KR102624745B1 - Electrical Power Receiving Equipment - Google Patents

Abstract

The present invention relates to a multi-function power receiving equipment for supplying electricity to station facilities.
A bus disconnector room (11a1) that accommodates the insulating gas, a first transformer room (11a2) that communicates with the bus disconnector chamber (11a1) and accommodates the insulating gas, and a first transformer chamber (11a2) that communicates with the first transformer chamber (11a2) and accommodates the insulating gas. a circuit breaker chamber (11a3), a second transformer chamber (11a4) that communicates with the circuit breaker chamber (11a3) and accommodates insulating gas, and a line disconnector chamber (11a5) that communicates with the second transformer chamber (11a4) and accommodates insulating gas. ), a first partition plate 11b installed in the case 11a and dividing the bus disconnector chamber 11a1 and the first transformer chamber 11a2, and a first partition plate 11b installed in the case 11a. A second partition plate 11c is installed in the case 11a to partition the first transformer chamber 11a2 and the breaker chamber 11a3, and a second partition plate 11c is installed in the case 11a to partition the breaker chamber 11a3 from the second transformer chamber 11a4. A GIS main body (11) equipped with a three-partition plate (11d) and a fourth partition plate (11e) built into the case (11a) to partition the second deflector chamber (11a4) and the line disconnector chamber (11a5); A bus disconnector (12) installed in the bus disconnector room (11a1); A first current transformer (13) installed in the first current transformer room (11a2); A circuit breaker (14) installed in the circuit breaker room (11a3); A second transformer (15) installed in the second transformer room (11a4); A line disconnector (16) installed in the line disconnector room (11a5); A GIS (10) consisting of a bushing (17) installed in the line disconnector room (11a5) and protruding to the outside; A transformer (20) electrically connected to the GIS (10); In the multi-function power receiving equipment including a tram line support mechanism (30) that supports a tram line (TL) and a plurality of lead wires (21) drawn from the transformer (20),
The GIS (10) is,
A first check valve (CV1) installed on the first partition plate (11b) to allow insulating gas to flow only from the bus disconnector chamber (11a1) to the first transformer chamber (11a2);
A second check valve (CV2) installed on the second partition plate (11c) to allow insulating gas to flow from the circuit breaker chamber (11a3) only to the first transformer chamber (11a2);
A third check valve (CV3) installed on the third partition plate (11d) to allow insulating gas to flow only from the circuit breaker chamber (11a3) to the second transformer chamber (11a4);
A fourth check valve (CV4) installed on the fourth partition plate (11e) to allow insulating gas to flow only from the line disconnector chamber (11a5) to the second transformer chamber (11a2);
A first control valve (EV1) installed on the first partition plate (11b) to control the flow of insulating gas from the first transformer chamber (11a2) to the bus disconnector chamber (11a1);
A second control valve (EV2) installed in the second partition plate (11c) to control the flow of insulating gas from the first transformer chamber (11a2) to the circuit breaker chamber (11a3);
A third control valve (EV3) installed in the third partition plate (11d) to control the flow of insulating gas from the second transformer chamber (11a2) to the circuit breaker chamber (11a3);
A fourth control valve (EV4) installed on the fourth partition plate (11e) to control the flow of insulating gas from the second transformer chamber (11a2) to the line disconnector chamber (11a5);
It is installed in the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5), respectively, and the internal pressure of the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5) 1st, 2nd, and 3rd pressure sensors (PS1, PS2, PS3) that respectively measure;
A first reference value and a second reference value smaller than the first reference value are set, and measured pressure values are received from the first, second, and third pressure sensors (PS1, PS2, and PS3), and the measurement is made from the first pressure sensor (PS1). If the pressure value is less than the first reference value, the first control valve (EV1) is opened, and if the measured pressure value from the second pressure sensor (PS2) is less than the first reference value, the second control valve (EV2) or the third control is controlled. The valve (EV3) is opened, and if the measured pressure value from the third pressure sensor (PS3) is less than the first reference value, the fourth control valve (EV4) is opened, and the first pressure sensor (PS1) or the second pressure sensor is opened. A control unit (CB) that outputs a warning signal when the measured pressure value from (PS2) or the third pressure sensor (PS3) is less than the second reference value;
Equipped with a transmitter (TR) that wirelessly transmits a warning signal from the control unit (CB) to the outside,
The tram line support mechanism 30,
The first and second vertical supports (31, 31') are provided to face each other, and both ends are installed on the top of the first and second vertical supports (31, 31'), respectively, and the first and second vertical supports (31, 31') are provided to face each other. ), a horizontal support 32 connecting the horizontal support 31, a base 33 provided horizontally at the bottom of the horizontal support 31, and a horizontal support 33 that is movable in the horizontal direction and is fixed to a certain position and is pulled out. Equipped with a plurality of guide insulators (34) supporting the electric wire (21) and a plurality of suspension insulators (36) installed on the horizontal supports (32) and supporting the tram line (TL),
A rotating device 41 is installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 and is driven at regular intervals, and a rotating device 41 is connected to the rotating device 41. a bird repellant (40) having a rotating bar (42) that rotates by ) and a plurality of reflective ribbons (43) installed on the rotating bar (42); a battery 50 installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 to supply power to the rotating device 41; A main movement line 61a provided inside the base body 61, and a plurality of branch movement lines 61b provided inside the base body 61 and branched from the main movement line 61a and exposed to the outside. Equipped with a base body (61) on which the GIS (10) and the transformer (20) are seated; A base 60 consisting of a plurality of nozzles 62 installed on the branch movement line 61b; A power receiving device (70) mounted on the base body (61) and supplying power to station facilities; a cooling water supply device (80) that supplies water to the main moving line (61a) of the base (60); A sprinkler warning device (90) installed on the GIS (10), the transformer (20), and the power receiving device (70) to display a warning display; A temperature sensor 100 installed in the GIS 10, the transformer 20, and the power receiving device 70, respectively; a cooling water controller (110) that receives a temperature value from the temperature sensor (100) and operates a cooling water supply device (80) and a water spray warning device (90) when the temperature value exceeds a standard value; A support bar 121 installed on the base body 61; An ultrasonic sensor 122 installed on the support bar 121 to detect nearby passersby; A danger warning device 120 that is installed on the support bar 121 and outputs a danger warning signal to the surrounding area when it receives a detection signal from the ultrasonic sensor 122; Surveillance camera (130) installed on the support bar (121) to film the surroundings
It is characterized in that it further includes.

Description

Multifunctional electric power receiving equipment for supplying electricity to station facilities {Electrical Power Receiving Equipment}

The present invention relates to a multi-function power receiving equipment for supplying electricity to station facilities.

Subway substations are equipped with power receiving devices (receiving equipment) that receive power from KEPCO to supply power to station facilities.

However, in the past, when the temperature around the power receiving device rises, it cannot be cooled, so there are limitations in ensuring that the power receiving device operates safely.

Additionally, conventionally, when the general public approaches the area around a power receiving device, they are exposed to the risk of an electrical accident.

