KR102518617B1 - Uninterruptible Power Supply Terminal Block with Current Transformers - Google Patents

Abstract

The present invention is fastened to the front of the first terminal block 200 by the first terminal block 200 fastened to the watt-hour meter and the first bypass terminal 310 provided in plurality on the bottom, so that the watt-hour meter is connected to the first terminal block ( 200), a second terminal block 400 fastened to the lower part of the first terminal block 200, a plurality of second bypass small terminals 520 provided on the bottom surface, and a second It is fastened to the front of the second terminal block 400 by the bypass large terminal 530, and includes a second bypass 500 for separating the first terminal block 200 from the second terminal block 400. The first terminal block 200 is provided in the upper center of the first terminal block 200, and a board terminal 211 fastened to the watt-hour meter is formed protruding toward the watt-hour meter on the upper surface, and the first terminal block 200 is formed on the front surface. 1. A fixing member 210 in which a fastening hole 212 into which the bypass terminal 310 is inserted and fixed is recessed, and a plurality of fixing members 210 are provided inside the first terminal block 200, but the head portion 221 is formed to be curved at the top. And, the first leg part 222 and the second leg part 223 are protruded on both sides of the lower part of the head part 221, respectively, the RST phase bus bar 220, and the RST phase bus bar 220 on the upper surface. The current sensor 230 through which the through hole 231 is formed so that the second leg portion 223 can be inserted therethrough, and the first leg portion 222 coupled and fixed to the lower portion of the first leg portion 222 of the bus bar 220 on the RST. 1 input terminal 240, the second input terminal 250 coupled and fixed to the lower part of the second leg part 223 of the bus bar 220 on the RST, provided on one side of the bus bar 220 on the RST It is characterized in that it includes an N-phase busbar 260 and an N-phase terminal 270 coupled and fixed to the lower portion of the N-phase busbar 260.

Description

Current sensor integrated uninterruptible replacement terminal block {Uninterruptible Power Supply Terminal Block with Current Transformers}

The present invention relates to an uninterruptible replacement terminal block, and more particularly, after fastening a first bypass to a first terminal block including a current sensor, it is possible to uninterruptively separate/replace a watt-hour meter from the first terminal block. 2 relates to a current sensor-integrated uninterruptible replacement terminal block capable of uninterruptedly separating/replacing the first terminal block from the second terminal block after fastening the bypass to the second terminal block.

An uninterruptible replacement terminal block is an accessory device of a transformer-type watt-hour meter used for connection between the watt-hour meter and the transformer, and is designed to replace the watt-hour meter with an uninterruptible one in case of damage or failure of the watt-hour meter. The 3-phase 4-wire type is mainly applied. In addition, since the uninterruptible replacement terminal block can be used in connection with the transformer and the watt-hour meter, the amount of power consumption can be measured through the watt-hour meter.

In addition, in the conventional uninterruptible replacement terminal block using an external current sensor (CT, Current Transformer), there is an advantage in that the watt-hour meter can be replaced without interruption and the wiring is easy.

1 is a plan view of a conventional current sensor-integrated uninterruptible replacement terminal block. Referring to FIG. 1, in the conventional current sensor-integrated uninterruptible replacement terminal block, a large-sized 250/5A current sensor is applied, which still requires a wide installation space and can accommodate only contract power of 148 kW or less, so that the contract power There was a problem that it was difficult to expand the range.

Referring to FIG. 1, in the conventional current sensor-integrated uninterruptible replacement terminal block, when the watt-hour meter is damaged or malfunctioned, the watt-hour meter can be separated and replaced without interruption using the CT short-circuit connection pin, but the integrated current sensor or terminal block is damaged or malfunctions. When the terminal block is uninterrupted, there is a problem in that it cannot be separated and replaced.

KR 10-14140011 B1

The present invention has been made to solve the above problems, and an object of the present invention is to fasten the second bypass to the second terminal block when the first terminal block or the integrated current sensor included in the first terminal block fails or is damaged. Thus, it is to provide a current sensor integrated uninterruptible replacement terminal block to which a separable structure capable of uninterruptedly separating and replacing the first terminal block or the integrated current sensor from the second terminal block is applied.

In addition, an object of the present invention is to provide a current sensor-integrated uninterruptible replacement terminal block to which a separable structure is applied, in which a watt-hour meter can be uninterruptedly separated and replaced from the first terminal block by fastening the first bypass to the first terminal block.

