KR102071184B1 - Prevention of deterioration of switchboard and fire suppression system - Google Patents

Abstract

The present invention provides a system for preventing deterioration and suppressing a fire of a switchboard in which humidity generated by a temperature difference in a sealed enclosure internal environment of the switchboard is removed so as to prevent a deterioration occurrence and intensively spray a fire extinguishing medium onto a region in which the fire occurs when the fire occurs, thereby suppressing the fire in an early stage.

Description

{Prevention of deterioration of switchboard and fire suppression system}

The present invention relates to a deterioration prevention and fire suppression system of the switchgear, and in detail, to prevent the deterioration by removing the humidity caused by the temperature difference in the environment inside the enclosure of the switchgear fire extinguishing agent to the zone where the fire occurred in the event of a fire. The present invention relates to a deterioration prevention and fire suppression system of a switchgear capable of extinguishing a fire early by intensively spraying.

The switchgear is a device for stepping down the high voltage power supplied from the substation to commercial voltage and supplying it to the customer.

The switchgear includes: a power supply facility for receiving high voltage power supplied from a substation, a substation facility for stepping down the high voltage power received from the substation to a commercial voltage, a power distribution facility for supplying the stepped electricity to the electric devices in each building, Switch devices and other safety devices.

On the other hand, the main causes of electrical fires in switchgear are short circuit, overcurrent, arc and short circuit. In addition, the main cause is caused by the user's surrounding environment (inundation, gas, temperature, home outlet connection failure). Most of the electric fires have been shown to be closely related to the switchboard due to electric deterioration and fire due to overload.

Switchgear that converts extra high voltage to commercial low voltage and supplies power to small area unit or building unit has a high risk of fire due to heat generation in high voltage parts such as high voltage transformer or switch contact. Therefore, switchboards or other distribution facilities require early suppression of fires as fire alarm generators for early warning of fire accidents.

On the other hand, humidity may be cited as a cause of deterioration of switchgear besides heat generation of high-pressure parts.

The interior of the enclosure constituting the switchboard is normally sealed and isolated from the outside environment. In such an environment, the humidity in the air inside the switchboard may increase momentarily due to a temperature difference with the outside.

In such an environment, for example, if the insulator surrounding the switchboard and the support of the switchboard is damaged according to the service life and the installation environment, the connection is exposed to high moisture, which is rapidly arced by high-pressure discharge, causing breakdown and fire. Will lead to.

Therefore, a fire alarm is normally installed in a switchboard.

The conventional general fire alarm is equipped with a thermometer for detecting the internal temperature of the switchboard and displaying it to the outside, and an alarm buzzer for alarming the arrival of a set temperature value, and allowing the administrator to monitor the temperature of the current switchboard through the thermometer or to fire a fire alarm. The buzzer informs the manager of the switchboard of the fire occurrence, or is not detected as a whole but is detected locally, and the fire zone is not divided due to the comprehensive alarm.

In addition, the fire alarms installed in the conventional switchboard and other facilities have only simple functions such as temperature display and fire alarm in the switchboard. Therefore, when a fire occurs, an administrator must operate a fire extinguisher to respond to a fire accident at the switchboard. Not only is this difficult, there is no means for checking the normal operation of the fire alarm. In addition, conventionally, the receiving device has a problem that the conduction test current is installed as a large analog meta over 25 mA as a large building, and there is no self failure diagnosis notification function, which makes digital communication and control impossible.

Document 1: Korean Patent Office Registered Patent Publication No. 10-0804128

It is an object of the present invention to minimize the risk of fire by reducing the occurrence of deterioration such as sparks in electrical distribution facilities such as transformers by periodically removing the moisture generated by the temperature difference in a sealed environment inside the switchboard which is one of the causes of deterioration. Provides a deterioration protection and fire suppression system for one switchboard.