In addition, substations for subway trains are installed at certain distances to transform electricity received through a KEPCO substation (not shown) into a voltage suitable for use in electric railways and supply it to the tram lines.

At this time, electricity received from the KEPCO substation is supplied to the tram line through a gas insulated switchgear and Scott transformer.

Gas Insulated Switchgear (GIS) is a power switchgear used in indoor and outdoor power plants or substations. It safely opens and closes lines not only in normal conditions under usage conditions, but also in abnormal conditions such as power accidents or short circuits. It is a device that appropriately protects the power system.

Additionally, Scott transformers are used to transform voltage for catenary purposes.

Meanwhile, the lead wire taken out from the Scott transformer is supported by an insulator provided on the catenary support stand and connected to the catenary line. Conventionally, the position of the insulator is fixed, so if the positions between the Scott transformer and the catenary line do not match each other, , there was difficulty in connecting the above-mentioned outgoing wires to the tram lines.

In addition, gas insulated switchgear is filled with insulating gas (SF6: sulfur hexafluoride gas), and if this insulating gas (SF6) leaks to the outside, the insulation performance may deteriorate, causing serious problems such as explosion.

In addition, in the past, when birds approached around a tram line support, the electrical components installed on the tram line support could be easily damaged by the bird.

Republic of Korea Patent Publication No. 10-1411025 Republic of Korea Patent Publication No. 10-1468254

The present invention was invented to solve the above problems, and when the surroundings of the power receiving device 70 for supplying electricity to station facilities and the GIS 10 for supplying electricity to the tram line (TL) are high temperature, it can be quickly It can be cooled, prevents the general public from accessing the power receiving device (70), GIS (10), and transformer (20), safely supports the tram line (TL), and removes the lead wire (21) from the transformer (20). It can be conveniently connected to the tram line (TL), and the insulation gas in the 1st and 2nd transformer rooms (11a2, 11a4) is used to prevent deterioration of the insulation performance of the equipment in the GIS (10), and the 1st and 2nd transformer rooms ( 11a2, 11a4) to easily fill insulating gas, improve safety through efficient use of insulating gas, and provide 'complex function power receiving equipment' that prevents birds from approaching around the tram line support device (30). Make it a problem you want to solve.

The present invention to solve the above problems,
A bus disconnector room (11a1) that accommodates the insulating gas, a first transformer room (11a2) that communicates with the bus disconnector chamber (11a1) and accommodates the insulating gas, and a first transformer chamber (11a2) that communicates with the first transformer chamber (11a2) and accommodates the insulating gas. a circuit breaker chamber (11a3), a second transformer chamber (11a4) that communicates with the circuit breaker chamber (11a3) and accommodates insulating gas, and a line disconnector chamber (11a5) that communicates with the second transformer chamber (11a4) and accommodates insulating gas. ), a first partition plate 11b installed in the case 11a and dividing the bus disconnector chamber 11a1 and the first transformer chamber 11a2, and a first partition plate 11b installed in the case 11a. A second partition plate 11c is installed in the case 11a to partition the first transformer chamber 11a2 and the breaker chamber 11a3, and a second partition plate 11c is installed in the case 11a to partition the breaker chamber 11a3 from the second transformer chamber 11a4. A GIS main body (11) equipped with a three-partition plate (11d) and a fourth partition plate (11e) built into the case (11a) to partition the second deflector chamber (11a4) and the line disconnector chamber (11a5); A bus disconnector (12) installed in the bus disconnector room (11a1); A first current transformer (13) installed in the first current transformer room (11a2); A circuit breaker (14) installed in the circuit breaker room (11a3); A second transformer (15) installed in the second transformer room (11a4); A line disconnector (16) installed in the line disconnector room (11a5); A GIS (10) consisting of a bushing (17) installed in the line disconnector room (11a5) and protruding to the outside; A transformer (20) electrically connected to the GIS (10); In the multi-function power receiving equipment including a tram line support mechanism (30) that supports a tram line (TL) and a plurality of lead wires (21) drawn from the transformer (20),
The first partition plate (11b) partitions the bus disconnector chamber (11a1) and the first transformer chamber (11a2) so that the bus disconnector chamber (11a1) and the first transformer chamber (11a2) do not communicate,
The second partition plate (11c) partitions the first transformer chamber (11a2) and the circuit breaker chamber (11a3) so that the first transformer chamber (11a2) and the circuit breaker chamber (11a3) do not communicate,
The third partition plate 11d partitions the circuit breaker chamber 11a3 and the second transformer chamber 11a4 so that the circuit breaker chamber 11a3 and the second transformer chamber 11a4 do not communicate,
The fourth partition plate 11e divides the second transformer chamber 11a4 and the line disconnector chamber 11a5 so that the second transformer chamber 11a4 and the line disconnector chamber 11a5 do not communicate,
GIS(10) is,
A first check valve (CV1) installed on the first partition plate (11b) to allow insulating gas to flow only from the bus disconnector chamber (11a1) to the first transformer chamber (11a2);
A second check valve (CV2) installed on the second partition plate (11c) to allow insulating gas to flow from the circuit breaker chamber (11a3) only to the first transformer chamber (11a2);
A third check valve (CV3) installed on the third partition plate (11d) to allow insulating gas to flow only from the circuit breaker chamber (11a3) to the second transformer chamber (11a4);
A fourth check valve (CV4) installed on the fourth partition plate (11e) to allow insulating gas to flow only from the line disconnector chamber (11a5) to the second transformer chamber (11a2);
A first control valve (EV1) installed on the first partition plate (11b) to control the flow of insulating gas from the first transformer chamber (11a2) to the bus disconnector chamber (11a1);
A second control valve (EV2) installed in the second partition plate (11c) to control the flow of insulating gas from the first transformer chamber (11a2) to the circuit breaker chamber (11a3);
A third control valve (EV3) installed in the third partition plate (11d) to control the flow of insulating gas from the second transformer chamber (11a2) to the circuit breaker chamber (11a3);
A fourth control valve (EV4) installed on the fourth partition plate (11e) to control the flow of insulating gas from the second transformer chamber (11a2) to the line disconnector chamber (11a5);
It is installed in the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5), respectively, and the internal pressure of the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5) 1st, 2nd, and 3rd pressure sensors (PS1, PS2, PS3) that respectively measure;
A first reference value and a second reference value smaller than the first reference value are set, and measured pressure values are received from the first, second, and third pressure sensors (PS1, PS2, and PS3), and the measurement is made from the first pressure sensor (PS1). If the pressure value is less than the first reference value, the first control valve (EV1) is opened, and if the measured pressure value from the second pressure sensor (PS2) is less than the first reference value, the second control valve (EV2) or the third control is controlled. The valve (EV3) is opened, and if the measured pressure value from the third pressure sensor (PS3) is less than the first reference value, the fourth control valve (EV4) is opened, and the first pressure sensor (PS1) or the second pressure sensor is opened. A control unit (CB) that outputs a warning signal when the measured pressure value from (PS2) or the third pressure sensor (PS3) is less than the second reference value;
Equipped with a transmitter (TR) that wirelessly transmits a warning signal from the control unit (CB) to the outside,
The tram line support mechanism 30 is,
The first and second vertical supports (31, 31') are provided to face each other, and both ends are installed on the top of the first and second vertical supports (31, 31'), respectively, and the first and second vertical supports (31, 31') are provided to face each other. ), a horizontal support 32 connecting the horizontal support 31, a base 33 provided horizontally at the bottom of the horizontal support 31, and a horizontal support 33 that is movable in the horizontal direction and is fixed to a certain position and is pulled out. Equipped with a plurality of guide insulators (34) supporting the electric wire (21) and a plurality of suspension insulators (36) installed on the horizontal supports (32) and supporting the tram line (TL),
A rotating device 41 installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 and driven at regular intervals, and a rotating device 41 connected to the rotating device 41. A bird repellant (40) having a rotating bar (42) rotated by and a plurality of reflective ribbons (43) installed on the rotating bar (42); a battery 50 installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 to supply power to the rotating device 41; A main moving line 61a provided inside the base body 61, and a plurality of branch moving lines 61b provided inside the base body 61 and branched from the main moving line 61a and exposed to the outside. Equipped with a base body (61) on which the GIS (10) and the transformer (20) are seated; A base 60 consisting of a plurality of nozzles 62 installed on the branch movement line 61b; A power receiving device (70) mounted on the base body (61) and supplying power to station facilities; a cooling water supply device (80) that supplies water to the main moving line (61a) of the base (60); A sprinkler warning device (90) installed on the GIS (10), the transformer (20), and the power receiving device (70) to display a warning display; A temperature sensor 100 installed in the GIS 10, the transformer 20, and the power receiving device 70, respectively; a cooling water controller (110) that receives a temperature value from the temperature sensor (100) and operates a cooling water supply device (80) and a water spray warning device (90) when the temperature value exceeds a standard value; A support bar 121 installed on the base body 61; An ultrasonic sensor 122 installed on the support bar 121 to detect nearby passersby; A danger warning device 120 that is installed on the support bar 121 and outputs a danger warning signal to the surrounding area when it receives a detection signal from the ultrasonic sensor 122; Surveillance camera (130) installed on the support bar (121) to film the surroundings
It is characterized in that it further includes.

