KR102097911B1 - Smart switchboard with condensation prevention and fire suppression - Google Patents

Abstract

Disclosed is a system for preventing condensation and suppressing fire of a switchboard which removes the humidity caused by a temperature difference in an enclosed enclosure environment of the switchboard to prevent deterioration, and also distributes a fire extinguishing agent to an area in which the fire occurs in the event of the fire to suppress the fire early.

Description

Smart switchboard with condensation prevention and fire suppression

The present invention relates to a smart switchgear having a condensation prevention and fire suppression device, and more specifically, to condense the condensation water generated inside the switchboard as a heat source of the heating pipe, and also to the electrical connection part of the transformer due to deterioration. It relates to a smart switchgear equipped with a condensation prevention and fire suppression device that initially extinguishes a fire by spraying extinguishing agents into an area where a fire occurs.

The switchgear is a device that supplies high-voltage power supplied from a substation to a commercial voltage by stepping down to a commercial voltage.

The switchboard includes a power receiving 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, and a distribution facility for supplying the stepped-down electricity to the electrical devices in each building. It may include a switch device and other safety devices.

On the other hand, the main causes of electrical fires in the switchgear are short circuit, overcurrent, arc, and earth leakage. In addition, the main cause is also the case due to the environment of the user's surrounding facilities (submerged condition, gas, temperature, poor access to home outlets). Most of the electric fires are fires due to electric deterioration and overload, and it appears that they are closely related to the switchboard.

The switchboard that converts the special high voltage into a commercial low voltage and supplies power to a small area unit or a building unit has a very high risk of fire due to heat generated from high voltage parts such as a high voltage transformer or a switch contact therein. Therefore, in the switchboard or other distribution facilities, an initial fire extinguishing system is necessary as a fire alarm generator for monitoring and early warning of fire accidents.

On the other hand, humidity may be exemplified as a cause of deterioration of the water switchboard in addition to heat generation of the high-pressure component.

The interior of the enclosure constituting the switchboard is usually in a closed structure and isolated from the external environment. In such an environment, the humidity in the air inside the switchboard may rise instantaneously high due to a temperature difference from the outside.

In this environment, for example, if the insulator surrounding the connection part and support part of the switchboard is damaged depending on the service life and installation environment, the connection part is exposed as it is to the moisture that has risen high, which causes an instantaneous arc due to the high voltage discharge phenomenon, resulting in insulation breakdown and fire. Will lead to.

In addition, the condensation phenomenon may be exemplified as a cause of fire in the switchboard. Condensation is caused by the temperature difference inside and outside the switchboard, and condensation water is generated in the ceiling and walls of the enclosure of the switchboard. A short circuit occurs in various electrical connections of the transformer, resulting in a fire.

Conventional fire alarms are usually installed in switchboards, but the fire alarms installed in the switchboards and other facilities only have simple functions such as temperature display and fire alarms in the switchboards, so that condensation water that causes fire may evaporate, or When a fire occurs due to deterioration due to other humidity, etc., it does not implement a technical structure such as extinguishing agent and extinguishing the fire immediately.

Document 1: Korean Patent Office Registration Patent Publication No. 10-0804128 Document 2: Republic of Korea Patent Office Publication No. 10-20110030845

An object of the present invention is to provide a smart switchgear equipped with a condensation prevention and fire suppression device to prevent condensation from being generated by evaporating condensation water generated inside the switchboard as a heat source of a heating pipe.

Another object of the present invention is the risk of fire through the removal of moisture, which is the cause of deterioration, by exhausting the increased moisture in the air inside the switchboard due to the temperature difference in a closed environment inside the switchboard as the heat source of the heating pipe to the outside of the switchboard. It provides a smart switchgear equipped with a condensation prevention and fire suppression device to minimize the.

In addition, the present invention provides a smart switchgear equipped with a condensation prevention and fire suppression device to extinguish a fire by automatically operating a fire extinguisher in the event of a fire in the switchboard.

In addition, the present invention provides a smart switchgear equipped with a condensation prevention and fire suppression device to intensively spray fire extinguishing agents into an area where a fire occurs while dividing the interior of the switchboard into left and right zones.