In addition, the present invention, despite the removal of moisture through the dehumidification device, when a fire occurs in the switchboard due to deterioration, automatically detects this by activating the fire suppression device in the switchboard to prevent deterioration and fire of the switchboard to suppress the fire Provide a suppression system.

In another aspect, the present invention provides a system for preventing deterioration and fire suppression of the switchgear to effectively extinguish the fire by injecting a fire extinguishing agent more intensively in the area where the fire occurred in the state of dividing the inside of the switchboard into left and right sections.

The present invention is a deterioration prevention and fire suppression system of the switchboard is installed in the inner space of the switchgear, installed in a state perpendicular to the wall of the inner space of the enclosure is formed with a moving passage inside the upper and lower The vertical duct, one end is connected horizontally to the upper end of the vertical duct and is installed horizontally long on the inner ceiling of the housing, there is formed a horizontal movement passage connected to the vertical movement passage of the vertical duct and the other end is opened A horizontal duct configured to be installed at an open lower end of the vertical duct and an intake fan for forced intake of air existing in the inner space of the enclosure into a vertical movement path of the vertical duct, and through the hole formed at one side of the vertical duct; Installed in the vertical movement passage of the duct and the vertical movement by the drive of the intake fan Heating coil member for evaporating moisture contained in the air passing through the furnace, through the hole formed on one side of the horizontal duct is inserted into the horizontal movement passage of the horizontal duct and the moisture contained in the air passing through the horizontal movement passage Installed on the other end of the horizontal duct, the humidity control means consisting of an exhaust fan forcibly evacuating the dehumidified air, and installed vertically on the left and right walls of the inner wall of the enclosure, respectively. Fire detection means comprising a left and right temperature detection sensor, respectively installed on the left and right support frame, the left and right support frame, and detecting the temperature rise due to the fire occurring in the left or right zone of the inner space of the enclosure; The control unit for receiving the signal detected by the left and right temperature sensor, it is placed on the bottom of the enclosure Fire extinguisher operated by the signal sent from the control unit, one end is connected to the fire extinguisher, the other end is connected to the supply line piped to the ceiling of the enclosure, both ends of the supply line and the horizontally long on the left and right sides of the ceiling, respectively It is arranged in the longitudinal direction of the left and right branch line, the left and right branch line, the left and right branch line through the supply line, the left and right branch line and the both ends of the supply line are connected to each other so as to open and close the left The left and right to selectively supply power to the left and right branch lines, respectively, by individually receiving power to the operation of the control unit receiving the signal sensed by the right sensing sensor and supplying the fire extinguishing agent supplied to the supply line, respectively. At least one or more valves installed on the right solenoid valve and the left and right branch lines; It consists of a left and right injection nozzle for injecting the extinguishing agent supplied to the side branch line and includes a fire suppression means for intensively spraying extinguishing agent to the area of fire in the left or right section of the enclosure. At least one humidity sensor is installed on the wall of the inner space of the enclosure, and the humidity sensor senses the humidity contained in the air present in the interior space of the enclosure and sends a signal to the controller, wherein the controller controls the humidity. In accordance with the detection signal of the sensing sensor to operate at the same time by supplying power to the intake fan, the heating coil member and the exhaust fan of the humidity control means, the bottom branch line is further piped along the bottom surface of the enclosure, the bottom branch One end of the line is connected to the supply line and the auxiliary solenoid valve 82, the Receiving a fire extinguishing agent passing through the supply line 64 in accordance with the opening operation, the bottom branch line is characterized in that at least one injection nozzle for injecting extinguishing agent is installed.

The present invention has the effect of minimizing the risk of fire by reducing the occurrence of deterioration such as sparks in the electrical distribution facilities such as transformer by periodically removing the moisture generated in the sealed environment inside the switchboard.

In addition, despite the removal of moisture through the dehumidification device, when a fire occurs in the switchboard due to deterioration, it can automatically detect and activate the fire suppression device in the switchboard to extinguish the fire. In addition, it is effective to extinguish the fire early by spraying the fire extinguishing agent more intensively in the area where the fire occurred in the state divided into the right area.