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The present invention, which is a means of solving the above problem, safely supports the tram line (TL) through the tram line support mechanism 30, and moves the position of the guide insulator 34 to protect the transformer 20 and the tram line (TL). There is an effect that the outgoing wire 21 of the transformer 20 and the tram line (TL) can be conveniently connected to suit various installation environments.

In addition, the present invention provides a first current transformer chamber (11a2) in which arcs are relatively less generated when there is a shortage of insulating gas in the bus disconnector room (11a1) and circuit breaker room (11a3) and the line disconnector room (11a5) where arcs are easily generated. ) and the insulating gas in the second transformer room (11a4) is transferred to the bus disconnector room (11a1) and circuit breaker room (11a3) and the line disconnector room (11a5), and the bus disconnector room (11a1) and circuit breaker room (11a3) ) and the deterioration of the insulation performance of the line disconnector room (11a5) is effectively prevented and safety is improved.

In addition, the present invention includes first, second, third, fourth check valves (CV1, CV2, CV3, CV4) and first, 2, 3, and 4 control valves (EV1, EV2, EV3, EV4) are installed, and the first deflector chamber (11a2) and 2. The insulating gas in the current transformer room (11a4) is efficiently utilized, and the first, second, third, and fourth check valves (CV1, CV2, CV3, and CV4) are used to connect the first transformer room (11a2) and the second transformer room ( 11a4) It has the effect of efficiently filling the interior with insulating gas.

In addition, the present invention, even if a separate pressure sensor is not installed in the first transformer chamber (11a2) and the second transformer chamber (11a4), the bus disconnector chamber (11a1), the circuit breaker chamber (11a3), and the line disconnector chamber By checking the pressure state within (11a5), it is possible to know the insulating gas filling state (insufficient gas state) of the first transformer chamber (11a) and the second transformer chamber (11a4).

In addition, the present invention can repel birds through the bird repellant (40), which has the effect of safely protecting the structure installed in the tram line support mechanism (30).

In addition, the present invention has the effect of protecting the GIS 10, the transformer 20, and the power receiving device 70 from surrounding high temperatures, and preventing surrounding people from coming into contact with water when spraying water.

In addition, the present invention has the effect of preventing the general public from being exposed to danger by preventing the general public from approaching the area around the composition of the present invention.

In addition, the present invention has the effect of capturing the surrounding situation and accurately identifying the cause of the problem when a problem occurs.

1 is a diagram schematically showing the interconnection relationship between the components of the present invention,
Figure 2 is a partial cross-sectional view for explaining the guide insulator part in Figure 1;
Figure 3 is a side view for explaining the tram line support mechanism of the present invention,
Figure 4 is a diagram showing a portion of Figure 3,
Figure 5 is a diagram for explaining the bird repellant portion in Figure 1;
Figure 6 is a diagram for explaining the GIS of the present invention,
Figure 7 is a schematic diagram of Figure 6;
Figure 8 is a diagram for explaining the control structure of the control unit according to the present invention,
Figure 9 is a partial cross-sectional view for explaining the base portion of the present invention,
Figure 10 is a diagram for explaining the control structure of the cooling spray controller according to the present invention,
Figure 11 is a diagram for explaining the risk warning mechanism part of the present invention,
12 to 17 are diagrams for explaining the operation of the present invention.

Hereinafter, the present invention will be described so that those skilled in the art can easily implement it.

Figure 1 is a diagram schematically showing the interconnection relationship between the components of the present invention, Figure 2 is a partial cross-sectional view for explaining the guide insulator portion in Figure 1, and Figure 3 is a side view for explaining the tram line support mechanism of the present invention. FIG. 4 is a view showing a portion of FIG. 3, FIG. 5 is a view for explaining the bird repellant portion in FIG. 1, FIG. 6 is a view for explaining the GIS of the present invention, and FIG. 7 is an outline of FIG. 6. Figure 8 is a diagram for explaining the control structure of the control unit according to the present invention, Figure 9 is a partial cross-sectional view for explaining the base portion of the present invention, and Figure 10 is a cooling spray according to the present invention. Figure 11 is a diagram for explaining the control structure of the controller, and Figure 11 is a diagram for explaining the hazard warning mechanism part of the present invention. The configuration of the present invention will be described with reference to Figures 1 to 11 as follows. Meanwhile, in the present invention, the directionality of the configuration of the present invention will be explained by taking the X-axis direction in FIG. 3 as the front-back direction and the Z-axis direction in FIG. 3 as the up-down direction.

The multi-function power receiving equipment according to the present invention includes a GIS (10), a transformer (20), a tram line support mechanism (30), a bird repellant (40), a battery (50), a base (60), and a water faucet. Device 70, cooling water supply device 80, water spray warning device 90, temperature sensor 100, cooling water controller 110, hazard warning mechanism 120, and surveillance camera 130. Includes. Meanwhile, in the present invention, the electrical connection structure of the GIS 10, the transformer 20, and the tram line (TL) is schematically shown.

