KR100571291B1 - Special high voltage faucet - Google Patents

Abstract

The present invention relates to a special high-voltage power receiving facility of the switchgear, omitting the redundant use of the elements used to protect the power distribution system, inserting the MOF function into the AISS support insulator, while reducing the installation area of the existing switchgear and investment in power supply facilities It is to reduce the cost.

The present invention is achieved by embedding a CT or CT and PT in the power insulator of the AISS installed in the switchboard, and by installing a MOF in the load insulator, which can greatly reduce the size of the switchboard.

Switchboard, AISS, insulator, CT, MOF

Description

High Voltage Power Supply Equipment {High voltage supply of electric power equipmnet}

1 is a disconnection diagram of an existing power plant

2 is a cross-sectional view of the conventional AISS insulator

Figure 3 is an embodiment of the present invention power line disconnection connection diagram

4 is a sectional view of an embodiment of the power receiving facility AISS insulator of the present invention

5 is a connection diagram of an embodiment power receiving equipment AISS of the present invention

Figure 6 is another embodiment of the power receiving equipment disconnection connection diagram

7 is a cross-sectional view of another embodiment of the power receiving facility AISS insulator of the present invention.

8 is another embodiment of the present invention faucet AISS connection diagram

9 is a circuit diagram illustrating disconnection of another embodiment of the present invention.

10 is a cross-sectional view of another embodiment faucet AISS insulator of the present invention.

11 is another embodiment of the present invention faucet AISS connection diagram

[Description of Symbols for Main Parts of Drawing]

10: AISS 11: Power Side Insulator

12: load side insulator 15: CT

16: PT 20: LA

30: MOF 32: PT

33: CT 40: Transformer

100: AISS

The present invention relates to a special high-voltage power receiving facility of the switchgear, omitting the redundant use of the elements used to protect the power distribution system, inserting the MOF function into the AISS support insulator, while reducing the installation area of the existing switchgear and investment in power supply facilities It is to reduce the cost.

Electric materials used in electric circuits are changing from oil type to mold type to solve the fire and insulation relationship. Transformers have been using mold type for a long time, and MOF to measure electricity consumption between KEPCO and customers is indoors. KEPCO regulations stipulate that mold-type flame retardant products should be used for installation in enclosed spaces such as faucets or cubicles.

In addition, ASS used for the line breaker installed at the power receiving point is replaced by AISS made of epoxy resin in the inflow type, and the load side support insulator of the AISS has a built-in CT to detect the overload and ground fault to operate the protection relay. To make it trip.

That is, according to the circuit diagram of the power receiving facility shown in FIG. 1, the LA 20 is installed in the panel SH-1 together with the LBS or AISS 10 that is the line breaker, and the panel SH-2 has power. The fuse 31 and the MOF 30 for KEPCO are installed. The panel SH-3 is equipped with a COS or power fuse and a transformer 40, and the panel LV-1 has a low voltage circuit breaker 50 installed therein. It is composed of breakers for each load branch.

At this time, the load side insulator 12 of the AISS 10 has a built-in CT (15) as shown in Figure 2, the system protection in the existing power plant is installed LA 20 used for lightning protection and overload And while the short-circuit protection power fuse 31 is installed, the COS or power fuse 41 installed on the primary side of the transformer 40 also plays the same role.

However, because the devices used for system protection are overlapped and occupy a large amount of installation area, it is difficult to reduce the size of the switchboard and reduce the manufacturing cost.

The present invention has been invented in view of the above, by installing CT, PT, and MOF in the power side insulator and load side insulator of the AISS installed in the switchboard, respectively, which was previously installed over two panels to be installed in one panel. In order to reduce the size of the switchboard, it is possible to reduce the production cost and the investment cost of the faucet facility of the customer.

The present invention is achieved by embedding a CT or CT and PT in the power insulator of the AISS installed in the switchboard, and by installing a MOF in the load insulator, which can greatly reduce the size of the switchboard.

The present invention is to reduce the size of the switchboard in charge of the special high-voltage power receiving equipment, the CT 15 is embedded in the power insulator 11 of the AISS (100) and the MOF 30 in the load side insulator 12 To reduce the size of the switchboard, or to embed the CT 15 and PT 16 in the power insulator 11 of the AISS 100 and the MOF 30 in the load insulator 12 to reduce the size of the switchboard. The CT 15 and PT 16 in the power insulator 11 of the AISS 100 and the MOF 30 in the load insulator 12 while the middle insulator 12 'and the load insulator The power fuse 38 is used between the 12 to reduce the size of the switchboard.