1 is a three-dimensional view showing the overall configuration of the deterioration prevention and fire suppression system of the switchboard.
2 is a side cross-sectional view of FIG.
3 is a front cross-sectional view of FIG.
Figure 4 is a block diagram showing the connection between the control unit and its configuration for automatically implementing the moisture removal and fire detection and fire suppression.
5 to 7 are views showing the flow of the fire suppression process.

Deterioration prevention and fire suppression system proposed by the present invention is equipped with a moisture removing means, the moisture removing means is forced to pass through the heating coil and the silica member in the process of periodically sucking and exhausting the air in the switchboard using a convection method After removing the moisture contained in the air by the exhaust to the switchboard to keep the humidity that causes the deterioration constant.

In addition, even if the moisture is removed, a fire in the switchboard may occur due to a short circuit, arc, or short circuit due to overcurrent.In this case, it is necessary to automatically extinguish the fire at an early stage. When the control unit operates the fire extinguisher, the fire extinguishing agent is supplied to the ceiling of the switchboard through the branch line, and then sprayed through the spray nozzle to automatically extinguish the fire.

In particular, the present invention partitions the space inside the switchboard into two spaces in order to more intensively spray the fire extinguishing agent in the fire generating zone, and concentrates the fire extinguishing agent in the corresponding zone according to the signal detected by the temperature sensor installed in each space It is to increase the fire fighting efficiency by spraying.

On the other hand, the temperature sensor is to continue to detect the temperature to send a signal to the control unit while the fire is fighting.

That is, if the area where the fire occurred is not the ceiling such as the bottom of the enclosure or the inside of the floor where the switchboard is installed, even if the fire extinguishing agent is concentrated in the branch line of the ceiling, the fire extinguishing agent cannot be effectively injected into the fire generating area. The fire extinguishing agent was selected and supplied as an auxiliary branch line installed at the bottom to immediately extinguish a fire that occurred on the bottom of the enclosure or inside the floor where the switchboard was installed.

Hereinafter will be described a specific embodiment of the present invention for realizing the concept presented above.

1 is a view showing in three dimensions the overall configuration of the deterioration prevention and fire suppression system of the switchboard, Figure 2 is a side cross-sectional view of Figure 1, Figure 3 is a view showing a front cross-sectional view of Figure 1, 4 is a block diagram showing the connection relationship between the control unit and its configuration for automatic dehumidification, fire detection and fire suppression.

As shown in Figures 1 to 4, the switchboard deterioration prevention and fire suppression system of the present invention is installed in the inner space 12 of the enclosure 10, the transformer is installed as a device for maintaining humidity, fire detection and suppression , Largely divided into humidity control means 20, fire detection means 50 and fire pressure means (60).

The humidity control means 20 removes moisture contained in the air in the process of periodically sucking and exhausting the air in the interior space 12 of the enclosure 10, and then exhausts it back to the enclosure 10 to cause deterioration. It is a means to keep the humidity constant.

The humidity control means 20 constitutes an external shape with vertical and horizontal ducts (22, 26).

The vertical duct 22 is installed vertically on one wall surface of the inner space 12 of the housing 10, and a vertical movement passage 24 is formed therein, and the upper and lower ends thereof are opened.

The open lower end of the vertical duct 22 is directed toward the bottom of the inner space 12 of the enclosure 10, but is preferably installed to be spaced slightly upward from the bottom of the inner space 12.

The horizontal duct 26 is a structure manufactured so that both ends thereof are open like the vertical duct 22 and a horizontal moving passage 28 is formed therein. The horizontal duct 26 is different from the vertical duct 22. The interior space 12 of the enclosure 10 is configured to be installed horizontally long.

The open end of the horizontal duct 26 is connected to the open upper end of the vertical duct 22 so that the horizontal movement passage 28 of the horizontal duct 26 is the vertical movement passage 24 of the vertical duct 22. To be connected to each other.