As shown in FIGS. 1, 6, 7, and 8, the GIS (10) includes a GIS main body (11), a bus disconnector (12), a first transformer (13), and a circuit breaker (14). ), a second current transformer (15), a line disconnector (16), a bushing (17), a repair welding ground switch (18), and a line welding ground switch (19).

The GIS main body 11 is equipped with a case 11a, a first partition plate 11b, a second partition plate 11c, a third partition plate 11d, and a fourth partition plate 11e. .

The case 11a includes a bus disconnector chamber 11a1 in which insulating gas (SF6) is accommodated, a first transformer chamber 11a2 in communication with the bus disconnector chamber 11a1 and accommodating the insulating gas, and a first transformer. A circuit breaker chamber (11a3) that communicates with the chamber (11a2) and accommodates the insulating gas, a second transformer chamber (11a4) that communicates with the circuit breaker chamber (11a3) and accommodates the insulating gas, and a second transformer chamber (11a4) It is equipped with a line disconnector room (11a5) where insulating gas is accommodated.

The first partition plate 11b is installed inside the case 11a and partitions the bus disconnector chamber 11a1 and the first deflector chamber 11a2. In the present invention, the first partition plate (11b) partitions the bus disconnector chamber (11a1) and the first transformer chamber (11a2) so that the bus disconnector chamber (11a1) and the first transformer chamber (11a2) do not communicate.

The second partition plate 11c is built into the case 11a and partitions the first current transformer chamber 11a2 and the circuit breaker chamber 11a3. In the present invention, the second partition plate 11c partitions the first deflector chamber 11a2 and the breaker chamber 11a3 so that the first deflector chamber 11a2 and the breaker chamber 11a3 do not communicate.

The third partition plate 11d is built into the case 11a and partitions the circuit breaker chamber 11a3 and the second transformer chamber 11a4. In the present invention, the third partition plate 11d partitions the circuit breaker chamber 11a3 and the second current transformer chamber 11a4 so that the circuit breaker chamber 11a3 and the second current transformer chamber 11a4 do not communicate with each other.

The fourth partition plate 11e is built into the case 11a and divides the second transformer chamber 11a4 and the line disconnector chamber 11a5. In the present invention, the fourth partition plate 11e partitions the second transformer chamber 11a4 and the line disconnector chamber 11a5 so that the second transformer chamber 11a4 and the line disconnector chamber 11a5 do not communicate.

The bus disconnector 12 is installed in the bus disconnector room 11a1. In the present invention, the bus disconnector 12 is used to open and close a circuit in a no-load state and disconnects the circuit going from the bus ML to the first current transformer 13.

The first current transformer 13 is installed in the first current transformer chamber 11a2. In the present invention, the first current transformer 3 converts current.

The circuit breaker 14 is installed in the circuit breaker room 11a3. In the present invention, the circuit breaker 14 operates momentarily to block the current when an abnormality occurs in the power system, and the power system can be protected by the operation of the circuit breaker 14.

The second current transformer 15 is installed in the second current transformer chamber 11a4. In the present invention, the second current transformer 15 converts current.

The line disconnector 16 is installed in the line disconnector room 11a5. In the present invention, the line disconnector 16 completely disconnects the power outage part from the power source when inspecting or repairing the equipment, or opens and closes the no-load circuit for the transfer of substation facilities.

The bushing 17 is installed in the line disconnector room 11a5 and protrudes outward.

The maintenance ground switch 18 is installed above the first bus disconnector room 11a1 and the line disconnector room 11a5, respectively, and grounds the circuit under abnormal conditions.

The line grounding switch 19 is installed below the line disconnector room 11a5, and grounds the line under abnormal conditions.

Meanwhile, as shown in FIG. 6, the present invention includes a bus disconnector 12, a first transformer 13, a circuit breaker 14, a second transformer 15, a line disconnector 16, and a bushing 17. , a line is formed through the connection between the repair welding ground switch (18) and the line welding ground switch (19).

In addition, the present invention includes a bus disconnector (12), a first transformer (13), a circuit breaker (14), a second transformer (15), a disconnector for a line (16), a bushing (17), and a maintenance welding ground switch (18). ), In addition to the line welding ground switch (19), the usual configuration to perform the GIS (Gas Insulated Switchgear) function is included. And for the well-known configuration according to the present invention, refer to Republic of Korea Patent Publication No. 10-1468254.

In addition, the GIS (10) of the present invention includes 1st, 2nd, 3rd, and 4th check valves (CV1, CV2, CV3, CV4) and 1st, 2nd, 3rd, and 4th control valves (EV1, EV2, EV3, EV4). Wow, it is equipped with the second and third pressure sensors (PS1, PS2, PS3).

The first check valve (CV1) is installed on the first partition plate (11b) and allows the insulating gas to flow only from the bus disconnector chamber (11a1) to the first transformer chamber (11a2).

The second check valve (CV2) is installed in the second partition plate (11c) and allows the insulating gas to flow from the circuit breaker chamber (11a3) only to the first transformer chamber (11a2).

The third check valve (CV3) is installed in the third partition plate (11d) and allows the insulating gas to flow from the circuit breaker chamber (11a3) only to the second transformer chamber (11a4).

The fourth check valve (CV4) is installed on the fourth partition plate (11e) and allows the insulating gas to flow from the line disconnector chamber (11a5) only to the second transformer chamber (11a2).

The first control valve EV1 is installed on the first partition plate 11b and controls the flow of insulating gas from the first transformer chamber 11a2 to the bus disconnector chamber 11a1. In the present invention, the first control valve (EV1) is of the electromagnetic valve type, and its operation is controlled by the control unit (CB).

The second control valve (EV2) is installed on the second partition plate (11c) and controls the flow of insulating gas from the first transformer chamber (11a2) to the circuit breaker chamber (11a3). In the present invention, the second control valve (EV2) is of the electromagnetic valve type, and its operation is controlled by the control unit (CB).

The third control valve EV3 is installed on the third partition plate 11d and controls the flow of insulating gas from the second transformer chamber 11a2 to the circuit breaker chamber 11a3. In the present invention, the third control valve (EV3) is of the electromagnetic valve type, and its operation is controlled by the control unit (CB).

The fourth control valve EV4 is installed on the fourth partition plate 11e and controls the flow of insulating gas from the second transformer chamber 11a2 to the line disconnector chamber 11a5. In the present invention, the fourth control valve (EV4) is of the electromagnetic valve type, and its operation is controlled by the control unit (CB).

The first, second, and third pressure sensors (PS1, PS2, and PS3) are installed in the bus disconnector room 11a1, the circuit breaker room 11a3, and the line disconnector room 11a5, respectively. ) and measure the internal pressure of the circuit breaker room (11a3) and the line disconnector room (11a5), respectively.