The present invention is a smart switchgear having a condensation prevention and fire suppression device, the inside of which is provided with a space for installing a transformer, and is covered with a state enclosing the inner ceiling of the enclosure, and the upper surface is open while the enclosure is inside. A heating frame that is installed in a space of the main body frame, which is sealed in a space 26 for storing condensation water falling down from the ceiling of the body frame, and heats the condensation water by evaporating the condensate water. , It is installed in the interior space of the body frame, the humidity sensor to detect the humidity contained in the air present in the space of the body frame, the power supply to the heating pipe according to the signal detected by the humidity sensor to generate heat A control unit, an intake fan installed outside the side plate of the body frame and forcibly intakes air in the interior space of the enclosure into the interior space of the body frame to evaporate moisture into the heat source of the heating pipe, outside the side plate of the body frame The exhaust fan is installed on the inner surface of the side wall of the enclosure, and is installed on the inner side of the side wall of the enclosure, forcibly discharging the air supplied to the interior space of the body frame to the outside of the enclosure by driving the intake fan. Condensation prevention means consisting of a humidity sensor for sensing humidity contained in the sensor and sending a signal to the control unit to automatically supply power to the intake fan and exhaust fan, respectively installed on the left and right sides of the inner wall of the enclosure and the enclosure Fire detection means consisting of a left and right temperature sensor that senses the temperature rise due to a fire in the left or right zone of the interior space and transmits a signal to the control unit, and is mounted on the bottom of the enclosure and approved by the control unit Fire extinguisher that operates automatically with a power supply, one end is connected to the fire extinguisher, the other end is piped to the ceiling of the enclosure to supply the fire extinguishing agent ejected from the fire extinguisher, connected to both ends of the supply pipe, the left side of the ceiling of the enclosure, and It is disposed on the right side respectively, and the left side receives the fire extinguishing agent ejected from the fire extinguisher through the supply pipe, The right branch pipe, the left and right branch pipes, and both ends of the supply pipe are connected to be opened and closed, respectively, and are selectively supplied with power by the operation of the control unit receiving signals sensed by the left and right detection sensors. At least one is installed on the left and right valves and the left and right branch pipes to operate individually and selectively supply the fire extinguishing agent supplied to the supply pipes to the left and right branch pipes, and to the left and right branch lines. It consists of left and right injection nozzles for spraying the supplied fire extinguishing agent, and consists of fire suppression means to intensively spray and extinguish the fire extinguishing agent from the left or right area of the enclosure to the area where the fire occurred, and the bottom surface of the space of the body frame Is characterized in that a taper plate is installed to gradually incline downward from the other side to one side, and a drain pipe is further connected to the other side of the body frame.

First, the present invention prevents condensation from occurring by condensing condensation water as a heat source of the heating pipe, and evaporating the increased moisture in the air inside the switchboard due to the temperature difference in a closed environment inside the switchboard as a heat source for the heating pipe. It has the effect of minimizing the risk of fire by removing moisture, which is the cause of deterioration, by exhausting it to the outside of the switchboard.

In addition, in the event of a fire in the switchboard, the fire extinguisher is automatically activated to immediately extinguish the fire. In addition, the fire extinguishing agent is intensively injected into the area where the fire occurred while the inside of the switchboard is divided into the left and right zones. There is an effect that can increase the efficiency.

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

Attached Figure 1 is a view showing the configuration of a smart switchgear equipped with a condensation prevention and fire suppression device from the front, Figure 2 is a diagram showing the main configuration of Figure 1 in three dimensions, Figure 3 is a partial excerpt of Figure 1 4 is a view showing a plane of the condensation preventing means in FIG. 2.

As shown in Figures 1, 2, 3, 4, the smart switchgear equipped with a condensation prevention and fire suppression device includes a housing 10 that provides a space 12 in which the transformer 200 is installed, Various means for preventing condensation and maintaining humidity and detecting and extinguishing a fire are installed in the inner space 12 of the enclosure 10.

The condensation preventing means 20 prevents condensation water such as dew from forming in the inner space 12 of the enclosure 10 or the like due to a difference in external temperature in the enclosure 10 of the switchboard, so that the condensation water falls to the transformer. It is provided for the purpose of preventing fires such as short circuits.