An intake fan 32 is installed at an open lower end of the vertical duct 22. The intake fan 32 automatically operates with power supplied from the power supply unit 92 in response to a signal from the control unit 90, and the air in the internal space 12 of the enclosure 10 is inside the vertical duct 22. Forced intake into the vertical movement passage (24).

The intake fan 32 is not continuously driven, but selectively operates only when the humidity in the air of the interior space 12 of the enclosure 10 is higher than the set value, and when the intake fan 32 is driven. The heating coil member 34 installed in the vertical duct 22 and the exhaust fan 42 installed at the outlet of the horizontal duct 26 are also driven by power.

On the other hand, a means for detecting the humidity contained in the air in the interior space 12 of the enclosure 10 is required, for this purpose the present invention constitutes at least one humidity sensor 30.

The humidity sensor 30 may be configured by installing only one at an appropriate position of the interior space 12 of the enclosure 10, but the above-mentioned to effectively detect the humidity generated in the entire interior space 12 of the enclosure 10 The support (30a) is installed in a vertical state in the interior space of the enclosure 10, and at least two or more humidity detection sensors are installed in the support (30a) spaced apart at regular intervals to be used.

The interior space 12 of the enclosure 10 is normally enclosed from the external environment in a sealed structure, and the environment is humidity in the air of the interior space 12 of the enclosure 10 due to a temperature difference from the outside. Can rise immediately. At this time, when the humidity sensor 30 of any one of the humidity detection sensor detects the humidity, the control unit 90 immediately sends a signal, and the control unit 90 compares the humidity data value inputted and then inputs the input. When the humidity exceeds the set humidity value, the power is supplied to the intake fan 32, the heating coil member 34, and the exhaust fan 42 through the power supply unit 92 to operate immediately.

A hole 23 is formed at one side of the vertical duct 22, and the heating coil member 34 is detachably inserted to the outside through the hole 23, and the inserted heating coil member 34 is a vertical duct. It is located in the internal movement passage 24 of (22).

The heating coil member 34 is composed of a heating wire 36 that generates heat by the power supplied from the power supply unit 92, and a coil pipe 38 surrounding the heating wire 36, thereby driving the intake fan 32. As a result, the forced intake air is heated in the movement passage 24 of the vertical duct 22 to evaporate moisture contained in the intake air.

That is, the air that is forced into the moving passage 24 of the vertical duct 22 by the drive of the intake fan 32, the moisture is first removed in the process of passing through the heating coil member 34.

The silica gel member 40 drills a hole 27 in one side of the horizontal duct 26 described above as a dehumidifying material, and is inserted into the inner horizontal moving passage 28 of the horizontal duct 26 through the hole 27. Be sure to

The silica gel member 40 passes through the heating coil member 34 described above, and when the air from which moisture is first removed is introduced into the horizontal movement passage 28 of the horizontal duct 26, the remaining moisture contained in the air is included. Will be removed.

The silica gel member 40 is usually formed in the form of granules as a silicate particle of a strong network made by the reaction of sulfuric acid and sodium silicate. The silica gel member 40 is installed and handled due to the form of granules while passing air. The cover paper 41 is formed of a porous nonwoven fabric through which air is passed, and the silica gel 39 is filled in the cover paper 41. Through this structure, the air passes through the nonwoven fabric 41 and passes through the moving passage 28 of the horizontal duct 26 in the state dehumidified by the silica gel 39.

The exhaust fan 42 is installed at the outlet of the horizontal duct 26 and forcibly exhausts air passing through the horizontal movement passage 28 of the horizontal duct 26 to the internal space 12 of the housing 10. . The exhaust fan 42 is driven by receiving power from the power supply unit 92 according to the signal of the controller 90.

Through the driving of the exhaust fan 42, air passes through the heating coil member 34 of the vertical duct 22, and is forced into the horizontal movement passage 28 of the horizontal duct 26, and then the silica gel member ( In the process of passing through 40, the water is completely exhausted to the interior space 12 of the enclosure 10 in a state where water is completely removed.