The control unit (CB) is configured to set a first reference value and a second reference value smaller than the first reference value, and receives measured pressure values from the first, second, and third pressure sensors (PS1, PS2, and PS3). If the measured pressure value from the pressure sensor (PS1) is less than the first reference value, the first control valve (EV1) is opened, and if the measured pressure value from the second pressure sensor (PS2) is less than the first reference value, the second control is performed. The valve (EV2) or the third control valve (EV3) is opened, and if the measured pressure value from the third pressure sensor (PS3) is less than the first reference value, the fourth control valve (EV4) is opened, and the first pressure sensor (PS3) is opened. If the measured pressure value from (PS1), second pressure sensor (PS2), or third pressure sensor (PS3) is less than the second reference value, a warning signal is output. In the present invention, the first and second reference values are set in various ways as needed, and the control unit (CB) is installed in the control panel (CS) arranged around the GIS main body (10).

The transmitter (TR) wirelessly transmits a warning signal from the control unit (CB) to the outside. In the present invention, the transmitter (TR) is installed in the control panel (CS) and controlled by the control unit (CB).

The transformer 20 is electrically connected to the GIS 10, as shown in FIG. 1. In the present invention, the transformer 20 is a Scott transformer, and a plurality of lead wires 21 are drawn out and connected to the tram line TL.

As shown in FIG. 1, the tram line support mechanism 30 supports the tram line TL and a plurality of lead wires 21 drawn from the transformer 20.

In the present invention, the tram line support mechanism 30 includes first and second vertical supports 31 and 31', horizontal supports 32, base 33, guide insulator 34, and suspension insulator 36. Equipped with

The first and second vertical supports 31 and 31' are provided to face each other. In the present invention, the first and second vertical supports 31 and 31' are installed on the ground in a vertical direction (up and down).

The horizontal supports 32 are installed at both ends on top of the first and second vertical supports 31 and 31', respectively, and connect the first and second vertical supports 31 and 31'.

The base 33 is provided in the horizontal direction (forward-backward direction) at the lower part of the horizontal support 31. In the present invention, the base 33 has a plate shape, and a guide groove 33a is formed along the horizontal direction. In the present invention, the guide groove (33a) may have a 'T'-shaped cross section. Meanwhile, in the present invention, the base 33 can be detachably installed on the horizontal support 31.

The guide insulator 34 is installed on the base 33 to be movable in the horizontal direction (front-back direction) and fixable at a certain position, and supports the lead wire 21. In the present invention, a plurality of guide insulators 34 are provided. In the present invention, the guide insulator 34 is provided with a 'T' shaped insertion part 34a at the top, and the insertion part 34a is movably inserted into the guide groove 33a. Meanwhile, in the present invention, a plurality of separate fixtures 35 are provided, and each fixture 35 is fastened with a through thread to the base 33a to pressurize and secure each of the plurality of insertion portions 34a. In the present invention, when the position of the guide insulator 34 is fixed through a pressurizing method according to the fixture 35, the base 33a is provided with a plurality of screw holes in the horizontal direction. In addition, in the present invention, various conventional methods can be applied to fixing the position of the guide insulator 34.

The suspension insulator 36 is installed on the horizontal support 32 and supports the tram line TL. In the present invention, a plurality of suspension insulators 36 are provided.

As shown in FIGS. 1 and 5, the bird repellant 40 includes a rotating device 41, a rotating bar 42, and a reflective ribbon 43.

The rotating device 41 is installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 and is driven at regular intervals. In the present invention, the rotating device 41 has a timer function and is driven at regular intervals. For example, the rotating device 41 may be set to operate only from 7 a.m. to 7 p.m. Meanwhile, in the present invention, the rotating device 41 may be a motor, but various driving methods can be applied as long as the rotating bar 42 can be rotated.

The rotation bar 42 is connected to the rotation device 41 and rotates by the rotation device 41. In the present invention, the rotating bar 42 is connected to the rotating shaft (not shown) of the rotating device 41.

The reflective ribbon 43 is installed on the rotating bar 42. In the present invention, a plurality of reflective ribbons 43 are provided, and a reflective material is applied to the surface.

As shown in FIGS. 1 and 5, the battery 50 is installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32, and is attached to the rotating device 41. Supply power. In the present invention, as long as power can be supplied to the rotating device 41, various power supply devices other than the battery 50 can be applied.

Meanwhile, in the present invention, the bird repellant 40 and the battery 50 are shown as being installed on the first vertical support 31, but they can be installed at various positions of the tram line support mechanism 30.

The base 60 includes a base body 61 and a nozzle 62, as shown in FIGS. 1 and 9.

The base body 61 includes a main moving line 61a provided inside the base body 61, and a plurality of main moving lines 61a provided inside the base body 61 and branched from the main moving line 61a and exposed to the outside. It is equipped with a branch movement line (61b), and the GIS (10) and transformer (20) are installed and placed. In the present invention, it may be in the form of a main movement line (61a) and a branch movement line (61b) piping. Meanwhile, in the present invention, the base body 61 is made of an insulating material. Meanwhile, when spraying (spraying) water, the branch moving line (61b) is preferably placed in a position where the sprayed water does not directly contact the GIS (10), the transformer (20), and the power receiving device (70).

The nozzle 62 is installed on the branch movement line 61b. In the present invention, a plurality of nozzles 62 are provided.

As shown in FIG. 1, the power receiving device 70 is mounted on the base body 61 and supplies power to station facilities. In the present invention, the power receiving device 70 receives electricity from KEPCO and supplies it to station facilities. Station facilities refer to various equipment such as lighting, station facilities, and computer equipment.

As shown in FIGS. 9 and 10, the cooling water supply device 80 supplies water (cooling water) to the main moving line 61a of the base 60. In the present invention, the cooling water supply device 80 is connected to the main moving line (61a) to supply water. Meanwhile, in the present invention, the cooling water supply device 80 is equipped with a water supply pump and a control valve, and when the control valve is opened, water is supplied to the main movement line 61a.

As shown in FIGS. 1 and 9, the sprinkler warning device 90 is installed on the GIS 10, the transformer 20, and the power receiving device 70, respectively, to display a warning. In the present invention, the sprinkler warning device 90 may be a warning light, a warning sound device, or a laser display device. Meanwhile, in the present invention, if the spray warning device 90 can perform a warning function, its installation location can be modified in various ways. If the spray warning device 90 is a laser display device, the base body 61 is transmitted through a laser. Warning signs can be placed on the top or surrounding ground.

As shown in FIGS. 1 and 9, the temperature sensor 100 is installed in the GIS 10, the transformer 20, and the power receiving device 70, respectively. In the present invention, as long as the temperature sensor 100 can measure the temperature around the base 60, its installation location can be modified in various ways.

As shown in FIG. 10, the cooling water controller 110 receives the temperature value from the temperature sensor 100, and when the temperature value exceeds the reference value, the cooling water supply device 80 and the water spray warning device 90 ) is run. In the present invention, the cooling spray controller 110 may be installed on the base 60, but its installation location may be modified in various ways.