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

First, the CT 15 is embedded in the power insulator 11 of the AISS 10, which is an embodiment of the present invention, and the MOF 30 is embedded in the load insulator 12 to reduce the size of the switchboard. Look at 5.

The embodiment of the present invention required two panels, such as a panel in which the AISS 10 was previously installed and a panel in which the MOF 30 was installed, but to perform the same function using one panel, but the AISS 100 The CT 15 is built into the power supply side insulator 11 to detect an overcurrent or ground fault current and sends a detection signal to the AISS control box 14 so as to automatically trip. At this time, the power supply insulator 11 of the AISS 100 It is made by epoxy vacuum casting.

The operation of opening the track by automatically tripping the AISS in the AISS control box 14 according to the detection signal of the CT 15 is the same as the operation in the existing AISS 10, and thus description thereof will be omitted. The trip operation according to the overcurrent or ground fault current detection in the invention makes use of the specification of the generalized AISS.

The load side insulator 12 of the AISS 100 has a MOF 30 which is a KEPCO metering device, but the MOF 30 is composed of a PT 32 and a CT 33, and the MOF 30 is detected. The signal allows the usage amount to be displayed through the DM 61 and the VAR 62 in the meter box 60 separately installed through the MOF TB box 35.

At this time, the load-side insulator 12 of the AISS 100 is manufactured by epoxy vacuum casting, but the CT 33 and PT 32 manufactured according to the capacity (CT ratio) of the destination are installed in the insulator 12.

According to this embodiment of the present invention, as compared to the conventional AISS (10) is installed on one panel and MOF (30) is installed in another panel to require two panels, MOF (30) in one panel By installing the built-in AISS (100) it is possible to reduce the size of the switchboard.

And a method of reducing the size of the switchboard by embedding the PT (16) and CT (15) in the power insulator 11 of the AISS (100) of the present invention and the MOF (30) in the load insulator 12 With reference to Figures 6 to 8 will be described.

Another embodiment of the present invention required two panels, such as a panel in which the AISS 10 was previously installed and a panel in which the MOF 30 was installed, but to perform the same function using one panel, but the AISS (100). PT (16) and CT (15) are built into the power insulator (11) of the power supply) so that measurement can be performed through the digital power measurement controller, while detecting fault current and fault voltage and sending detection signals to measure and AISS ( 100 is to be an automatic trip, the power insulator 11 of the AISS (100) is to be produced by epoxy vacuum casting.

 PT 16 and CT 15 installed in the power supply side insulator 11 of the present invention is a three-phase voltage, three-phase current, three-phase power, three-phase unbalance rate, three-phase reactive power, using a digital power measurement controller, It provides three-phase apparent power, three-phase active power, frequency, power factor, and parking short-circuit status.It uses digital power protection relays to provide various measurements as well as relay functions such as overcurrent, ground current, overvoltage, low voltage, and open phase. It can be installed and it prevents an electric accident by automatically tripping the AISS using the relay function.

On the other hand, when the PT 16 and the CT 15 are embedded in the power insulator 11 of the AISS 100, the size of the insulator is larger than that of the existing AISS 10, but the distance between the grounds is increased accordingly. The problem of flashover between earths disappears.

The load side insulator 12 of the AISS 100 has a MOF 30 which is a KEPCO metering device, but the MOF 30 is composed of a PT 32 and a CT 33, and the MOF 30 is detected. The signal allows the usage amount to be displayed through the DM 61 and the VAR 62 in the meter box 60 separately installed through the MOF TB box 35.

At this time, the load side insulator 12 of the AISS 100 is manufactured by epoxy vacuum casting, but CT 33 and PT 32 manufactured according to the capacity of the customer (CT ratio) are installed in the insulator 12.

According to another embodiment of the present invention as described above, the AISS 10 is installed in one panel and the MOF 30 is installed in another panel, which requires two panels. 16) and the CT 15 are installed on the power supply side insulator 11 and the MOF 30 can reduce the size of the switchboard by installing the AISS 100 installed on the load side insulator 12.

In another embodiment of the present invention, the PT 16 and the CT 15 are embedded in the power insulator 11 of the AISS 100 and the MOF 30 is embedded in the load insulator 12 while the middle insulator 12 is embedded. ') And a load fuse 38 is installed between the load side insulator 12 to use the primary protection of the MOF (30), while performing the protection function faithfully while reducing the size of the switchboard 9 to 11 Look at.

Another embodiment of the present invention required two panels, such as a panel in which the AISS 10 was previously installed and a panel in which the MOF 30 was installed, but to perform the same function using a single panel, but AISS ( PT 16 and CT 15 are built into the insulator 11 of the power supply 100, and the measurement is performed through the digital power measurement controller, while detecting the fault current and the fault voltage and sending a detection signal to measure and AISS ( 100 is to be an automatic trip, using the current-type power fuse 38 in the middle insulator 12 'and the load insulator 12 to protect the primary side of the MOF (30), wherein the AISS (100) The power supply side insulator 11) is manufactured by epoxy vacuum casting.

  PT 16 and CT 15 installed in the power supply side insulator 11 of the present invention is a three-phase voltage, three-phase current, three-phase power, three-phase unbalance rate, three-phase reactive power, using a digital power measurement controller, 3-phase apparent power, 3-phase active power, frequency, power factor, parking short-circuit status, and so on.It uses digital power protection relays to measure various types of relays as well as overcurrent, ground current, overvoltage, low voltage, phase loss, etc. Function can be installed, and by using the relay function to automatically trip the AISS to prevent electric accidents.

On the other hand, when the PT 16 and CT 15 are embedded in the power insulator 11 of the AISS 100, the size of the insulator becomes larger than that of the existing AISS 100, but the distance between the grounds increases accordingly. The problem of flashover between earths disappears.

On the other hand, between the middle side insulator 12 ′ and the load side insulator 12, a current-limiting power fuse 38 is installed to be used for the primary side protection of the MOF 30.

In addition, the load side insulator 12 of the AISS 100 has a MOF 30 which is a KEPCO metering device, but the MOF 30 is composed of a PT 32 and a CT 33, and the MOF 30 The detection signal allows the usage amount to be displayed through the DM 61 and the VAR 62 in the meter box 60 separately installed through the MOF TB box 35.

At this time, the load-side insulator 12 of the AISS 100 is manufactured by epoxy vacuum casting, but the CT 33 and the PT 32 manufactured according to the capacity of the customer are installed in the insulator 12.

According to another exemplary embodiment of the present invention, PT is installed in one panel as compared with the conventional AISS 10 installed in one panel and MOF 30 installed in another panel, which requires two panels. (16) and CT (15) are installed on the power supply side insulator 11, MOF (30) to install the AISS (100) installed on the load side insulator 12, it is possible to reduce the size of the switchboard while the current-flow power fuse The use of 38 makes it possible to protect the primary side of the MOF 30.

In the present invention, since the MOF is inserted into the support insulator of the AISS, the installation space is reduced, and the transformer is protected by forming the trip circuit of the AISS by checking the over temperature, and installing on the low pressure side. In conjunction with the digital power measurement controller, the high-performance, high-reliability monitoring and control system can be configured to reduce the installation area and manufacturing cost.

The present invention relates to a special high-voltage power receiving facility of the switchgear, and to reduce the manufacturing cost by eliminating the redundant use of the elements used to protect the power distribution system, while inserting the MOF function into the AISS support insulator, the installation area of the existing switchgear It will reduce the investment cost of the faucet facility by the customer side.

Claims (4)

In the special high-voltage faucet facility, the LA 20 is connected to the faucet while the AISS 100 is connected, and the transformer 40 is connected to the rear end of the AISS 100 via a power fuse 31. A built-in CT 15 for detecting an overcurrent ground current in the insulator 11 of the power supply side 100 to trip the AISS 100 in the AISS control box 14 when an abnormality is detected by the detection signal of the CT 15, The load side insulator (12) of the AISS (100) is a special high-voltage faucet, characterized in that to reduce the switchboard panel by embedding the MOF (30). In the special high-voltage faucet facility, the LA 20 is connected to the faucet while the AISS 100 is connected, and the transformer 40 is connected to the rear end of the AISS 100 via a power fuse 31. PT 16 and CT 15 are embedded in the power supply side insulator 11 of 100 to detect the measurement, fault current and voltage through the digital power measurement controller, and trip the AISS 100. The load side insulator (12) of the special high-voltage power receiving facility, characterized in that to reduce the switchboard panel by embedding the MOF (30). In the special high-voltage faucet facility, the LA 20 is connected to the faucet while the AISS 100 is connected, and the transformer 40 is connected to the rear end of the AISS 100, but the power insulator 11 of the AISS 100 is connected. PT (16) and CT (15) in the built-in to detect the measurement and fault current and voltage through the digital power measurement controller to trip the AISS (100), the middle insulator of the AISS (100) 12 ') and a current-limiting power fuse 38 is installed between the load side insulator 12 and the load side insulator 12 of the AISS 100 has a MOF 30 built therein to reduce the switchboard panel. Special high voltage faucets. The special high voltage power receiving facility according to any one of claims 1 to 3, wherein the transformer (40) checks the temperature so as to trip and protect the AISS (100) when it becomes over temperature.

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