighting equipment 10 to 50.

The fire controller 111 is configured to receive the state detection signal of the fire fighting equipment as well as to control the operation of the fire fighting equipment 10 to 50.

The signal processor 112 processes the state detection signal received from the fire controller 111 and receives the operation control signal from the main controller 120 to process the signal.

The signal converter 113 converts the sensed signal processed by the signal processor 112 into a bi-directional signal and transmits the bi-directional signal to the main controller 120 or receives the operation control signal received from the main controller 120, 113).

At this time, the signal converter 113 continuously transmits the detection signal to the main controller 120, but when the operation control signal is received from the main controller 120, the signal converter 113 is configured to suspend the transmission of the detection signal.

3, a plurality of sub-controllers 110 provided in each of the fire fighting equipment 10 to 50 installed in a multi-house or a building may transmit a state detection signal of the fire fighting equipment 10 to 50 Signal processing is performed (S101).

Here, the state detection signal includes a power ON / OFF state signal of the fire alarm 10, a power ON / OFF state signal and a light ON / OFF state signal of the hydrant 20, a power ON / OFF state signal of the drencher 30, Off state signal or power on / off state signal of the sprinkler 40, a power on / off state signal or open / close state signal of the firewall 50, a fire hydrant 20, a drencher 30, And a pressure sensing signal of the hydraulic pressure sensor.

Next, the sub-controller 110 transmits a status detection signal to the main controller 120, which is connected to the main controller 120 using the digital preliminary lines of the pre-installed pairs (S102).

Next, the main controller 120 receives and displays a state detection signal or outputs a warning alarm sound according to the state detection signal (S103).

Next, the main controller 120 generates operation control signals for the fire fighting facilities 10 to 50 and transmits them to the corresponding sub-controller 110 (S104).

Here, the operation control signal includes a power on / off control signal of the fire alarm 10, a power on / off control signal of the hydrant 20 and a light on / off control signal, The power on / off control signal of the sprinkler 40, the power on / off control signal or the opening and closing control signal of the firewall 50, the fire hydrant 20, the drencher 30, And a hydraulic valve opening / closing operation control signal.

Next, the sub-controller 110 receives the operation control signal and performs signal processing (S105).

Next, the sub controller 110 controls operation of the fire fighting facilities 10 to 50 according to the signal-processed operation control signal (S106).

Next, the main controller 120 transmits the state detection signal to the fire control system (not shown) through a wired or wireless communication system (S107).

In addition, as shown in FIG. 4, the present invention may further include a check window 210 connected to the lower end of the extinguishing piping 200 to which the extinguishing water is supplied, the part of the extinguishing piping 200 being connected and screwed together.

A main opening / closing valve 220 is installed on the fire extinguishing piping 200 directly above the inspection window 210.

The main opening / closing valve 220 seals the upper digestion pipe 200 of the inspection window 210 when inspecting the inspection window 210, so that a safe inspection can be performed.

In order to install the inspection window 210, a fixing boss (BOS) is integrally formed inside the lower fire extinguishing pipe 200 of the inspection window 210, and a bypass guide 210 constituting the inspection window 210 The fixing bolt 240 passing through the lower end of the block 230 is bolted through the center of the fixing boss BOS to fix the detour guide block 230 firmly.

Particularly, since the water supplied from the water supply pump (not shown) is supplied in a high pressure state, the counter guide block 230 is formed in a substantially 'C' shape in which a part of the lower end is closed and a part of the side is opened And a check connection chamber 250 is formed on the opposite side of the opened side.

Here, the reason why the check connection chamber 250 is positioned as shown in the drawing is to place the water pressure at the smallest working position so as to improve the convenience of the inspection.

Four fixing balls 270 are fixed to the fixing bolt 240 at intervals of 90 degrees around the fluid ring 260. The fixing bolts 240 are fixed to the lower end of the fluid ring 260, The spring 280 is fixed, and the lower end of the flow spring 280 is fixed on the fixed boss BOS.