As shown in FIGS. 1 and 11, the danger warning mechanism 120 includes a support bar 12, an ultrasonic sensor 122, and a danger alarm 123.

The support bar 121 is installed on the base body 61. In the present invention, the support bar 121 has a long bar shape and is installed around the GIS 10, the transformer 20, or the power receiving device 70.

The ultrasonic sensor 122 is installed on the support bar 121 and detects nearby passers-by. In the present invention, the ultrasonic sensor 122 outputs a detection signal when it detects a nearby passerby. Meanwhile, in the present invention, various sensing means can be applied to detect nearby passers-by (moving objects).

The danger alarm 123 is installed on the support bar 121 and outputs a danger warning signal to the surrounding area when it receives a detection signal from the ultrasonic sensor 122. In the present invention, the danger alarm 123 may be a voice device that outputs a warning sound or a warning light that outputs a warning light.

As shown in FIGS. 1 and 11, the surveillance camera 130 is installed on the support bar 121 and takes pictures of the surroundings. In the present invention, the surveillance camera 130 is installed at the top of the support bar 121, and stores captured images or transmits the captured images to a separate management center.

Meanwhile, in the present invention, a plurality of hazard warning devices 120 and surveillance cameras 130 may be provided and may be installed in various positions of the base body 61.

FIGS. 12 to 17 are diagrams for explaining the operation of the present invention. The operation of the present invention is explained with reference to FIGS. 12 to 17 as follows.

In the present invention, the position of the guide insulator 34 is adjusted according to the position of the outgoing wire 21 from the transformer 20 or the position of the suspension insulator 36 on which the tram line TL is supported, so that the outgoing wire 21 ) and the tram line (TL) can be connected stably.

That is, the present invention can adjust the position of the guide insulator 34 as shown in FIG. 12 to connect the lead wire 21 and the tram line TL to suit various installation environments.

Hereinafter, the method of maintaining insulation performance according to the movement of insulation gas in the present invention will be described as follows.

According to the present invention, when insulating gas leaks little by little from the bus disconnector chamber 11a1 of the case 11a, the pressure of the busbar disconnector chamber 11a1 is lowered.

At this time, the first pressure sensor (PS1) transmits the measured pressure value of the bus disconnector room (11a1) to the control unit (CB), and the control unit (CB) compares the measured pressure value with a preset first reference value. , if the measured pressure value is lower than the first reference value, the first control valve (EV1) is opened.

Then, the insulating gas contained (filled) in the first current transformer chamber 11a2 of the case 11a moves to the bus disconnector chamber 11a1 through the first control valve EV1 (see arrow direction in FIG. 12). , it is possible to prevent deterioration of the insulation performance of the bus disconnector room 11a1.

In addition, according to the present invention, when insulating gas leaks little by little from the circuit breaker chamber (11a3) of the case (11a), the pressure of the circuit breaker chamber (11a3) decreases.

At this time, the second pressure sensor (PS2) transmits the measured pressure value of the circuit breaker chamber (11a3) to the control unit (CB), and the control unit (CB) compares the measured pressure value with a preset first reference value, If the measured pressure value is lower than the first reference value, the second control valve (EV2) or the third control valve (EV3) is opened, or the second control valve (EV2) and the third control valve (EV3) are opened.

Then, the insulating gas contained (filled) in the first transformer chamber (11a2) and the second transformer chamber (11a4) of the case (11a) passes through the second control valve (EV2) and the third control valve (EV3) to the circuit breaker chamber. By moving to (11a3) (see the arrow direction in FIG. 13), it is possible to prevent deterioration of the insulation performance of the circuit breaker room (11a3).

In addition, according to the present invention, when insulating gas leaks little by little from the line disconnector chamber 11a5 of the case 11a, the pressure of the line disconnector chamber 11a5 is lowered.

At this time, the third pressure sensor (PS3) transmits the measured pressure value of the line disconnector room (11a5) to the control unit (CB), and the control unit (CB) compares the measured pressure value with the preset first reference value. , if the measured pressure value is lower than the first reference value, the fourth control valve (EV4) is opened.

Then, the insulating gas contained (filled) in the second transformer chamber 11a4 of the case 11a moves to the line disconnector chamber 11a5 through the fourth control valve EV4 (see arrow direction in FIG. 13). , it is possible to prevent deterioration of the insulation performance of the line disconnector room 11a5.

In this way, despite moving the insulating gas in the first transformer room (11a2) and the second transformer room (11a4) to the bus disconnector room (11a1), the circuit breaker room (11a3), and the line disconnector room (11a5), When the measured pressure values from the 1st, 2nd, and 3rd pressure sensors (PS1, PS2, and PS3) become lower than the preset second reference value, the control unit (CB) sends the first, second, and third pressure signals to a separate management center via the transmitter (TR). A warning signal corresponding to the 2nd and 3rd pressure sensors (PS1, PS2, PS3) is output. Then, the manager can check this and quickly respond (check) if an insulation problem occurs in the GIS (10).

Meanwhile, in the present invention, after the insulating gas in the first transformer room (11a2) or the second transformer room (11a4) is moved to the bus disconnector room (11a1) or circuit breaker room (11a3) or line disconnector room (11a5), When the internal pressure of the bus disconnector room (11a1), circuit breaker room (11a3), or line disconnector room (11a5) becomes higher again than the preset first reference value, the first control valve (EV1) or the second control valve (EV2) Alternatively, the third control valve (EV3) or fourth control valve (EV4) is closed by the control unit (CB).

In addition, in the present invention, if the insulating gas is insufficient below the standard (second standard value) in the bus disconnector room 11a1 or the circuit breaker room 11a3 or the line disconnector room 11a5, the bus disconnector room 11a1 or the circuit breaker room 11a5 is cut off. Fill the air chamber (11a3) or the line disconnector chamber (11a5) with insulating gas.

At this time, in the present invention, when insulating gas is injected into the bus disconnector chamber (11a1), the insulating gas injected into the busbar disconnector chamber (11a1) is sufficiently injected into the busbar disconnector chamber (11a1) to open the first check valve (CV1). moves to the first deflector chamber (11a2) and fills the first deflector chamber (11a2) (see arrow direction in FIG. 14).

In addition, according to the present invention, when the insulating gas is injected into the breaker chamber (11a3), the insulating gas injected into the breaker chamber (11a3) is sufficiently injected into the breaker chamber (11a3) and is injected into the first transformer chamber through the second check valve (CV2). Move to (11a2) to fill the first transformer chamber (11a2) and move to the second transformer chamber (11a4) through the third check valve (CV3) to fill the second transformer chamber (11a4) (see Figure 14). (see arrow direction)

In addition, according to the present invention, when the insulating gas is injected into the line disconnector room (11a5), the insulating gas injected into the line disconnector room (11a5) is sufficiently injected into the line disconnector room (11a5) to open the fourth check valve (CV4). moves to the second deflector chamber (11a4) and fills the second deflector chamber (11a4) (see arrow direction in FIG. 14).