At this time, the air discharged to the outlet of the horizontal duct 26 through the exhaust fan 42 is warmed slightly by the heat source of the heating coil member 34, and thus air existing in the bottom of the space 10 of the enclosure 10. The temperature is higher than that of the air chamber. The temperature difference of the air above and below the space 12 of the enclosure 10 induces air circulation through convection to direct air into the vertical and horizontal ducts 22 and 26. By absorbing and exhausting effectively, it is possible to increase the efficiency of removing moisture.

On the other hand, the humidity control means 20 may be configured to further include a ventilation fan (44). The ventilation fan 44 is installed on the wall surface of the enclosure 10. That is, when the air inside the enclosure 10 is continuously warmed by the operation of the humidity control means 20, the temperature of the internal space 12 of the enclosure 10 is increased, and the enclosure is provided through the ventilation fan 44. (10) By forcibly discharging the air inside the outside to keep the temperature of the interior space 12 of the enclosure 10 constant. The ventilation fan 44 sets an operating time in the control unit 90, and when the humidity control means 20 operates, when the operating time set in the control unit 90 is reached, power is supplied and driven to operate the air. Ventilate.

Through the operation of the humidity control means 20, the air present in the interior space 12 of the enclosure 10 is always maintained below a certain humidity to control the humidity causing the deterioration to reduce the risk of fire. have.

On the other hand, not only humidity but also other causes, for example, a fire may occur due to an arc, a short circuit caused by a high-pressure discharge, and in this case, the fire is immediately detected to extinguish the fire early to minimize fire damage.

In order to implement this, the present invention automatically operates in accordance with the detection signal of the fire detection means 50, the fire detection means 50 for detecting a fire in the enclosure 10, the fire suppression means 60 for extinguishing the fire. This is installed more.

The fire detection means 50 is made of a temperature sensor. The temperature sensor detects when the temperature of the fire zone rapidly rises when a fire occurs due to a short circuit in an area of the inner space of the enclosure, and immediately sends a signal to the controller 90, and the controller 90 ) Operates the fire extinguisher 62, which is the fire suppression means 60, in accordance with the detection signal of the temperature sensor to inject fire extinguishing agents into the fire generating zone to extinguish the fire initially.

Since the interior of the enclosure 10 in which the temperature sensor is installed has a large space, it is impossible to detect the temperature difference of the entire area of the interior space 12 of the enclosure 10 using only one temperature sensor.

In particular, the present invention has an object to more effectively extinguish the fire by spraying the fire extinguishing agent more concentrated in the area where the fire occurs, for this purpose the present invention based on the center of the inner space 12 of the housing 10 It is divided into left and right zones 12a and 12b, and left and right branch lines 66 and 68 are respectively installed on the ceilings of the zones 12a and 12b, respectively, and selectively operated according to signals from the control unit 90. The left and right solenoid valves 70 and 72 are selectively supplied with the extinguishing agent and sprayed.

By installing one temperature sensor on the enclosure 10 of the switchboard having such a zone setting, it is impossible to determine in which zone the fire occurred on the left or right side of the enclosure.

Therefore, the temperature detection sensor, which is a fire detection means of the present invention, separately configures left and right temperature detection sensors 56 and 58 in the left and right zones 12a and 12b of the enclosure 10 so that the fire of the enclosure 10 may be reduced. When the internal space 12 occurs in the left zone 12a or the right zone 12b, one of the left and right temperature sensors 56 and 58 senses the temperature rise of the zone and the controller 90 The signal is sent to the control unit, the control unit 90 may inject the fire extinguishing agent to the area in accordance with the detection signal of the sensor.

In addition, the fire may occur anywhere in the upper or lower portion of the transformer 200, and in consideration of this, the left temperature sensor 56 may support the support frame 52 on the left side of the wall of the inner space 12 of the enclosure 10. And a plurality of left temperature sensor 56 above and below the support frame 52.

In addition, the right temperature sensor 58 is also provided with a support frame 54 on the right side of the inner space wall surface of the housing 10, and a plurality of right temperature sensor 58 is installed above and below the support frame 54. Configure. Allows for immediate detection of temperature rise due to fire in the upper and lower spaces of the enclosure.

Through the above fire detection means structure, even if a fire occurs at any position of the transformer, it is possible to accurately determine the ignition zone of the fire and to concentrate fire extinguishing agents into the fire generating area, thereby realizing effective fire suppression.

Fire suppression means 60 is a means for automatically spraying the fire extinguishing agent to the fire generating zone in accordance with the detection signal of the fire detection means (50).

In particular, the fire suppression means 60 transmits a signal by detecting the area where the fire occurred in the state where the internal space 12 of the enclosure 10 is divided into left and right areas 12a and 12b. When the fire extinguishing agent is intensively sprayed only in the fire-generating zone of the left and right zones (12a, 12b) has the purpose to effectively extinguish the fire.

The fire suppression means 60 is connected to both ends of the fire extinguisher 62, one end of the fire extinguisher 62 and the other end of the supply line 64 piped to the ceiling of the housing 10, the supply line 64 And the left and right branch lines 66 and 68, the left and right branch lines 66 and 68 disposed in the longitudinal direction of the enclosure 10 horizontally to the left and right sides of the ceiling 10, respectively, and horizontally. At least one of the left and right solenoid valves 70 and 72 and the left and right branch lines 66 and 68 which connect both ends of the line 64 so as to be opened and closed, and the left and right branch lines 66 , 68, the left and right injection nozzles for injecting the extinguishing agent supplied to (74, 76).

The left and right solenoid valves 70 and 72 are selectively operated by the power applied by the operation of the control unit 90 and open and close the left and right branch lines 66 and 68.

The fire suppression means 60 is the control unit when the control unit 90 receives a detection signal applied from any one of the left temperature sensor 56 or the right temperature sensor 58 of the fire detection means (50) 90, the left branch line 66 and the right branch line 68 is applied to the solenoid valve installed in the area where the sensor is located to open and operate the fire extinguisher at the same time, the fire extinguisher 62 Fire extinguishing agent ejected by the operation of the) is supplied only to the branch line is connected to the open solenoid valve via the supply line 64 can be concentrated spraying the extinguishing agent to the area where the fire occurred.

That is, for example, when a fire occurs in the right zone 12b of the enclosure 10, the temperature of the right zone 12b of the enclosure 10 rises rapidly first, at which time the right sensor 58 detects the temperature. When the signal is sent to the control unit 90, the control unit 90 supplies power to the right control valve 72 as a signal of the right detection sensor 58 to open and then operates the fire extinguisher 62. The fire extinguishing agent passes through the supply line 64, and then through the right branch line 68 connected to the open right solenoid valve 72, through the injection nozzle 76, the right side of the housing 10 in which the fire has occurred. Intensive spraying of extinguishing agents in zone 12b increases fire extinguishing efficiency.

Of course, when a fire occurs in the left section 12a of the enclosure 10, the control unit opens the left control valve 70 to suppress the fire.

On the other hand, a separate auxiliary solenoid valve 82 is further connected to the supply line 64, which is the fire suppression means 60, and is installed close to the auxiliary solenoid valve 82 along the bottom surface of the enclosure 10. The bottom branch line 80 may be installed.

The bottom branch line 80, for example, in the process of extinguishing a fire with extinguishing agent sprayed through one of the left and right branch lines 66 and 68, for example, fire extinguishing sprayed from a transformer or other ceiling. This is a line provided to extinguish fire in case where fire does not reach well.

That is, in the process of extinguishing a fire, the left and right temperature sensors 56 and 58 detect a temperature in real time and send a signal to the control unit 90. When the temperature does not drop in the process of extinguishing a fire, effective fire extinguishing is performed. In this case, if it is determined that the temperature does not fall for a predetermined time or more, the control unit 90 supplies power to the auxiliary solenoid valve 82 installed in the supply line 64 to open it. Through the opening of the auxiliary solenoid valve 82, the extinguishing agent is supplied to the bottom branch line 80 to simultaneously spray the extinguishing agent down the transformer 200 through the injection nozzle 84, thereby realizing the initial suppression of the fire. It was made.

Hereinafter, the operational flow of the deterioration prevention and fire suppression system of the switchboard according to the present invention will be described with reference to FIGS.

As shown in FIG. 5, when a fire occurs in the left region 12a of the enclosure 10 (S10), the left detection sensor 56 detects this and transmits a signal to the controller 90 (S20).

The controller 90 compares and determines whether the signal transmitted from the left detection sensor 56 is greater than or equal to a preset temperature and time (S30), and if it determines that the signal is transmitted more than or equal to the predetermined temperature and time, the left solenoid valve 70 Opening operation by supplying power to (S40), and then fire extinguisher 62 is operated (S50).

When the fire extinguisher 62 is operated by the signal of the controller 90, the extinguishing agent is supplied to the left branch line 66 through the open left solenoid valve 62 via the supply line 64, and then to the left side. Through the left injection nozzle (74) installed in the branch line (66), the fire is concentrated to the left area (12a) of the housing 10 in which the fire occurred (S60).

On the other hand, when the fire occurs in the right region 12b of the enclosure 10 as shown in Figure 6 (S110) and the right detection sensor 58 detects this and sends a signal to the controller 90 (S120).

The controller 90 compares and determines whether the signal transmitted from the right sensor 58 is greater than or equal to a predetermined temperature and time (S130), and if it determines that the signal is transmitted more than or equal to the predetermined temperature and time, the right solenoid valve 72. Opening operation by supplying power (S140), and then operates the fire extinguisher 62 (S150).

When the fire extinguisher 62 is operated by the signal of the controller 90, the extinguishing agent is supplied to the right branch line 68 through the open right solenoid valve 72 via the supply line 64, and then the right side. Through the right injection nozzle 76 installed in the branch line 68 is injected to the right area (12b) of the housing 10 in which the fire occurred and the fire is suppressed (S160).

On the other hand, after the fire is extinguished as shown in FIG. 7 (S210), the control unit 90 determines whether the set fire suppression time has elapsed (S220), and if the fire suppression time set in the control unit 90 elapses, If the temperature is continuously detected by any of the right sensor (56, 58) (S230), it is determined that the fire has not yet been suppressed, in this case, the control unit 90 is the auxiliary solenoid valve installed in the supply line (64) Power supply to the 82 to open (S240), through the opening of the auxiliary solenoid valve 82, the extinguishing agent is supplied to the bottom branch line (80) to extinguish the transformer down through the injection nozzle (84) Simultaneously spraying medicine to extinguish the fire (S250).

10: enclosure 12: internal space
12a: left zone 12b: right zone
20: humidity control means 22: vertical duct
26: horizontal duct 30: humidity sensor
32: intake fan 34: heating coil member
40: silica gel member 42: exhaust fan
50: fire detection means 56: left temperature detection sensor
58: right temperature sensor 60: fire extinguishing means
62: fire extinguisher 64: supply line
66: left branch line 68: right branch line
70: left solenoid valve 72: right solenoid valve
80: bottom branch line 82: auxiliary solenoid valve

Claims (1)

In the deterioration prevention and fire suppression system of the switchboard which is installed in the interior space 12 of the enclosure 10 of the switchboard,
A vertical duct 22 installed vertically on a wall surface of the inner space 12 of the enclosure 10 and having a vertical movement passage 24 formed therein, the upper and lower ends of which are opened;
One end is horizontally connected to the upper end of the vertical duct 22 and installed horizontally long on the inner ceiling of the housing 10, and a horizontal movement passage connected to the vertical movement passage 24 of the vertical duct 22 therein. A horizontal duct 26 formed with an open end 26 and open at the other end thereof;
An intake fan 32 installed at an open lower end of the vertical duct 22 and forcibly inhaling air existing in the internal space 12 of the housing 10 to the vertical movement passage 24 of the vertical duct 22. ;
Passed through the hole 23 formed on one side of the vertical duct 22 is installed in the vertical movement passage 24 of the vertical duct 22 and generates heat with the power applied from the outside of the intake fan 32 A heating coil member 34 for evaporating moisture contained in air passing through the vertical movement passage 24 by driving;
The air is inserted into the horizontal moving passage 28 of the horizontal duct 26 through a hole formed at one side of the horizontal duct 26 and passes through the horizontal moving passage 28 through the heating coil member 34. Silica gel member 40 to remove the moisture contained again;
A process of periodically absorbing and exhausting air in the interior space 12 of the enclosure 10 by configuring an exhaust fan 42 installed at the other open end of the horizontal duct 26 and forcibly evacuating air from which moisture is removed. Humidity control means 20 to remove the moisture contained in the air, and to maintain the constant humidity that causes the deterioration by exhausting again to the enclosure (10);
Left and right support frames 52 and 54 installed vertically on the left and right walls of the inner wall of the enclosure 10, respectively;
Left and right installed on the left and right support frames 52 and 54, respectively, the left to sense the temperature rise due to the fire occurred in the left zone 12a or the right zone 12b of the inner space 12 of the enclosure 10, respectively Fire detection means (50) consisting of right temperature sensor (56, 58);
A controller 90 for receiving a signal detected by the left and right temperature sensors 56 and 58;
A fire extinguisher (62) mounted on the bottom of the enclosure (10) and operating with a signal transmitted from the controller (90);
A supply line 64 having one end connected to the fire extinguisher 62 and the other end piped to the ceiling of the housing 10;
Fire extinguishing agent connected to both ends of the supply line 64 and disposed in the lengthwise direction of the enclosure on the left and right sides of the ceiling of the housing 10, respectively, and ejected from the fire extinguisher 62 through the supply line 64. Left and right branch lines (66, 68) receiving the;
The controller may be connected to both ends of the left and right branch lines 66 and 68 and the supply line 64 so as to be opened and closed, respectively, and receives a signal sensed by the left and right detection sensors 56 and 58. 90, the left and right electronics to selectively supply power to each other to operate individually and to selectively supply the fire extinguishing agent supplied to the supply line 64 to the left and right branch lines 66 and 68, respectively. Valves 70 and 72 and;
At least one or more installed in the left and right branch line (66, 68) and composed of left and right injection nozzles (74, 76) for injecting the extinguishing agent supplied to the left and right branch line (66, 68) And a fire suppression means (60) for extinguishing by intensively spraying extinguishing agent from the left side region (12a) or the right side region (12b) to the zone where the fire has occurred;
At least one humidity sensor 30 is installed on a wall surface of the interior space 12 of the enclosure 10, and the humidity sensor 30 is included in air existing in the interior space 12 of the enclosure 10. Sensing the humidity to send a signal to the control unit 90, the control unit 90 according to the detection signal of the humidity sensor 30, the intake fan 30 and the heating coil of the humidity control means 20 Simultaneously operating power by supplying power to the member 34 and the exhaust fan 42;
A bottom branch line 80 is further piped along the outer surface of the bottom of the enclosure 10, one end of the bottom branch line 80 is connected to the supply line 64 and the auxiliary solenoid valve 82. The fire extinguishing agent passing through the supply line 64 is supplied according to the opening operation of the auxiliary solenoid valve 82, and the bottom branch line 80 has at least one injection nozzle 84 for spraying extinguishing agent. Installed;
Deterioration prevention and fire suppression system of the switchgear, characterized in that the enclosure is installed a ventilation fan forcibly discharging the air inside the enclosure (10) to the outside.

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