The condensation preventing means 20 generates condensation by evaporating the condensation water generated on the inner surface of the ceiling to a heat source of the heating pipe 28 in a place where condensation water is generated, especially in the state surrounding the ceiling of the enclosure 10. Will be prevented.

The condensation preventing means 20 is integrally formed along the outer surface of the bottom plate 24 and the bottom plate 24 made of a size sufficient to cover the ceiling 14 of the housing 10 and the The side plate 25 forming the space 26 on the top surface of the bottom plate 24 and the top surface are made of a body frame 22 constructed by opening.

The body frame 22 composed of the bottom plate 24 and the side plate 26 has a structure in which its upper surface is opened, and when the body frame 22 is covered with the ceiling 14 of the enclosure 10, the body frame 22 The space 26 is directly connected to the ceiling 14 of the enclosure 10.

The space 26 of the body frame 24 supports the condensation water generated in the ceiling 14 of the enclosure 10 due to the temperature difference between the inside and outside of the enclosure 10 and prevents the condensation water from falling into the transformer. In addition, it functions as a chamber that stores a certain amount of condensation water.

A heating pipe 28 is arranged on the bottom surface of the space 26 of the body frame 22. The heating pipe 28 is a member that generates heat with an externally applied power source, and has a structure in which a heating wire is embedded in a tube shape.

The heating pipe 28 generates heat with power applied from the outside and evaporates condensation water generated on the ceiling 14 of the enclosure 10. At this time, the condensation water on the inner surface of the ceiling 14 of the enclosure 10 And condensation water dropped in the space 26 of the main frame 22 together.

That is, even if heat is generated in the heating pipe 28, a certain period of time is required to evaporate the condensation water. At this time, some condensation water may fall to the transformer during the evaporation process. Therefore, the condensation water that has fallen by surrounding the ceiling 14 with the main body frame 22 of the present invention is stored in the inner space 26 of the main body frame 22 so that the evaporation is performed to remove condensation water more safely. It is possible.

The bottom plate 24 of the body frame 22 may be configured such that the tapered plate 38 is installed to gradually incline downward from one side to the other.

The taper plate 38 induces condensation water falling into the space of the body frame 22 to flow to the other floor of the body frame 22 on the taper plate 38. In addition, a drain pipe 40 is further connected to the other side of the body frame 22, and the drain pipe 40 discharges condensation water flowing into the bottom of the other side of the body frame 22 to the outside of the enclosure.

That is, even if the condensation water is evaporated with heat generated from the heating pipe 28, when a large amount of condensation water is generated, it does not evaporate, and some condensation water is filled in the space 26 of the body frame 22. The water flows to the other side of the body frame 22 on the taper plate 38 of the body frame 22, and then is guided to be naturally discharged through the drain pipe 40 so that condensation water can be quickly removed.

A humidity sensor 42 is installed inside the body frame 22. The humidity sensor 42 detects the increased humidity in the interior space of the body frame 22 due to the condensation water and the high inflow of air from the enclosure to be described later, outputs a signal to the control unit 90, and outputs a signal to the control unit 90 Receives the detection signal of the humidity sensor 42 and supplies power to the heating pipe 28 installed in the space 26 of the body frame 22, and the heating pipe 28 supplied with power. Is heated and is removed by evaporation of condensed water.

An intake fan 30 is connected to the side plate 25 of the body frame 22. The intake fan 30 automatically operates with the power supplied from the power supply unit 92 according to the signal from the control unit 90, and the air in the inner space 12 of the enclosure 10 is spaced in the body frame 22 ( 26) It is a fan forcibly inspiring.

At this time, the intake fan 30 is selectively operated only when the humidity in the air of the inner space 12 of the enclosure 10 is higher than the set value, and when the intake fan 32 is driven, the main frame 22 The installed heating pipe 28 is driven at the same time to heat the air sucked into the space 26 of the body frame 22 by driving the intake fan 30 to evaporate and remove the moisture contained in the air. .

On the inner wall surface of the inner space 12 of the housing 10, a housing humidity sensor 34 is installed. The enclosure humidity sensor 34 detects the humidity contained in the air in the interior space 12 of the enclosure 10 and transmits a signal to the control unit 90.