Meanwhile, the bus disconnector room 11a1, circuit breaker room 11a3, or line disconnector room 11a5 is frequently opened for inspection, etc.

At this time, in the present invention, when the bus disconnector room (11a1) or the circuit breaker room (11a3) or the line disconnector room (11a5) is opened for inspection, the bus disconnector room (11a1) or the circuit breaker room (11a3) or the line disconnector room (11a1) is disconnected. The insulating gas inside the log chamber 11a5 is discharged to the outside. However, the 1st, 2, 3, and 4th compartment plates (11b, 11c, 11d, 11e) are installed with the 1st, 2, 3, and 4th check valves (CV1, CV2, CV3, and CV4), (11a2,11a4) The insulating gas inside is not discharged to the outside.

In addition, in the present invention, when the inspection is completed, the bus disconnector room (11a1) or the circuit breaker room (11a3) or the line disconnector room (11a5) is closed and insulating gas is injected. Insulating gas is injected into (11a3) or the line disconnector room (11a5) through the same process as the above-mentioned insulating gas injection (see FIG. 14).

Meanwhile, with the present invention installed, when the wind blows, the reflective ribbon 43 of the bird repellant 40 flutters, blocking the approach of birds.

In addition, in the present invention, the rotation device 41 of the bird repellant 40 is driven every certain time (for example, during the day), and the rotation bar 42 is rotated as shown in FIG. 15 by driving the rotation device 41. It rotates.

Then, as the reflective ribbon 43 rotates along the rotating bar 42, light reflection is further enhanced, and birds are more effectively prevented from approaching the tram line support mechanism 30.

In addition, the present invention is that, in the state in which the present invention is installed, the surrounding temperature of the GIS 10, the transformer 20, and the electric receiving device 70 increases, and the coolant controller 110 receives the signal from the temperature sensor 100. When a temperature value exceeds the reference value, the coolant controller 110 drives the coolant supply device 80 and the spray warning device 90.

At this time, the cooling water supply device 80 supplies water to the main movement line 61a, and the water passing through the main movement line 61a is sprayed through the branch movement line 61b and the nozzle 62 as shown in FIG. (sprayed), and at the same time, the spray warning device 90 outputs a warning signal (warning light, warning sound) to the surrounding area.

Then, the surroundings of the GIS (10), the transformer (20), and the power receiving device (70) are cooled to increase the safety of the GIS (10), the transformer (20), and the receiving device (70), and the surrounding people can be prevented from entering the water spray point. You can prevent it from coming.

In addition, the present invention is that when the general public approaches the GIS 10, the transformer 20, or the power receiving device 70 while the present invention is installed, the ultrasonic sensor 122 detects this as shown in FIG. 17 and generates a detection signal. Outputs, and the danger notification device 123 that receives this outputs a warning signal (alarm sound) to the surrounding area. Then, the general public can know that there are high-voltage electrical facilities nearby.

And, in the present invention, the surveillance camera 130 takes pictures of the surroundings while the present invention is installed. Therefore, if a problem occurs around the present invention, the problem situation can be accurately confirmed.

As described above, the present invention safely supports the tramline (TL) through the tramline support mechanism 30, and allows the transformer 20 and the tramline (TL) to be installed in various installation environments by moving the position of the guide insulator 34. Correspondingly, there is an effect of conveniently connecting the lead wire 21 of the transformer 20 and the tram line TL.

In addition, the present invention provides a first current transformer chamber (11a2) in which arcs are relatively less generated when there is a shortage of insulating gas in the bus disconnector room (11a1) and circuit breaker room (11a3) and the line disconnector room (11a5) where arcs are easily generated. ) and the insulating gas in the second transformer room (11a4) is transferred to the bus disconnector room (11a1) and circuit breaker room (11a3) and the line disconnector room (11a5), and the bus disconnector room (11a1) and circuit breaker room (11a3) ) and the deterioration of the insulation performance of the line disconnector room (11a5) is effectively prevented and safety is improved.

In addition, the present invention includes first, second, third, fourth check valves (CV1, CV2, CV3, CV4) and first, 2, 3, and 4 control valves (EV1, EV2, EV3, EV4) are installed, and the first deflector chamber (11a2) and 2. The insulating gas in the current transformer room (11a4) is efficiently utilized, and the first, second, third, and fourth check valves (CV1, CV2, CV3, and CV4) are used to connect the first transformer room (11a2) and the second transformer room ( 11a4) It has the effect of efficiently filling the interior with insulating gas.

In addition, the present invention, even if a separate pressure sensor is not installed in the first transformer chamber (11a2) and the second transformer chamber (11a4), the bus disconnector chamber (11a1), the circuit breaker chamber (11a3), and the line disconnector chamber By checking the pressure state within (11a5), it is possible to know the insulating gas filling state (insufficient gas state) of the first transformer chamber (11a) and the second transformer chamber (11a4).

In addition, the present invention can repel birds through the bird repellant (40), which has the effect of safely protecting the structure installed in the tram line support mechanism (30).

In addition, the present invention has the effect of protecting the GIS 10, the transformer 20, and the power receiving device 70 from surrounding high temperatures, and preventing surrounding people from coming into contact with water when spraying water.

In addition, the present invention has the effect of preventing the general public from being exposed to danger by preventing the general public from approaching the area around the composition of the present invention.

In addition, the present invention has the effect of capturing the surrounding situation and accurately identifying the cause of the problem when a problem occurs.

Meanwhile, the present invention is called 'Electricity Supply to Station Facilities' in the sense that it further includes various configurations such as a configuration for supplying electricity to subway trains such as GIS (10) in the structure of a power receiving facility for supplying electricity to station facilities. It is defined as ‘complex function power receiving equipment’, and the subject of claims of the present invention is defined as ‘complex function power receiving equipment’.

10: GIS 11; GIS main body
12: Bus disconnector 13: First transformer
14: breaker 15; 2nd transformer
16: Line disconnector 17: Bushing
18: Repair welding ground switch 19: Line welding ground switch
CV1~CV4: Check valves 1~4 EV1~EV4: Control valves 1~4
PS1~PS3: 1st~3rd pressure sensor CB: Control unit
TR: Transmitter 20: Transformer
30: Tram line support mechanism 31,31': 1st and 2nd vertical supports
32: horizontal support 33: base
34: guide insulator 35: fixture
36: Suspension insulator 40: Bird repellant
41: Rotating device 42: Rotating bar
43: reflective ribbon 50: battery
60: Base 61: Base body
62: Nozzle 70: Faucet device
80: Cooling water supply device 90: Sprinkler warning device
100: Temperature sensor 110: Cooling water controller
120: Hazard warning mechanism 121: Support bar
122: Ultrasonic sensor 123: Danger notification device
130: Surveillance Camera ML: Mothership
TL: tram line

Claims (1)