The inspection window 260 is formed of a transparent material. Therefore, it is configured to see the inside.

In addition, an external check pipe 290 is connected to the check connection chamber 250, and a check valve 300 is installed in the external check pipe 290.

In addition, a water supply check controller 310 is installed on the outer circumference of the upper digestion pipe 200 of the inspection window 210, and the water supply check controller 310 is configured to be capable of wireless communication with the main controller 120.

A water sensor 320 may be installed on a portion of the external check pipe 290 to check the presence or absence of water flowing through the external check pipe 290. A rainfall detection sensor is preferable.

The main opening / closing valve 220, the check valve 300, and the water supply sensor 320 are electrically connected to the water supply controller 310.

That is, the main on-off valve 220 and the check valve 300 can be opened or closed under the control of the water supply check controller 310 as a kind of solenoid valve.

Particularly, although not shown in the figure, the water supply check controller 310 is provided with a timer so as to check whether the water supply is normally performed through the digestive pipe 200 at a set period. In other words, water supply can not be done properly due to faults in the water pump and so on.

The water supply check controller 310 checks the water supply state according to the control signal of the main controller 120. First, the main on / off valve 220 is closed and the check valve 300 is opened Water on the digestive pipe 200 is discharged to the outside.

In this case, the water supply, that is, the water that has been filled on the lower fire extinguishing pipe 200 of the main on-off valve 220 is discharged to the outside through the external check pipe 290. If the water supply pump fails, The water supply controller 310 and the main controller 120 communicating with the water supply controller 310 can notify the water supply controller 310 in real time It is possible to recognize the abnormality of the water supply pump, and the follow-up action becomes possible.

On the other hand, when the normal operation is started, the check valve 300 is closed after a predetermined time, and then the main on-off valve 220 is opened.

At the same time, if the inspector is in the vicinity of the inspection window 210, the inspection ball 270 is floated in the flow direction of the extinguishing water because the extinguishing water flows to escape, which can be visually immediately observed.

As a result, you can immediately check whether there is a problem with the award.

When the check is completed, the elongated fluid spring 280 is retracted, and the check ball 270 returns to its original position and waits for the next check.

As described above, according to the present invention, since the improved inspection window 210 is provided, it is possible to detect the abnormality of the feed pump automatically in real time as well as real-time observation, thereby doubling the inspection function, do.

In addition, in the present invention, the fire detector 400 is also modified as shown in FIG. 5 so that wireless communication can be performed without a battery and semi-permanent use is possible.

The fire detector 400 is mounted on a ceiling surface in an ordinary household, and is installed to be driven after a voltage drop by sharing a power source in the home, that is, 220 V, and is mainly divided into a heat sensor or a smoke detector.

Particularly, since it is connected to the detection panel (not shown) provided in the fire hydrant by wire, it is troublesome to perform the wiring work in the indoor wiring, and it is very difficult to move the position once installed for the reason of wire.

Therefore, there is a lot of inconvenience because it is impossible to change the position of the fire detector 400 due to the inappropriate position of the fire detector 400 in the recent generation.

In the present invention, as shown in FIG. 5, a sensor base 410 that can be fixed to a ceiling surface in a household, a sensor case 410 including a substrate on which elements necessary for fire detection are integrated, And a sensor cover 430 for sealing the upper portion of the sensor case 420. A sensor substrate 440 is fixed to an inner center of the sensor case 420, A pair of sensing modules 460 symmetrically disposed on both sides of the sensor substrate 440 in the radial direction of the sensor base 410. The sensing module 460 includes a pair of sensing modules 460, And a plurality of solar cells 470 are installed in the circumferential direction with the sensing module 460 interposed therebetween to generate a starting current required for communication.

Since it has been confirmed that the communication module mounted on the sensor substrate 440 can sufficiently perform wireless communication through the three-dimensional flat plate antenna 450 even when the sensor module 440 flows only about 0.5 mm A, it is possible to transmit the signal through the solar cell 470, The obtained microcurrent was sufficiently obtained from the obtained voltage, which is considered to be the same as that of a solar cell installed in an electronic calculator or the like and driven without a battery.

In addition, a radio communication unit capable of communicating with the three-dimensional flat plate antenna 450 is naturally provided on the detection panel of the fire hydrant, and the detection panel is connected to the sub-controller 110 by wire.

In addition, if the signal amplifier is further mounted on the detector substrate 440, the communication sensitivity can be further increased.

The sensing module 460 may be a conventional smoke sensing sensor or a heat sensing sensor, and the three-dimensional flat antenna 450 may include a vertical portion 450 protruding in a direction perpendicular to the sensor substrate 440 in order to increase transmission sensitivity. A horizontal portion 452 projecting in the horizontal direction, and a horizontal portion 452 projecting in the horizontal direction.

With this structure, the battery can be used semi-permanently without a separate battery, and there is an advantage that the installation position can be arbitrarily freely changed since there is no line.

In addition, in the present invention, as shown in FIG. 6, the water sucked into the inlet of the water pump 500 is automatically converted into a direction in which the impeller of the pump rotates, whereby the impeller is vertically collided with the impeller, So as to prevent the service life from being shortened, the digestion feeding angle changing unit 510 can be further installed.

The fire extinguishing oil infusion angle switching unit 510 includes a housing 530 having a flange shape interposed between the extinguishing water inflow inlet 520 and the water feed pump 500 and a flange fixing member 530 fixed to one side of the housing 530 And a rotation release ring 550 that is flanged and fixed between the feed pump 500 and the housing 530 that is the other side of the housing 530.

In this case, the rotation induction ring 540 and the rotation relief ring 550 have the same structure, but only the rotational induction ring 540 has a square boss (SQR) on the central fixed plate FTP.

The center plate FTP is fixed to a rim RIT constituting the circumference by a plurality of comb teeth BIT and all the remaining parts except the comb teeth B are in the form of perforations. Is disposed at an angle with a predetermined angle so as to make the extinguishing water into rotation speed.

The RIM is rotatably fixed to the inner circumference of the rotary induction ring 540 and the rotary ejection ring 550. The RIM is rotatably supported on the inner circumference of the rotary induction ring 540 and the rotary release ring 550, The first rotator 570 and the second rotator 580 are successively fitted and the ends of the rectangular boss SQR are spaced apart from the center plate FTP of the rotation releasing ring 550 by a minute interval .

At this time, the first rotor 570 has a plurality of 'v' -type grooves 572 formed at regular intervals along the circumference and a plurality of holes 574 formed on the plate surface, And the comb 580 has a comb-shaped through hole 582 formed on its surface.

The reason for this construction is to accelerate the rotational force since the inflow of digested water is filled in the 'v' shaped groove 572 while moving along the circumference after being hit by the plate surface, and is already in a state of being rotated by the comb teeth BIT , The holes 574 are for reducing the pressure applied to the plate surface, and the comb-like holes 582 are for enhancing the discharge capability of the rotating water.

For this, the first and second rotors 570 and 580 should be formed small enough to be spaced apart from the inner diameter of the housing 530 by an interval of 10 mm.

With this configuration, the rotational water discharged through the rotation releasing ring 550 flows while being rotated in the direction of rotating the impeller of the water pump 500, so that the erosion of the impeller is significantly reduced, the pressure applied to the impeller is reduced, And contributes to increase the emission efficiency.

In addition, the housing 2130 constituting the external appearance of the control unit 100 has a special housing 2130 structure capable of effectively suppressing heat and noise due to the driving of a plurality of mounted boards, i.e., .

In addition, since the boards mounted inside the housing 2130 are weak against heat, it is necessary to cool them in terms of prevention of deterioration. However, when cooling is performed by a simple direct air blowing type, dust inside the housing 2130 is scattered, Is high.

Therefore, indirect cooling needs to be carried out effectively and effectively.

To this end, the present invention has the structure of the housing 2130 as shown in FIG.

7, the housing 2130 includes a rectangular frame 2132 and a front door 2134 is hinged to one side of the fixed frame 2132 so that the front door 2134 can be opened and closed. A rear plate 2136 is fixed to the rear surface of the front frame 2134 opposite to the front door 2134 and a side plate 2138 is fixed to both sides of the fixing frame 2132, And an upper plate 2142 is fixed to a ceiling facing the bottom plate 2140. [

In addition, air suction holes 2138a in the form of a rectangular slit are formed in both side plates 2138, and a filter 2138b is incorporated in the air suction holes 2138a.

Therefore, the outside air is introduced into the housing 2130 in a filtered state.

Meanwhile, an indirect cooling unit 2150 is installed on the upper surface of the upper plate 2142.

8, the indirect cooling unit 2150 includes a rectangular box-shaped suction chamber 2152 opened to communicate with the housing 2130 through the upper plate 2142, A blowing pipe 2154 penetrating through the center of the top surface of the suction chamber 2152 and having a hooked lower end inserted and fixed therein, a blowing fan 2156 installed at the upper end of the blowing pipe 2154, An exhaust hole 2160 formed in the horizontal portion 2158 and a plurality of exhaust ports 2162 formed in the upper surface of the suction chamber 2152 on a position equivalent to the exhaust hole 2160.

Therefore, when the blowing fan 2156 is operated, the outside air is introduced and discharged into the blowing pipe 2154, and then discharged through the discharge hole 2160 and the discharge port 2162.

That is, the introduced outside air is not supplied into the housing 2130 but is diverted and then discharged to the outside.

In the process, negative pressure is generated in the interior of the suction chamber 2152, particularly around the discharge port 2162, and the internal air distributed in the lower space of the suction chamber 2152 due to a kind of venturi effect due to the suction pressure by the negative pressure So that the heated air inside the housing 2130 is sucked to the outside.

As a result, the inside of the housing 2130 is entirely formed with negative pressure, fresh cool external air is introduced into the housing 2130 through the suction hole 2138a via the filter 2138b, dust is generated in the housing 2130 It is naturally cooled to a non-scattered state.

That is, since the general cooling structure is a structure in which outside air is introduced through the air blowing fan 2156 and is directly injected into the housing 2130 to be cooled directly, severe dust is generated inside the housing 2130 due to wind pressure , The dust is attached to the main terminals of each board, and in some cases, a spark due to static electricity is generated, which may cause a short circuit.

However, since the present invention has an indirect blowing mode in which such a situation is completely dispensed, that is, an indirect cooling structure, cooling can be performed without generating dust inside the housing 2130.

The inner surface of the front door 2134, the side plate 2138, the bottom plate 2140 and the thick plate 2136 constituting the housing 2130 is formed with a heat-resistant coating layer and a latent heat-resistant coating layer. If the latent heat function, that is, the heat retaining function, which expels the heat in the cold state, is provided, it is possible to operate more stably and thus deterioration of the board can be suppressed as much as possible. In addition, it is more preferable to provide an anti-static function so as to contribute to stabilization to prevent a short circuit.

The coating layer for this purpose was prepared by mixing 8 parts by weight of sodium silicate, 2.5 parts by weight of oxycarboxylate, 1 part by weight of citronella ) Oil, 1.5 parts by weight of microencapsulated polypropylene yarn of 0.1 탆 length, 3 parts by weight of paraffin wax, 4 parts by weight of polyoxyethylene, 3 parts by weight of propylene glycol, 2.5 parts by weight of N-ethylgavazol methacrylate , 3 parts by weight of sepiolite, 2.5 parts by weight of melamine cyanate, 2.5 parts by weight of tetraisopropyltitanate, and 1.5 parts by weight of mica, and spray-coated at 50-60 占 폚.

Here, the reason why the mixture is heated to the above-mentioned temperature range is to maintain uniform dispersibility and stability while increasing fluidity, wherein the acrylic resin is to maximize the adhesive force, and the methylpentene polymer resin has low viscosity and fluidity It is easy to apply and is added especially to have a very high melting point of 235 ° C, to have excellent mechanical strength at high temperature and to enhance heat resistance stability.

In addition, the sodium silicates are added to enhance the heat stability by inducing gelation to form a film.

In addition, the oxycarboxylate is added to reduce moisture content of the material to reduce voids and thereby increase strength.

The citronella oil is generally added to improve the insect repellency, but in the present invention, it is added in order to promote the viscosity control and the coordination of the inorganic powders.

In addition, a polypropylene yarn having a length of 0.1 mu m and microencapsulated by a Wurster Method can be further added so that heat resistance can be realized in the urethane resin.

The paraffin wax is a phase change material having a phase change temperature range of 20 to 50 ° C. The paraffin wax is a phase change material which accumulates latent heat during heating to prevent the temperature from being deprived, thereby performing a heat holding function for a long time, So that it is added in the present invention for latent heat utilization.

Polyoxyethylene is a kind of polyether which is obtained by polymerization of ethylene oxide with a cationic catalyst. In the present invention, it is added in order to inhibit the generation of static electricity by forming a film in a state of being dissolved in water in a fabric and paper.

In addition, propylene glycol is hygroscopic but has no volatility and is stable to heat and light, so it is used as a solvent to dissolve resin and mix with water, and is added to prevent fungal growth on the surface.

In addition, N-ethyl-carbazole methacrylate is added to prevent cracking by inducing stabilization of the coating layer while enhancing transparency.

Furthermore, sepiolite is referred to as meerschaum, a round tubular variant, and is added to induce dispersion stability and uniform dispersion of the resin composition.

In addition, melamine cyanate is added to reinforce heat resistance. Tetraisopropyltitanate is a coupling agent having an organic titanate structure, which enhances the interfacial adhesion between the polymer resin and the inorganic substance to increase both durability and heat resistance And mica is a kind of silicate minerals which are crushed to a size of 0.1-0.2 μm and sieved and added to enhance surface hardness and heat resistance due to hardness characteristics.

According to the structure of the coating layer, it is possible to contribute to prevention of deterioration of the board using heat resistance and latent heat characteristics.

In order to confirm whether or not the coating layer has latent heat characteristics, that is, heat retainability, a steel plate sample having no coating layer and a steel plate sample having a coating layer were prepared, and heat radiation side was confirmed according to JIS C 6802-1997.

As a result of the measurement, it was confirmed that there was a latent heat characteristic (heat absorption power) when the coating layer was present at 46 W / m.k when there was a coating layer and 58 W / m.k when there was no coating layer.

9, a plurality of radiating fins 2170 are further formed to pass through the inner coating surface of the front door 2134 and the side plate 2138 in order to further enhance the heat radiation characteristic.

That is, the radiating fin 2170 is first formed, and the coating liquid is sprayed to form a coating layer.

At this time, the radiating fins 2170 should protrude more than the surface of the coating layer, thereby increasing the heat radiating effect.

The front door 2134 and the side plate 2138 are formed to have a hollow portion 2172 therein and on the outer surfaces of the front door 2134 and the side plate 2138, It is further preferable that an opening 2174 communicating with the hollow portion 2172 is further formed so that the heat transferred to the hollow portion 2172 can be quickly discharged to the atmosphere.

In this case, it is preferable that the outside of the hollow portion 2172 is entirely opened to reduce the thickness thereof, but this is particularly preferable because it is related to the appearance quality.

In addition, the housing 2130 can be attached to the sound absorbing sheet 2180 along the inner side surface of the side plate 2138, as shown in FIG. 10, to reduce noise generated during operation of the devices mounted therein.

The sound absorbing sheet 2180 is in the form of a gasket and is mounted on the coating layer and along the circumference of the side where the heat radiation fins 2170 are not formed so as not to interfere with the heat radiation fins 2170.

Particularly, the sound absorbing sheet 2180 is not a known non-woven fabric but uses a circular knitted fabric to significantly increase sound absorption and sound insulation effects.

That is, when the yarn is circularly wound through the circular knitting machine, a substantially cylindrical fabric is formed. The material of the fabric is polypropylene yarn, and at least a, b, c, , and c two knitting yarns are knitted into a general fabric, and b and d two knitting yarns are knitted into a denser elastic structure so that the circularly formed polypropylene knitted fabric 2182 is repeatedly formed in a longitudinal direction and compacted, So that the sound absorbing characteristic is improved by making the sound absorbed, i.e., sounding, completely obstructed.

In addition, in order to improve sound absorption characteristics and adhesion properties, the cylindrical polypropylene knitted fabric 2182 is flattened in a radial direction to form a double layer, and the outer surface, that is, the periphery of the double- So that the sound absorbing sheet 2180 according to the present invention can be realized.

In this case, since the cylindrical polypropylene knitted fabric 2182 can not be inflated in a pressed state, it is possible to safely hold the sheet image. In particular, the PET film 2184 is needle-punched for forming voids, Structure.

Then, the generated noise is introduced into the polypropylene knitted fabric 2182 through the needle hole of the PET film 2184, is completely confined, is refracted and reflected inside, loses energy, and is completely cased, and the sound is lost. .

110: Sub-controller 120: Main controller

Claims (1)

A plurality of sub-controllers (110) for performing a state detection of each fire fighting equipment installed in the apartment house and transmitting a state detection signal, receiving an operation control signal to control power on / off of the fire fighting equipment, ); Controller 110 connected to each other through a pair of digital preliminary lines provided in the apartment house, receives and monitors the state detection signal from the sub-controller 110, and generates the operation control signal And a main controller (120) for transmitting to the sub-controller (110); The main controller 120 includes a memory unit 121 for a map DB for storing map information of a managed apartment, including a built-in memory, a tablet PC carried by a worker or an administrator under the control of the main controller 120, A wireless communication unit 122 for communicating with the main controller 120 through the wireless communication unit 122 and a main controller 120 receiving the status detection signal from the sub controller 110, And an alarm generating unit 124 for alarming the peripheral managers to recognize immediately when the abnormality occurs when the main controller 120 reads and emits an emergency bell or blinks the lamp. The sub controller 110 includes a fire controller 111 for receiving a detection signal of the fire fighting equipment and controlling the operation of the fire fighting equipment, a signal processor for signal processing the detection signal received from the fire controller 111, A signal processor 112 for receiving an operation control signal from the main controller 120 and performing signal processing on the received signal and a signal processor 112 for converting the signal processed by the signal processor 112 into a bidirectional signal and transmitting the signal to the main controller 120, And a signal converter 113 for receiving an operation control signal received from the signal processor 120 and transmitting the received operation control signal to the signal processor 112. The status detection signal is a power on / Off state signal of the sprinkler 40, the power on / off state signal of the sprinkler 40, the power on / off state signal of the sprinkler 40, the power on / Off control signal of the fire hydrant 20, the power on / off control signal of the hydrator 20, the power on / off control signal of the sprinkler 40, the power on / The sub controller 110 senses the water pressure of the hydrator 20 and the sprinkler 40 through a hydraulic pressure sensor to generate a state detection signal and outputs the generated state detection signal to the main controller 120 The main controller 120 controls the hydraulic valve opening and closing operations of the hydrants 20 and the sprinkler 40 by receiving an operation control signal from the main controller 120. The main controller 120 controls the hydraulic pressure The power source of the fire alarm 10 is turned off or the power of the fire hydrant 10 is turned off or the power of the sprinkler 40 is off, ON state, Configured to transmit the status detection signal to the control system of the fire department in a wired or wireless communication manner in order to make the fire fighting equipment remotely checkable by the fire department, A remote fire fighting inspection system of a fire fighting system comprising:
Further comprising a check window 210 connected to the digesting pipe 200 at a lower end of the digesting pipe 200 through which a part of the extinguishing pipe 200 is connected and screwed together, A main opening / closing valve 220 is installed on the fire extinguishing pipe 200 in the upper portion and a fixed boss BOS is integrally formed in the fire extinguishing pipe 200 in the direct lower portion where the inspection window 210 is installed A fixing bolt 240 passing through the lower end of the detour guide block 230 constituting the inspection window 210 is bolted through the center of the fixing boss BOS and the detour guide block 230 A check connecting chamber 250 is formed on the opposite side of the opening and a fluid circulation passage 260 is formed in the fixing bolt 240. The check valve 250 is provided on the opposite side of the check connection chamber 250, And four circles (90 degrees) are formed around the circumference of the fluid ring (260) The lower end of the flow spring 280 is fixed on the fixed boss BOS and the lower end of the flow spring 280 is fixed on the fixed boss BOS, The inspection connection chamber 250 is connected to an external inspection pipe 290 and a check valve 300 is installed in the external inspection pipe 290 And a water supply check controller 310 is further installed on the outer circumferential surface of the upper digestion pipe 200 of the inspection window 210. The water supply check controller 310 is configured to be capable of wireless communication with the main controller 120, A water supply sensor 320 is installed in a part of the external check pipe 290 to check the presence or absence of water flowing through the external check pipe 290. The water supply check controller 310 is connected to the main check valve 290, (220), the check valve (300), and the water supply sensor (320) are electrically connected And air control;
The map DB memory unit 121, the wireless communication unit 122, the display unit 123 and the alarm generating unit 124 are mounted on the housing 2130 in a board form to constitute the control unit 100;
The housing 2130 includes a rectangular frame 2132 and a front door 2134 is hingedly fixed to one side of the fixing frame 2132 so as to be openable and closable on the front face of the fixed frame 2132, And a bottom plate 2140 is fixed to the lower surface of the fixed frame 2132. The bottom plate 2140 is fixed to the lower surface of the fixed frame 2132 An upper plate 2142 is fixed to a ceiling facing the bottom plate 2140 and an air suction hole 2138a in the form of a rectangular slit is formed in both side plates 2138. A filter And an indirect cooling unit 2150 is installed on the upper surface of the upper plate 2142. The indirect cooling unit 2150 has a lower portion communicating with the housing 2130 through the upper plate 2142, A suction chamber 2152 in the form of an open rectangular box, Shaped blowing pipe 2154 through which a lower end of the hook shape is inserted and fixed, a blowing fan 2156 installed at the upper end of the blowing pipe 2154, and an exhaust hole 2158 formed in the hook-shaped horizontal portion 2158 of the blowing pipe 2154 2160) and a plurality of outlets (2162) formed on the upper surface of the suction chamber (2152) at a position equivalent to the exhaust hole (2160);
A plurality of radiating fins 2170 are further formed on the inner surfaces of the front door 2134 and the side plates 2138. The front doors 2134 and the side plates 2138 are formed to have a hollow portion 2172 therein, A plurality of openings 2174 communicating with the hollow portion 2172 are formed on the outer surfaces of the front door 2134 and the side plate 2138 to increase the heat radiation performance;
A sound absorbing sheet 2180 is further attached to the inner side surface of the side plate 2138 along the periphery of the side where the heat radiation fins 2170 are not formed so as not to interfere with the heat dissipating fins 2170, A circular polypropylene knitted fabric 2182 knitted repeatedly at a spacing in the longitudinal direction when knitted over the knitted fabric 2100, and the polypropylene knitted fabric 2182 is flattened in the radial direction to form a double layer The PET film 2184 is needle-punched so that a plurality of needle holes are formed on the outer surface of the polypropylene knitted fabric 2182, So that noise can be reduced.

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