The interior space 12 of the enclosure 10 is usually a closed structure, and the humidity in the air in the interior space 12 of the enclosure 10 may rise instantaneously high due to a temperature difference from the outside. When the humidity humidity sensor 34 detects the humidity at this time and sends a signal to the control unit 90, the control unit 90 compares and determines the humidity data value previously input, and then exceeds the input humidity value. Power is automatically supplied to the intake fan 30 and the heating pipe 28 through 92 to automatically remove moisture.

The enclosure humidity sensor 34 can be configured by installing only one in the proper location of the interior space 12 of the enclosure 10, but can effectively detect the humidity generated in the entire interior space 12 of the enclosure 10. It is preferable to install two or more humidity detection sensors 34 above and below the space 12 of the enclosure 10.

One end of the exhaust pipe 33 is coupled to the side plate 25 of the body frame 22, and the other end of the exhaust pipe 33 passes through the side plate 25 of the housing 10, and outside the housing 10 To be connected to the exhaust fan 32 installed in. The exhaust fan 32 exhausts the air heated by the heat source of the heating pipe 28 in the inner space 26 of the body frame 22 to the outside of the enclosure 10.

Meanwhile, the fire extinguishing means 60 is intended to extinguish the fire initially by spraying fire extinguishing agents into the fire generating area when a fire occurs in the transformer 200 due to arc or leakage due to humidity or other high pressure discharge. As provided, the fire suppression means 60 automatically operates with an electric signal applied from the control unit 90 according to the detection signal of the left and right temperature sensor.

The left and right temperature detection sensors 52 and 54 detect when a fire occurs due to a short circuit in a certain area of the inner space 12 of the enclosure 10 and when the temperature of the fired area starts to rise rapidly, Immediately sends a signal to the control unit 90, and the control unit 90 fires the extinguishing agent by operating the fire extinguisher 60, which is a fire suppression means 60, according to the detection signals of the left and right temperature detection sensors 52 and 54. The fire is initially injected to extinguish the fire.

The temperature sensor should induce the fire to be effectively extinguished by spraying the fire extinguishing agent more intensively in the area where the fire occurred, and for this purpose, the present invention is based on the center of the inner space 12 of the housing 10, the left, It is divided into right zones 12a and 12b, and left and right temperature detection sensors 52 and 54 are respectively installed in the left and right zones 12a and 12b, and then one of the left and right zones 12a and 12b is installed. When a fire occurred in one place, the temperature sensor located in the area sensed it and sent it to the control unit to spray the fire extinguishing agent so that the fire extinguishing agent could be injected more intensively into the fire.

The fire suppression means 60 is a means to effectively extinguish a fire by intensively spraying fire extinguishing agents into a fire generating area when a fire occurs in one of the left and right areas of the enclosure.

The fire extinguishing means 60 is a fire extinguisher 62, one end is connected to the fire extinguisher 62, the other end of the supply pipe 64, which is piped to the ceiling 14 of the enclosure 10, the supply pipe 64 of At least one left and right branch pipe (70, 72) composed of left and right valves (66, 68) connected to both ends and at least one of the left and right branch pipes (70, 72) are installed, and the left and right branch pipes ( 70, 72) is composed of left and right nozzles 74, 76 for spraying the fire extinguishing agent.

The left and right valves 66 and 68 are solenoid valves, which are selectively automatically operated by the power supplied by the operation of the control unit 90, and open and close the left and right branch pipes 70 and 72.

When the control unit 90 receives a detection signal applied from any one of the left and right temperature detection sensors 52 and 54, the fire suppression means 60 has the left branch valve 66 and Of the right branch valve 68, the power is applied to the solenoid valve installed in the area where the sensor is located to open and operate the fire extinguisher, and the fire extinguishing agent ejected by the operation of the fire extinguisher 62 is supplied to the supply pipe. It is supplied only to the branch pipe connected to the solenoid valve opened on (64), so that the fire extinguishing agent can be intensively injected into the area where the fire occurred.