A bus disconnector room (11a1) that accommodates the insulating gas, a first transformer room (11a2) that communicates with the bus disconnector chamber (11a1) and accommodates the insulating gas, and a first transformer chamber (11a2) that communicates with the first transformer chamber (11a2) and accommodates the insulating gas. a circuit breaker chamber (11a3), a second transformer chamber (11a4) that communicates with the circuit breaker chamber (11a3) and accommodates insulating gas, and a line disconnector chamber (11a5) that communicates with the second transformer chamber (11a4) and accommodates insulating gas. ), a first partition plate 11b installed in the case 11a and dividing the bus disconnector chamber 11a1 and the first transformer chamber 11a2, and a first partition plate 11b installed in the case 11a. A second partition plate 11c is installed in the case 11a to partition the first transformer chamber 11a2 and the breaker chamber 11a3, and a second partition plate 11c is installed in the case 11a to partition the breaker chamber 11a3 from the second transformer chamber 11a4. A GIS main body (11) equipped with a three-partition plate (11d) and a fourth partition plate (11e) built into the case (11a) to partition the second deflector chamber (11a4) and the line disconnector chamber (11a5); A bus disconnector (12) installed in the bus disconnector room (11a1); A first current transformer (13) installed in the first current transformer room (11a2); A circuit breaker (14) installed in the circuit breaker room (11a3); A second transformer (15) installed in the second transformer room (11a4); A line disconnector (16) installed in the line disconnector room (11a5); A GIS (10) consisting of a bushing (17) installed in the line disconnector room (11a5) and protruding to the outside; A transformer (20) electrically connected to the GIS (10); In the multi-function power receiving equipment including a tram line support mechanism (30) that supports a tram line (TL) and a plurality of lead wires (21) drawn from the transformer (20),
The first partition plate (11b) partitions the bus disconnector chamber (11a1) and the first transformer chamber (11a2) so that the bus disconnector chamber (11a1) and the first transformer chamber (11a2) do not communicate,
The second partition plate (11c) partitions the first transformer chamber (11a2) and the circuit breaker chamber (11a3) so that the first transformer chamber (11a2) and the circuit breaker chamber (11a3) do not communicate,
The third partition plate 11d partitions the circuit breaker chamber 11a3 and the second transformer chamber 11a4 so that the circuit breaker chamber 11a3 and the second transformer chamber 11a4 do not communicate,
The fourth partition plate 11e divides the second transformer chamber 11a4 and the line disconnector chamber 11a5 so that the second transformer chamber 11a4 and the line disconnector chamber 11a5 do not communicate,
GIS(10) is,
A first check valve (CV1) installed on the first partition plate (11b) to allow insulating gas to flow only from the bus disconnector chamber (11a1) to the first transformer chamber (11a2);
A second check valve (CV2) installed on the second partition plate (11c) to allow insulating gas to flow from the circuit breaker chamber (11a3) only to the first transformer chamber (11a2);
A third check valve (CV3) installed on the third partition plate (11d) to allow insulating gas to flow only from the circuit breaker chamber (11a3) to the second transformer chamber (11a4);
A fourth check valve (CV4) installed on the fourth partition plate (11e) to allow insulating gas to flow only from the line disconnector chamber (11a5) to the second transformer chamber (11a2);
A first control valve (EV1) installed on the first partition plate (11b) to control the flow of insulating gas from the first transformer chamber (11a2) to the bus disconnector chamber (11a1);
A second control valve (EV2) installed in the second partition plate (11c) to control the flow of insulating gas from the first transformer chamber (11a2) to the circuit breaker chamber (11a3);
A third control valve (EV3) installed in the third partition plate (11d) to control the flow of insulating gas from the second transformer chamber (11a2) to the circuit breaker chamber (11a3);
A fourth control valve (EV4) installed on the fourth partition plate (11e) to control the flow of insulating gas from the second transformer chamber (11a2) to the line disconnector chamber (11a5);
It is installed in the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5), respectively, and the internal pressure of the bus disconnector room (11a1) and the circuit breaker room (11a3) and the line disconnector room (11a5) 1st, 2nd, and 3rd pressure sensors (PS1, PS2, PS3) that respectively measure;
A first reference value and a second reference value smaller than the first reference value are set, and measured pressure values are received from the first, second, and third pressure sensors (PS1, PS2, and PS3), and the measurement is made from the first pressure sensor (PS1). If the pressure value is less than the first reference value, the first control valve (EV1) is opened, and if the measured pressure value from the second pressure sensor (PS2) is less than the first reference value, the second control valve (EV2) or the third control is controlled. The valve (EV3) is opened, and if the measured pressure value from the third pressure sensor (PS3) is less than the first reference value, the fourth control valve (EV4) is opened, and the first pressure sensor (PS1) or the second pressure sensor is opened. A control unit (CB) that outputs a warning signal when the measured pressure value from (PS2) or the third pressure sensor (PS3) is less than the second reference value;
Equipped with a transmitter (TR) that wirelessly transmits a warning signal from the control unit (CB) to the outside,
The tram line support mechanism 30 is,
The first and second vertical supports (31, 31') are provided to face each other, and both ends are installed on the top of the first and second vertical supports (31, 31'), respectively, and the first and second vertical supports (31, 31') are provided to face each other. ), a horizontal support 32 connecting the horizontal support 31, a base 33 provided horizontally at the bottom of the horizontal support 31, and a horizontal support 33 that is movable in the horizontal direction and is fixed to a certain position and is pulled out. Equipped with a plurality of guide insulators (34) supporting the electric wire (21) and a plurality of suspension insulators (36) installed on the horizontal supports (32) and supporting the tram line (TL),
A rotating device 41 installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 and driven at regular intervals, and a rotating device 41 connected to the rotating device 41. A bird repellant (40) having a rotating bar (42) rotated by and a plurality of reflective ribbons (43) installed on the rotating bar (42); a battery 50 installed on the first vertical support 31, the second vertical support 31', or the horizontal support 32 to supply power to the rotating device 41; A main moving line 61a provided inside the base body 61, and a plurality of branch moving lines 61b provided inside the base body 61 and branched from the main moving line 61a and exposed to the outside. Equipped with a base body (61) on which the GIS (10) and the transformer (20) are seated; A base 60 consisting of a plurality of nozzles 62 installed on the branch movement line 61b; A power receiving device (70) mounted on the base body (61) and supplying power to station facilities; a cooling water supply device (80) that supplies water to the main moving line (61a) of the base (60); A sprinkler warning device (90) installed on the GIS (10), the transformer (20), and the power receiving device (70) to display a warning display; A temperature sensor 100 installed in the GIS 10, the transformer 20, and the power receiving device 70, respectively; a cooling water controller (110) that receives a temperature value from the temperature sensor (100) and operates a cooling water supply device (80) and a water spray warning device (90) when the temperature value exceeds a standard value; A support bar 121 installed on the base body 61; An ultrasonic sensor 122 installed on the support bar 121 to detect nearby passersby; A danger warning device 120 that is installed on the support bar 121 and outputs a danger warning signal to the surrounding area when it receives a detection signal from the ultrasonic sensor 122; Surveillance camera (130) installed on the support bar (121) to film the surroundings
A multi-function water faucet equipment further comprising: