KR20100079903A - Solid insulated switchgear - Google Patents

Abstract

PURPOSE: A solid-insulated-switchgear is provided to perform a solid-insulation without an insulating gas by including an incoming panel, a feeding panel, a potential transforming(PT) panel, and a Bus-tie panel. CONSTITUTION: An incoming panel(10) includes a solid-insulated disconnecting switch(1), a solid-insulated-grounding switch(2), and a solid-insulated breaker(4). A PT panel is electrically connected with the incoming panel. A feeding panel includes the solid-insulated disconnecting switch, the solid-insulated-grounding switch, and the solid-insulated breaker. The feeding panel is electrically connected with a wiring for supplying power. A Bus-tie panel is electrically connected with the feeding panel and includes the solid-insulated disconnecting switch, the solid-insulated-grounding switch, and the solid-insulated breaker.

Description

Solid Insulated Switchgear {SOLID INSULATED SWITCHGEAR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to solid isulated switchgears and, more particularly, to ultra-high pressure solid state insulated switchgears suitable for large power reception of 154 kilovolts or more.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to switchgear for use in the field of receiving and distributing ultra high voltage power of 154 kilovolts (KV) in large-scale civilian power demand.

As such an ultra high voltage switchgear, SF6 (sulfur hexafluoride) gas insulated switchgear has conventionally been used. However, there is a problem that SF6 (sulfur hexafluoride) gas is regulated in each country as one of the global warming gases, which is enclosed in the enclosure of the switchgear to quickly extinguish arcs generated during disconnection and breaking of ultra high voltage lines. . Therefore, without using SF6 (sulfur hexafluoride) gas as the insulating gas, it is necessary to replace other gas such as nitrogen gas or to find another insulating method.

In addition, the commercial switchgear for high voltage distribution needs to be designed to suit a variety of usage environments. Representatively, the power supply panel (incoming pannel), the power distribution panel (feeder pannel), the PT panel (Potential Transformer pannel) and the bus tie panel (Bus Tie) When the panel is composed of a combination of functional panels of each panel and each functional panel is insulated, it is required to configure each functional panel with solid insulating components.

Accordingly, the present invention solves the problems and problems of the prior art as described above, and an object of the present invention is to provide a solid insulated switchgear having a solid state insulated distribution panel, a PT panel, and a bus tie panel.

An object of the present invention, the solid-state insulating disconnector, the solid-state insulating grounding switch and the solid-state insulation breaker, the power supply panel (INCOMING PANNEL) is connected for the power supply and the power supply to the incoming power;

A PT panel electrically connected to the power receiving panel, the PT panel having a phase transformer transformer;

A distribution panel electrically connected to the PT panel and having a solid insulated disconnector, a solid insulated ground breaker, and a solid insulated breaker, the electric power supply panel being connected for power distribution; And

A first booth tie part electrically connected to the power distribution panel and having a solid insulated disconnector, a solid insulated ground breaker, and a solid insulated breaker, for supplying a first power source; A bus tie panel including a disconnector and a solid insulated ground switch, and including a second bus tie portion electrically connected to the first bus tie portion to connect different power buses.

It can be achieved by providing a solid insulated switchgear according to the invention, characterized in that it comprises.

Switchgear according to the present invention is a switchgear for civil insulation ultra-high pressure solid-insulated switchgear, because it uses solid insulation without the use of insulating gas, and maintenance is not necessary to periodically check and supplement the gas pressure of the insulating gas in the switchgear. Since the gas pressure is unnecessary, the total volume of the switchgear can be reduced, and since the use of SF6 gas, which is regulated internationally, can be used, it can provide a switchgear that is eco-friendly and satisfies the eco-friendly requirements of various countries internationally. The effect can be obtained.

The object of the present invention and the constitution and effect of the present invention to achieve the same will be more clearly understood by the following description of the preferred embodiment of the present invention with reference to the accompanying drawings.

1 and 7, the solid-state insulation switch gear 100 according to the present invention includes an INCOMING PANNEL 10, a PT panel (POTENTIAL TRANSFORMER PANNEL) 20, and a power distribution panel (FEEDER). PANNEL 30 and BUS TIE PANNEL 40.

Meanwhile, referring to FIGS. 1 and 2, a configuration and an operation of the power receiving panel 10 of the solid state switchgear 100 according to the present invention will be described.

As shown in FIGS. 1 and 2, the INCOMING PANNEL 10 includes a solid insulated disconnector (symbol DS in FIG. 1 and a symbol 1 in FIG. 2), and a solid insulated grounding switch (symbol in FIG. 1). ES, see FIG. 2, and a solid-state insulation circuit breaker (see CB in FIG. 1, 4 in FIG. 2), and are connected to the electric wire C1 for supplying incoming electric power. As can be seen in FIG. 1, the power receiving panel 10 may further include a current transformer (see symbol CT in FIG. 1) provided around the power receiving cable C1 to detect the amount of current. The power receiving panel 10 further includes a lightning arrester (see reference numeral LA in FIG. 1 and reference numeral 6 in FIG. 2) provided for each phase to ground a lightning strike. The solid insulated disconnector (symbol DS in FIG. 1, see symbol 1 in FIG. 2), the solid insulated ground breaker (symbol ES in FIG. 1, reference numeral 2 in FIG. 2) and solid insulated circuit breaker (symbol CB in FIG. 1, FIG. 2). 3, the current transformers (see CT in FIG. 1) and the lightning arresters (see LA in FIG. 1, 6 in FIG. 2) are provided so as to correspond to respective phases of three-phase alternating current.

Although the solid insulated disconnecting device 1 is not shown inside, the energized position is in contact with the fixed contactor by a fixed contact connected to the power supply side, an insulated shaft rotated by a drive unit including a motor and a reducer, and a screw formed on the insulated shaft. And a movable contactor which is movable to a disconnecting position separated from the fixed contactor, and the outside is cast enclosing with a solid insulating material such as epoxy and electrically solid insulated from the outside. For a more detailed description of the configuration and operation can refer to the Republic of Korea Patent Registration No. 10-0753561 filed on May 11, 2006, the applicant of the present invention. Although the solid insulated grounding switch 2 is not shown inside, the fixed contactor connected to the ground (ground), the insulated shaft rotated by a drive unit including a motor and a reducer, the screw portion formed on the insulated shaft to the fixed contactor It is composed of a contacting ground position and a movable contactor which is movable to an energized position separated from the fixed contactor, and the outside is electrically insulated from the outside by casting enclosing with a solid insulating material such as epoxy Has a configuration. For a more detailed description of this configuration and operation can be referred to the Patent Registration No. 10-0753561. The power receiving panel 10 includes an actuator 3 for opening and closing the solid-state insulation circuit breaker 4 as shown in FIG. 2, and the actuator 3 preferably uses the electromagnetic force of the coil. It can be composed of a permanent magnet actuator that provides linear power. The solid insulation breaker (4) may be composed of a vacuum interrupter (vacuum interruper) that is externally cast enclosed by an electrical solid insulation material such as epoxy, the operation inside the vacuum vessel of the vacuum interrupter constituting the solid insulation breaker (4) A power transfer lever for linearly driving a contact to the open / closed position is connected between the actuator 3 and the solid state insulation circuit breaker 4, and the power transfer lever is also cast-out enclosed by an electrical solid insulation material to solid-state insulation. Has a configuration. More detailed configuration and operation of the actuator (3) and the solid-state insulation circuit breaker (4) is a Korean Patent Registration No. 10-0789447 filed by the inventor of the present invention and filed and filed December 29, 2006 by the applicant of the present invention Reference may be made. The power receiving panel 10 includes a junction box 7 for receiving power through the power receiving cable C1 and for connecting the arrester 6. The junction box 7 is composed of a housing having a conductor portion for electrical conduction inside and a shell wrapped with a solid insulating material, the conductor portion being horizontally connected to the fixed contact side of the solid-state insulation circuit breaker 4 and the power receiving unit. It may be configured to include a vertical conductor portion vertically connected to the cable (C1) and the arrester (6). The vertical conductor portion and the horizontal conductor portion may be provided in the form of a socket and a plug for secure connection. The interior of the cable connection box 7 can refer to the configuration of the disconnector base portion of the registration publication of the Republic of Korea Patent Registration No. 10-0753561 and will not be shown. On the other hand, reference numeral 8 is a frame enclosure (frame enclosure) for receiving and supporting the components in the interior of the power receiving panel 10 described above.

Referring to the operation of the power receiving panel 10 configured as described above, the current drawn through the power receiving cable (C1) is fixed and movable inside of the solid-state insulation breaker (4) in the energized position with the conductor portion in the junction box (7) Bushing through the internal conductor and movable contact and the fixed contact of the solid insulated disconnecting switch 1, which is also the energized position, via the contact and the conductor part, and the internal fixed and movable contact of the solid insulated earthing switch 2, which is the energized position. (Included in reference numeral 1, but not given separately) is leaked to the PT panel 20 through the cable not shown as shown in FIG. Here, the bushing is an output terminal for transmitting the three-phase electric power connected to the three-phase line cable to the PT side panel 20, the power distribution panel 30, and the bus tie panel 40 at the rear end, and It consists of an outer covering of insulating material in which electrical conductors are embedded. At this time, when the actuator 3 drives the solid insulated circuit breaker 4 to the blocking position, when the solid insulated circuit breaker 4 is the blocking position, the internal fixed and movable contacts are separated, so that the current is supplied from the solid insulated circuit breaker 4. The flow of electric current is cut off by the solid-state grounding switch 2 at the rear end and the like. In addition, when the solid insulated grounding switch 2 is in the ground position, the current flows out to the ground and does not flow to the rear solid insulated disconnector 1. In addition, when the solid insulated disconnector 1 is in the disconnected position, the current flow is disconnected from the solid insulated disconnector 1 and the current flow to the cable and the PT panel 20 at the rear end is disconnected.

On the other hand, with reference to Figures 1 and 3 will be described the configuration and operation of the PT panel (POTENTIAL TRANSFORMER PANNEL) 20 of the solid state switchgear according to the present invention. As shown, the PT panel 20 is electrically connected to the power receiving panel 10 and the power distribution panel 30 and includes a phase shifter (see PT in FIG. 1 and reference numeral 24 in FIG. 3). do. 1 and 3, the PT panel 20 includes a solid insulated disconnector (symbol DS in FIG. 1, reference numeral 21 in FIG. 3) and a solid insulated ground switch (ES in FIG. 1, FIG. 3). And 22). Since the disconnector 21 and the ground switch 22 have the same configuration and function as those of the solid insulation disconnector 1 and the solid insulation ground switch 2 of the power receiving panel 10 described above, the detailed description thereof will be repeated. It will be omitted to avoid. The junction box 23 is electrically connected to the solid insulated ground switch 22 so that an electrical conductor is provided therein to transfer the power provided from the solid insulated ground switch 22 to the instrument transformer 24 in a subsequent step. It can be constructed in a structure similar to the junction box 7 described above by a junction box that is embedded and enclosed in an outer case molded of a solid insulating material. Three junction boxes 23 may be configured to correspond to a three-phase alternating current, each of which includes a power fuse (not shown in FIG. 3) but may be referred to as a circuit symbol for overcurrent. When generated, the power fuse can be configured to cut off the circuit to protect the instrument transformer 24 in the rear stage.

Instrument transformer 24 is composed of a transformer that is proportional to the voltage of the received power and provides a stepped down voltage as a secondary side output voltage for measurement. Three instrument transformers 24 may be configured to correspond to three-phase alternating current.

The frame enclosure 25 is provided as a means for accommodating and supporting components therein, similarly to the frame enclosure 8 of the power receiving panel 10 described above.

The operation of the PT panel 20 in the solid state switchgear according to the present invention configured as described above will be described.

In the PT panel 20, the electric power received using the solid insulated disconnecting unit 21 is supplied (by energizing position) or disconnected by bypassing to a later stage (i.e., a distribution panel or a bus tie panel). Disconnection position), and the operator can be discharged by grounding and discharging the residual current in the state where the solid insulated disconnector 21 operates in the disconnection position when performing the branching or replacement of the line using the solid insulated ground switch 22. It can protect against a safety accident, and can measure the voltage of electric power currently received using the instrument transformer 24.

Meanwhile, with reference to FIGS. 1 and 4, the detailed configuration and operation of the power distribution panel 30 among the components of the solid state insulating switchgear according to the present invention will be described.

The power distribution panel 30 is connected to a wire for supplying power, that is, the power distribution cable C2 for power distribution, and includes a solid insulated disconnector (see FIG. 1, DS 31 and FIG. 4) and a solid insulated ground switch (FIG. 1). And ES solid reference breaker (see CB in FIG. 1 and 34 in FIG. 4). The power distribution panel 30 further includes an arrester (see SA in FIG. 1 and reference 35 in FIG. 4) provided for each phase to ground a lightning strike.

The power distribution panel 30 includes an actuator 33 for opening and closing the solid-state insulation circuit breaker 34 as shown in FIG. 4, and the actuator 33 includes the actuator 3 in the power receiving panel 10 described above. It can be configured in the same way. The distribution panel 30 includes a junction box 36 for the distribution to the load side via the distribution cable C2 and the connection to the arrester 35. The junction box 36 may be configured in the same manner as the junction box 7 in the power receiving panel 10 described above. In Fig. 4, the power distribution panel 30 according to the present invention includes an arrester 35 for grounding a lightning strike. The power distribution panel 30 also includes a bushing (see the right end of the portion indicated by reference numeral 31 in FIG. 4) for receiving power, which bushing is the solid-state insulating disconnector 1 in the power receiving panel 10 described above. As can be seen in FIG. 1 with the same configuration as the bushing at the right end of the power receiving power bypassed through the PT panel 20 is the power distribution panel 40 and parallel to the bus tie panel 40. Power is supplied via the bushing. On the other hand, reference numeral 37 is a frame enclosure for receiving and supporting the components inside the above-described power distribution panel 30. Detailed configuration description of the components described above in the description of the panel will be omitted to avoid duplicate description.

The operation of the components in the power distribution panel 30 is as follows. When power is supplied to the solid insulated disconnector 31 through the bushing, power is supplied to or disconnected from the solid insulated grounding switch 32 of the rear end according to the position of the solid insulated disconnector 31, that is, the energized position and the disconnected position. The operator insulates safety by discharging the residual current to the grounded position while the solid insulated disconnector 31 operates in the disconnection position when performing the branching or replacement of the line using the solid insulated grounding switch 32. It can protect against accidents, and the distribution to the load side is made or interrupted by the position of the solid state insulation breaker 34, that is, the energized or interrupted position. Therefore, when the solid insulated disconnector 31 is the energized position, the solid insulated ground switch 32 is the energized position, not the grounded position, and the solid insulated breaker 34 is also the energized position, the power supplied through the bushing is a solid insulated disconnector ( 31), the solid insulated grounding switch 32, the solid insulated circuit breaker 33, the junction box 36 is drawn out (supplied) to the load side through the distribution cable (C2).

Instrument transformers (usually abbreviated as METERING OUT FIT, MOF) may be additionally connected to the power system line located at the rear end of the distribution panel 30. The transformer transformer current transformer (MOF) is a power device that transforms the ultra-high voltage to 220 volts and converts the amount of current to provide a power meter so that power can be metered using a general power meter. Therefore, the transformer transformer current transformer as a main component includes a primary inlet terminal unit for inputting power of an ultra-high voltage line, a transformer, a current transformer, and a secondary output terminal unit for outputting downed voltage and current signals to the outside.

On the other hand, with reference to Figures 5 and 6 will be described the configuration and operation of the bus tie panel 40 of the solid state switchgear according to the present invention.

The booth tie panel 40 is a means for connecting different power busbars, and includes a first booth tie part 40a and a second booth tie part 40b.

First, the configuration and operation of the first bus tie portion 40a will be described with reference to FIG. 5.

The first booth tie portion 40a is electrically connected to the power distribution panel 30 via a cable (not shown) via a bushing (see the right end of the portion indicated by reference numeral 40a1), and a solid insulated disconnector ( 40a1), a solid insulated ground switch 40a2, and a solid insulated breaker 40a4 are provided to supply a first power source (power). An actuator 40a3 in which the solid insulated circuit breaker 40a4 provides a driving force for opening and closing the contact (particularly the movable contact) is included in the first bus tie portion 40a. The first booth tie portion 40a also includes a bushing 40a5 to provide output power, and the internal configuration of the bushing 40a5 may be configured the same as the bushing of the power receiving panel described above. Reference numeral 40a6 denotes a frame enclosure for receiving and supporting internal components of the first booth tie portion 40a.

The operation of the components in the first booth tie portion 40a will be described below. When power is supplied to the solid insulated disconnector 40a1 through a bushing on the right end of the solid insulated disconnector 40a1, the power is supplied to the solid insulated grounding switch of the rear end according to the position of the solid insulated disconnector 40a1, that is, the energized position and the disconnected position. 40a2 is supplied or cut off. The operator is safe by discharging the residual current to the ground position while the solid insulated disconnector 40a1 is operated to the disconnected position when performing branching or replacement of the line using the solid insulated ground switch 40a2. It can protect against an accident and the energized connection to the second bus tie part 40b is made or blocked by the position of the solid state insulating breaker 40a4, that is, the energized or interrupted position. Therefore, when the solid insulated disconnector 40a1 is in the energized position, the solid insulated ground switch 40a2 is in the energized position instead of the grounded position, and the solid insulated breaker 40a4 is also in the energized position, bushing of the right end of the solid insulated disconnector 40a1. The power supplied through the solid state insulation disconnector 40a1, the solid insulation ground breaker 40a2, the solid insulation breaker 40a4, the bushing (40a5) can be electrically connected to the second bus tie portion 40b The condition is fulfilled.

Next, the configuration and operation of the second bus tie portion 40b will be described with reference to Fig. 6. The second power source is connected to the second power supply to supply the second power source, and the solid state insulation disconnector 40b1 and the solid state insulation grounding switch 40b2 are connected to each other. And electrically connected to the first booth tie portion 40a. The second booth tie portion 40b includes a second power supply connection portion 40b3 that provides a means for connection with the second power source. The second power supply connection portion 40b3 includes a junction box for providing a live connection to the solid insulated grounding switch 40b2 and electrical insulation from the outside, and a bushing for connection with the second power supply side cable. Reference numeral 40b4 denotes a frame enclosure for receiving and supporting internal components of the second booth tie portion 40b.

The operation of the components in the second booth tie portion 40b configured as described above is as follows.

When the power of the second power supply is supplied through the bushing on the right end of the second power connection portion 40b3, current flows to the solid insulated grounding switch 40b2 through a conductor not shown in the second power connection portion 40b3. At this time, the second power source (power) flows into the supply or the ground to the solid state insulation disconnector 40b1 at the rear end according to the position of the solid state insulation ground switch 40b2, that is, the energization position and the ground position. The solid insulated ground switch 40b2 is operated to the ground position while the solid insulated disconnector 40b1 operates in the disconnection position when the branch or the replacement of the line is performed using the solid insulated ground switch 40b2. By discharging the residual current, the worker can be protected from a safety accident, and the energized connection to the first bus tie part 40a is made or disconnected by the position of the solid insulation disconnector 40b1, that is, the energization or disconnection position. Therefore, when the solid insulated disconnector 40b1 is in the energized position and the solid insulated ground switch 40b2 is also in the energized position other than the grounded position, the second power source (power) supplied through the bushing at the right end of the second power connection unit 40b3 is A condition in which the second power supply connection portion 40b3, the solid insulated ground switch 40a2, and the solid insulated disconnector 40b1 can be electrically connected to the first bus tie portion 40a is achieved.

As described above, by providing a solid-insulated switchgear according to the present invention, it does not use SF6 gas, which is regulated internationally, so that it is environmentally friendly and meets the environmentally-required requirements of various countries internationally, and receives ultra-high voltage of 154 kilovolts or more. This provides the effect of providing a solid-insulated switchgear that can be measured, distributed, and connected to other power sources.

1 is a circuit diagram showing the configuration of a solid-state insulation switchgear according to the present invention in each panel and circuit configuration,

Figure 2 is a front view showing the internal configuration of the power distribution panel of the components of the solid state switchgear according to the present invention,

Figure 3 is a front view showing the internal configuration of the PT panel of the components of the solid state switchgear according to the present invention,

Figure 4 is a front view showing the internal configuration of the power distribution panel of the components of the solid state switchgear according to the present invention,

5 is a front view showing an internal configuration of a first booth tie part of a booth tie panel among the parts of a solid insulation switchgear according to the present invention;

6 is a front view showing the internal configuration of the second booth tie part of the booth tie panel among the parts of the solid state insulating switchgear according to the present invention;

7 is a front view showing the overall configuration of the solid state switchgear according to the present invention,

8 is a perspective view showing an overall configuration of a solid-state insulation switch gear according to the present invention.

* Explanation of symbols on the main parts of the drawings

1, 21, 31, 40a1, 40b1: solid insulation disconnector

2, 22, 32, 40a2, 40b2: solid insulated earthing switch

3, 33, 40a3: Actuator 4, 34, 40a4: Solid-state breaker

8, 25, 37, 40a6, 40b4: frame enclosure

6, 35: lightning arrestor 7, 23, 36: connector

9, 48, 117b, 147b: lightning arrester junction box

C1: power distribution cable C2: power distribution cable

10: Incoming pannel

20: PT Panel (Potential Transformer pannel)

24: Potential Transformer

30: feeder pannel

40: bus tie pannel

40a: first booth tie part 40b: second booth tie part

40a5: Bushing 40b3: Second power supply connection

100: solid insulated switchgear

Claims (5)

An INCOMING PANNEL having a solid insulated disconnector, a solid insulated ground breaker, and a solid insulated breaker, and connected for a power supply and an electric wire to supply incoming power; A PT panel electrically connected to the power receiving panel, the PT panel having a phase transformer transformer; A distribution panel electrically connected to the PT panel and having a solid insulated disconnector, a solid insulated ground breaker, and a solid insulated breaker, the electric power supply panel being connected for power distribution; And A first booth tie part electrically connected to the power distribution panel and having a solid insulated disconnector, a solid insulated ground breaker, and a solid insulated breaker, for supplying a first power source; A bus tie panel including a disconnector and a solid insulated ground switch, and including a second bus tie portion electrically connected to the first bus tie portion to connect different power buses. Solid-state switchgear comprising a. The method of claim 1, The faucet panel, And a current transformer installed around the power receiving cable to detect a current amount. The method of claim 1, The PT panel, And a solid insulated switchgear and a solid insulated ground switch. The method of claim 1, The power receiving panel and the power distribution panel, Solid-state switchgear provided by a phase further comprises a lightning arrester for grounding the lightning. The method of claim 1, Solid state insulated switchgear comprising a transformer transformer current transformer (hereinafter commonly referred to as METERING OUT FIT, MOF) connected to the power system line located at the rear end of the distribution panel.

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