That is, for example, when a fire occurs in the right zone of the enclosure, the temperature of the right zone 12b of the enclosure 10 first rises rapidly, and at this time, the right temperature sensor 54 detects the temperature and sends it to the control unit 90. When the signal is transmitted, the control unit 90 supplies power to the right valve 68 to open the signal by the signal from the right temperature sensor 54, and then operates the fire extinguisher 62, through which the fire extinguishing agent is supplied. After passing through the pipe 64, through the right branch pipe 72 connected to the open right valve 68, through the right injection nozzle 78, the fire extinguishing agent is concentrated by spraying the fire extinguishing agent into the right area of the enclosure. This will increase the fire suppression efficiency.

In addition, when a fire occurs in the left zone 12b of the enclosure, in contrast to the above, the control unit 90 opens the left valve 66 to intensively suppress the fire generated from the left side.

When the condensation prevention and fire suppression device of the present invention configured as described above starts condensation water from the ceiling 14 of the enclosure 10 due to an external temperature difference, the condensation water becomes the ceiling (14) of the enclosure 10 ) Is dropped to the bottom of the inner space 26 of the body frame 22 covered.

At this time, the humidity sensor 42 installed inside the body frame 22 detects the increased humidity in the interior space 26 of the body frame 22 due to the generation of condensation water and outputs a signal to the control unit 90 Then, the control unit 90 receives the detection signal of the humidity sensor 42 and supplies power to the heating pipe 28 installed in the space 26 of the main frame 22, and supplies power. The heating pipe 28 is heated and is removed by evaporating condensation water.

On the other hand, if a larger amount of condensation occurs than the amount of evaporation, the condensation water that has not evaporated flows to the other side of the inner space 26 of the main frame 22 by riding on the bottom taper plate 38 of the main frame 22, It is automatically discharged outside the enclosure 10 through the drain pipe 40.

The condensation preventing means 20 may prevent condensation water generated due to an external temperature difference from falling into the transformer 200, thereby preventing a fire hazard due to a short circuit.

On the other hand, if a fire occurs in the transformer due to an arc or discharge, etc. in addition to the condensation water, the fire suppression means 60 immediately operates and extinguishes the fire at an early stage.

That is, for example, as shown in FIG. 5, when a fire occurs in the left zone 12a of the enclosure 10 (S10), the left temperature sensor 66 detects this and sends a signal to the control unit 90 (S20). ).

The control unit 90 compares and determines whether the signal transmitted from the left detection sensor 66 is greater than or equal to a preset temperature and time (S30), and then determines that the signal is transmitted at a set temperature and time or higher, to the left valve (0). The power is supplied to operate open (S40), and then the fire extinguisher 62 is operated (S50).

When the fire extinguisher 62 is operated by the signal of the control unit 90, the fire extinguishing agent is supplied to the left branch line 66 through the open left solenoid valve 62 through the supply line 64, and then the left side. Through the left nozzle 74 installed in the branch valve 70, the fire is intensively injected into the left zone 12a of the enclosure 10 where the fire occurs and extinguish the fire (S60).

In addition, when a fire occurs in the right area 12b of the enclosure 10 as shown in FIG. 6 (S110), the right temperature sensor 54 detects this and transmits a signal to the control unit 90 (S120).

The control unit 90 compares and determines whether the signal transmitted from the right detection sensor 54 is greater than or equal to a preset temperature and time (S130), and then determines that the signal is transmitted at a set temperature and time or higher, to the right valve 68. The power is supplied to open the operation (S140), and then the fire extinguisher 62 is operated (S150).

When the fire extinguisher 62 is operated by the signal of the control unit 90, the fire extinguishing agent is supplied to the right branch valve 72 through the open right valve 68 through the supply pipe 64, and then the right branch Through the right injection nozzle 76 installed on the valve 72, it is intensively sprayed to the right zone 12b of the enclosure 10 where the fire occurs and extinguish the fire (S160).

10: enclosure 12: space
12a: left zone 12b: right zone
20: condensation preventing means 22: body frame
26: space 28: heating pipe
30: intake fan 32: exhaust fan
34: housing temperature sensor 38: taper plate
40: drain pipe 42: humidity sensor
52: left temperature sensor 54: right temperature sensor
60: fire fighting means 62: fire extinguisher
64: Supply piping 66: Left valve
68: right valve 70: left branch piping
72: right branch piping 90: control

Claims (1)

In the smart switchgear equipped with a condensation prevention and fire suppression device,
The housing 10 is provided with a space 12 for installing the transformer 200 therein;
The bottom plate 24 is manufactured to a size sufficient to cover the ceiling 14 of the housing 10, and is integrally formed along the outer surface of the bottom plate 24, and is formed at an upper surface of the bottom plate 24. The side plate 25 and the upper surface forming the space 26 are constructed by opening and covered with the inner ceiling 14 of the enclosure 10 in an enclosed state, and therein the ceiling 14 of the enclosure 10. A body frame 22 in which a space 26 for storing condensation water falling down in a closed state is sealed;
A heating pipe 28 installed in the space 26 of the main frame 22 and heating with evaporated power and heating and condensing condensate water stored in the space 26;
A humidity sensing sensor 42 installed in the inner space 26 of the body frame 22 and detecting humidity contained in air existing in the space 26 of the body frame 22;
A control unit 90 for supplying power to the heating pipe 28 and generating heat according to the signal detected by the humidity sensor 42;
It is installed on the outside of the side plate of the body frame 22 and forcibly intakes air in the inner space 12 of the enclosure 10 into the inner space 26 of the body frame 22, so that the heating pipe 28 An intake fan 30 to evaporate moisture as a heat source;
It is installed connected to the outside of the side plate of the body frame 22 by a connecting pipe (33), and the air supplied to the inner space (26) of the body frame (22) by driving of the intake fan (30) is outside of the housing (10). Exhaust fan 32 forcibly discharged to;
It is installed on the inner surface of the side wall of the housing 10 and detects the humidity contained in the air present in the inner space 12 of the housing 10, and sends a signal to the control unit 90 to transmit the signal to the intake fan 30 and A housing humidity sensor 34 for automatically supplying power to the exhaust fan 42 to remove moisture generated in the space 12 of the housing 10;
A taper plate (38) installed on the bottom plate (24) of the body frame (22) and gradually inclined downwardly from one side to the other to induce condensation water to flow to the other side of the body frame;
A condensation preventing means (20) which is connected to the other side of the body frame (22) and consists of a drain pipe (40) that discharges condensation water flowing to the other side of the body frame (22) to the outside of the enclosure;
It is installed on the left and right sides of the inner wall of the enclosure 10, respectively, and detects the temperature rise due to fire in the left zone 12a or the right zone 12b of the inner space 12 of the enclosure 10, respectively, and controls the control unit. Fire detection means 50 consisting of left and right temperature sensor (52, 54) for transmitting a signal to (90);
A fire extinguisher 62 mounted on the bottom of the housing 10 and automatically operated with power applied from the control unit 90;
One end is connected to the fire extinguisher 62, the other end is piped to the ceiling of the housing 10, the supply pipe 64 for supplying the fire extinguishing agent ejected from the fire extinguisher 62;
Left and right branch pipes connected to both ends of the supply pipe 64 and disposed on the left and right sides of the ceiling of the enclosure 10 respectively, receiving the fire extinguishing agent ejected from the fire extinguisher 62 through the supply pipe 64 (66, 68);
The left and right branch pipes 66 and 68 and both ends of the supply pipe 64 are connected to be open and closed, respectively, and the control unit receiving the signals detected by the left and right detection sensors 56 and 58 ( 90) left and right valves to selectively supply power to each of the operations and operate individually, and to selectively supply the fire extinguishing agent supplied to the supply pipe 64 to the left and right branch pipes 66 and 68, respectively. (70, 72) and;
At least one is installed in the left and right branch pipes 66 and 68, and is composed of left and right spray nozzles 74 and 76 for spraying the fire extinguishing agent supplied to the left and right branch lines 66 and 68. It consists of fire suppression means (60) for intensively spraying and extinguishing the fire extinguishing agent from the left zone (12a) or right zone (12b) of (10) to the fire zone;
The bottom surface of the space 26 of the main frame 22 is tapered plate 38 is installed to gradually incline downward from the other side to one side, and the drain pipe 40 is further provided on the other side of the main frame 22 Smart switchgear with condensation prevention and fire suppression device, characterized in that it is connected and installed.

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