In addition, an object of the present invention is to provide a current sensor-integrated uninterruptible replacement terminal block to which a large number of 400/5A current sensors are applied, which can accommodate contract power of 237 kW or less, and whose size is significantly reduced compared to the prior art.

In order to solve the above technical problems, the current sensor integrated uninterruptible replacement terminal block 100 according to the present invention is connected to the first terminal block 200 fastened to the watt-hour meter and the first bypass terminal 310 provided in plurality on the bottom surface. A first bypass (300) fastened to the front of the first terminal block (200) to separate the watt-hour meter from the first terminal block (200), and a second bypass (300) fastened to the lower part of the first terminal block (200). The terminal block 400 is fastened to the front of the second terminal block 400 by the second bypass small terminal 520 and the second bypass large terminal 530 provided in plurality on the bottom surface, so that the first terminal block 200 ) is configured to include a second bypass 500 for separating from the second terminal block 400, and the first terminal block 200 is provided in plurality at the upper center of the first terminal block 200, the upper surface A fixing member 210 in which a board terminal 211 fastened to the watt-hour meter protrudes toward the watt-hour meter, and a fastening hole 212 into which the first bypass terminal 310 is inserted and fixed is recessed on the front surface, the first A plurality of terminals are provided inside the terminal block 200, and the head part 221 is formed to be curved on the upper part, and the first leg part 222 and the second leg part 223 are formed on both sides of the lower part of the head part 221. Each of the RST-phase busbars 220 protruding, the current sensor 230 having through-holes 231 formed therethrough so that the second leg 223 of the RST-phase busbar 220 can be inserted therethrough, The first input terminal 240 coupled and fixed to the lower part of the first leg part 222 of the bus bar 220 on the RST, coupled and fixed to the lower part of the second leg part 223 of the bus bar 220 on the RST second input terminal 250, the N-phase busbar 260 provided on one side of the RST-phase busbar 220, and the N-phase terminal 270 coupled and fixed to the lower portion of the N-phase busbar 260 It is characterized in that it includes.

In addition, a plurality of second terminal blocks 400 are provided on the inside front of the second terminal block 400, and a first through hole 411 through which the first input terminal 240 is inserted and coupled is formed on the upper surface, , the first terminal box 410 through which the first fastening hole 412 communicating with the first through hole 411 is formed at the bottom of the front side, and a plurality of the second terminal block 400 are provided on the inner rear side of the second terminal block 400. A second through hole 421 through which the second input terminal 250 is inserted and coupled is formed through, and a second fastening hole 422 communicating with the second through hole 421 is formed through the lower front surface. It is provided on one side of the terminal box 420 and the first terminal box 410, and a third through hole 431 through which the N-phase terminal 270 is inserted and coupled is formed on the upper surface, and the third through hole 431 is formed on the upper surface of the front surface. 3 The third terminal box 430 through which the third fastening hole 432 communicating with the through hole 431 is formed, the first fastening hole 412 of the first terminal box 410, and the second terminal box ( 420) corresponding to the second fastening hole 422 and the third fastening hole 432 of the third terminal box 430, respectively, and including a headless bolt 450 through which an insertion hole 451 is formed on the front surface characterized by

In addition, the second bypass 500 includes a plurality of second bypass busbars 510 provided inside the second bypass 500, and the second bypass large terminal 530 is It is provided on one side of the rear side of the second bypass busbar 510, and after the end is inserted through the insertion hole 451 of the headless bolt 450 coupled to the lower front surface of the second terminal box 420, the first It is fastened to the second fastening hole 422 of the second terminal box 420, and the second bypass small terminal 520 is provided on the other side of the rear surface of the second bypass bus bar 510, and the end is the first After being inserted through the insertion hole 451 of the headless bolt 450 coupled to the lower front surface of the terminal box 410, it is fastened to the first fastening hole 412 of the first terminal box 410, and the first The length of the large terminal of the second bypass 500 is longer than that of the small terminal of the second bypass 500.

In addition, the second bypass large terminal 530 is characterized in that an insulating tube 531 is provided on the other side of the outer circumferential surface to surround the other side of the second bypass large terminal 530 for insulation.

In addition, the second leg part 223 is characterized in that the outer surface of the second leg part 223 is inserted into and coupled to the inner circumferential surface of the through hole 231 of the current sensor 230 in line contact.

In the current sensor integrated uninterruptible replacement terminal block according to the present invention, the second bypass is fastened to the second terminal block, so that the first terminal block or the integrated current sensor included in the first terminal block can be separated from the second terminal block without interruption. Applied, even when the first terminal block or current sensor is damaged or out of order, the first terminal block or current sensor can be separated without interruption and replaced or repaired.

In addition, in the current sensor integrated uninterruptible replacement terminal block according to the present invention, the first bypass is fastened to the first terminal block including the current sensor, and a separable structure capable of separating the watt-hour meter from the first terminal block is applied, so that the watt-hour meter is damaged or damaged. Even in case of failure, the watt-hour meter can be separated without interruption and replaced or repaired.

In addition, in the current sensor-integrated uninterruptible replacement terminal block according to the present invention, a 400/5A current sensor capable of accommodating contract power of 237 kW or less is applied, compared to a conventional 250/5A current sensor capable of accommodating contract power of 148 kW or less. In addition to extending the range, there is an effect that the size of the current sensor is remarkably reduced.

1 is a plan view of a conventional current sensor-integrated uninterruptible replacement terminal block.
2 is a perspective view of a current sensor-integrated uninterruptible replacement terminal block according to the present invention.
3 is a plan view illustrating a coupling structure of a first terminal block and a second terminal block in which a first cover and a second cover are removed, respectively.
FIG. 4 is an exploded view of the first terminal block shown in FIG. 2 .
FIG. 5 is a bottom view for explaining a coupling structure of a bus bar, a first input terminal, a second input terminal, and a current sensor on the RST shown in FIG. 4;
FIG. 6 is a perspective view of the first bypass terminal shown in FIG. 2 .
FIG. 7 is an exploded view of the second terminal block shown in FIG. 2 .
8 is a perspective view for explaining a coupling structure of lower parts of the second bypass.
9 is an exploded view for explaining a coupling relationship between a first terminal block, a second terminal block, and a second bypass.
10 is a perspective view for explaining a coupling structure of a first terminal block and a first bypass.
11 is a perspective view for explaining a coupling structure of a second terminal block and a second bypass.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings in order to describe in detail enough for those skilled in the art to easily implement the technical idea of the present invention.

However, the following examples are merely examples to aid understanding of the present invention, and the scope of the present invention is not reduced or limited thereby. In addition, the present invention may be embodied in many different forms and is not limited to the embodiments described herein.

2 is a perspective view of a current sensor integrated uninterruptible replacement terminal block 100 according to the present invention, and FIG. 3 is a first terminal block 200 and a second terminal block with the first cover 205 and the second cover 405 removed, respectively. It is a plan view for explaining the coupling structure of (400).

4 is an exploded view of the first terminal block 200 shown in FIG. 2, and FIG. 5 is an RST phase bus bar 220 shown in FIG. 4, the first input terminal 240, the second input terminal 250, and It is a bottom view for explaining the coupling structure of the current sensor 230.

FIG. 6 is a perspective view of the first bypass terminal 310 shown in FIG. 2 , and FIG. 7 is an exploded view of the second terminal block 400 shown in FIG. 2 .

8 is a perspective view for explaining the coupling structure of lower parts of the second bypass 500, and FIG. 9 is a coupling relationship between the first terminal block 200, the second terminal block 400, and the second bypass 500. It is an exploded view to explain .

10 is a perspective view for explaining the coupling structure of the first terminal block 200 and the first bypass 300, and FIG. 11 is a perspective view for explaining the coupling structure of the second terminal block 400 and the second bypass 500. It is a perspective view for

2 to 3, the CT-integrated uninterruptible replacement terminal block according to the present invention includes a first terminal block 200, a first bypass 300, a second terminal block 400, and a second bypass 500. It is composed by

First, the first terminal block 200 is coupled to an watt-hour meter (not shown), and the first bypass 300 is controlled by the first bypass terminals 310 provided in plurality on the bottom surface of the first bypass 300. It is fastened to the front of the first terminal block 200 and serves to separate the watt-hour meter from the first terminal block 200.

In addition, the second terminal block 400 is fastened to the lower part of the first terminal block 200, and the second bypass 500 includes a plurality of second bypass large terminals 530 and second bypass small terminals provided on the bottom surface. It is fastened to the front of the second terminal block 400 by 520, and serves to separate the first terminal block 200 from the second terminal block 400.

3 to 5, the first terminal block 200 includes a first case 201, a first cover 205, a fixing member 210, a bus bar on RST 220, a current sensor 230, It is configured to include a first input terminal 240, a second input terminal 250, an N-phase bus bar 260, and an N-phase terminal 270.

First, the first case 201 is provided at the rear of the first terminal block 200 , and the first cover 205 is provided at the front of the first terminal block 200 . The first case 201 and the first cover 205 form the exterior of the first terminal block 200 .

In addition, a plurality of fixing members 210 are provided at a predetermined distance from each other at the upper center of the first terminal block 200 so as to be fastened to the watt-hour meter. In addition, on the upper surface of the fixing member 210, a board terminal 211 fastened to the watt-hour meter protrudes toward the watt-hour meter, and on the front surface of the fixing member 210, a fastening hole into which the first bypass terminal 310 is inserted and fixed ( 212) is formed with a depression.

In addition, a plurality of busbars 220 on the RST are provided inside the first terminal block 200, and a head portion 221 is formed curved in an ∩ shape on the top of the busbar 220 on the RST, and the head portion 221 is bent. A first leg part 222 and a second leg part 223 protrude from both sides of the lower part of 221, respectively.

In addition, a through hole 231 is formed through the upper surface of the current sensor 230 (CT, Current Transformer) so that the second leg portion 223 of the bus bar 220 on the RST can be inserted therethrough. At this time, the current sensor 230 is preferably formed in the shape of a cylinder having a predetermined height.

Also, the width of the second leg portion 223 is formed to have the same value as the diameter of the through hole 231, so that the outer surface of the second leg portion 223 comes into line contact with the inner circumferential surface of the through hole 231. Therefore, when the second leg 223 of the bus bar 220 on the RST is inserted into the through hole 231 of the current sensor 230, the second leg 223 of the bus bar 220 on the RST ) is inserted and coupled so that the outer surface of the second leg part 223 comes into contact with the inner circumferential surface of the through hole 231 of the current sensor 230.

In addition, a 400/5A current sensor capable of accommodating up to 237 kW or less contract power is applied to the current sensor 230, and the range of contract power is expanded compared to the conventional 250/5A current sensor that can accommodate up to 148 kW or less contract power. In addition, there is an advantage in that the size of the current sensor 230 is significantly reduced.

In addition, the first input terminal 240 and the second input terminal 250 are coupled and fixed to the lower portions of the first leg part 222 and the second leg part 223 of the bus bar 220 on the RST, respectively. At this time, the first input terminal 240 is preferably formed in the same shape as the second input terminal 250 .

And, the N-phase busbar 260 is provided on one side of the RST-phase busbar 220 disposed on the rightmost side.

Then, the N-phase terminal 270 is coupled and fixed to the lower portion of the N-phase bus bar 260. At this time, the N-phase terminal 270 is preferably formed in the same shape as the second input terminal 250 .

On the other hand, when the first case 201 and the first cover 205 are coupled, the first input terminal 240 and the second input terminal 250 are provided on the bottom surface of the first case 201 and the first cover 205. And a plurality of first coupling holes 206 are formed through so that the N-phase terminal 270 can protrude to the lower part of the first terminal block 200 .

3 and 7, the second terminal block 400 includes a second case 401, a second cover 405, a first terminal box 410, a second terminal box 420, and a third terminal box. (430) and a headless bolt (450).

First, the second case 401 is provided at the rear of the second terminal block 400 , and the second cover 405 is provided at the front of the second terminal block 400 . The second case 401 and the second cover 405 form the outer appearance of the second terminal block 400 .

In addition, a plurality of first terminal boxes 410 are provided at a predetermined distance apart from the inside front of the second terminal block 400, and the first input terminal 240 is inserted and coupled to the upper surface of the first terminal box 410. A first through hole 411 is formed to pass through, and a first fastening hole 412 communicating with the first through hole 411 is formed through a lower portion of the front surface of the first terminal box 410 .

In addition, a plurality of second terminal boxes 420 are provided at the inner rear of the second terminal block 400 at a predetermined distance apart, and the second input terminal 250 is inserted and coupled to the upper surface of the second terminal box 420. A second through hole 421 is formed to pass through, and a second fastening hole 422 communicating with the second through hole 421 is formed through a lower portion of the front surface of the second terminal box 420 .

In addition, the third terminal box 430 is provided on one side of the first terminal box 410 disposed on the rightmost side, and the N-phase terminal 270 is inserted and coupled to the upper surface of the third terminal box 430. The through hole 431 is formed through, and the third fastening hole 432 communicating with the third through hole 431 is formed through the upper part of the front surface of the third terminal box 430 .

In addition, the headless bolt 450 is the first fastening hole 412 of the first terminal box 410, the second fastening hole 422 of the second terminal box 420, and the third terminal box 430 Corresponding to the fastening holes 432, respectively, the insertion hole 451 is formed through the front of the headless bolt 450. At this time, the cross section of the insertion hole 451 is preferably formed in a hexagonal shape.

Meanwhile, on the upper surface of the second case 401, a plurality of second coupling holes 402 are formed so that the second input terminal 250 can be inserted and coupled to the second through hole 421 of the second terminal box 420. through is formed.

And, when the second case 401 and the second cover 405 are coupled, the first input terminal 240 is located on the upper surface of the second case 401 and the second cover 405 of the first terminal box 410. A plurality of third coupling holes 406 are formed through the first through hole 411 to be inserted and coupled thereto.

And, on the front surface of the second cover 405, a plurality of fourth coupling holes 407 so that the second bypass large terminal 530 can be inserted into and coupled to the second fastening holes 422 of the second terminal box 420. ) is formed through.

And, on the front surface of the second cover 405, a plurality of fifth coupling holes 408 so that the second bypass small terminals 520 can be inserted and coupled to the first fastening holes 412 of the first terminal box 410. ) is formed through.

Meanwhile, referring to FIGS. 8 and 9 , the second bypass 500 includes a second bypass busbar 510, a second bypass large terminal 530, and a second bypass small terminal 520. It is composed by

First, a plurality of second bypass busbars 510 are provided inside the second bypass 500 . At this time, the second bypass busbar 510 is preferably formed in the shape of a rectangular plate having a predetermined thickness.

And, the second bypass large terminal 530 is provided on one side of the rear side of the second bypass bus bar 510, and the end of the second bypass large terminal 530 is the front lower part of the second terminal box 420. After being inserted through the insertion hole 451 of the headless bolt 450 coupled to, it is fastened to the second fastening hole 422 of the second terminal box 420.

And, the second bypass small terminal 520 is provided on the other side of the rear surface of the second bypass bus bar 510, and the end of the second bypass small terminal 520 is the front lower part of the first terminal box 410. After being inserted through the insertion hole 451 of the headless bolt 450 coupled to, it is fastened to the first fastening hole 412 of the first terminal box 410.

And, the second bypass large terminal 530 is fastened to the second fastening hole 422 of the second terminal box 420 provided at the inner rear of the second terminal block 400, and the second bypass small terminal ( 520) is fastened to the first fastening hole 412 of the first terminal box 410 provided on the inside front of the second terminal block 400, so the length of the second bypass large terminal 530 is the second bypass It is formed longer than the length of the small terminal 520.

In addition, an insulating tube 531 is provided on the other side of the outer circumferential surface of the second bypass large terminal 530 to surround the other side of the second bypass large terminal 530 for insulation. The insulating tube 531 is provided for the purpose of preventing an arc or short circuit from occurring in the second bypass large terminal 530 .

On the other hand, after the current sensor-integrated uninterruptible replacement terminal block 100 is installed between the transformer (not shown) and the watt-hour meter, electricity (current and voltage) is transferred to the transformer, the transformer and the second terminal block 400, and the wire and second terminal block ( 400) to flow through.

And, inside the first terminal block, induction proportional to the amount of current flowing from the first input terminal 240 to the second input terminal 250 by the current flowing from the first input terminal 240 to the second input terminal 250. current occurs.

Next, a process of separating the watt-hour meter from the first terminal block 200 will be described.

Referring to FIGS. 2, 9, and 10 , a user inserts and couples the first bypass terminal 310 of the first bypass 300 into the fastening hole 212 of the fixing member 210 .

After that, the user can separate the watt-hour meter from the first board terminal 211 of the first terminal block 200 by pulling the watt-hour meter in one direction (opposite direction of gravity).

Due to this, when the watt-hour meter is damaged or fails, the watt-hour meter can be easily separated from the first terminal block 200.

Next, a process of separating the first terminal block 200 from the second terminal block 400 will be described.

2, 9, and 11, the user connects the second bypass large terminal 530 and the second bypass small terminal 520 of the second bypass 500 to the second terminal box 420, respectively. It is inserted into and coupled to the second fastening hole 422 of and the first fastening hole 412 of the first terminal box 410.

After that, the user can separate the first terminal block 200 from the second terminal block 400 by pulling the first terminal block 200 in one direction (opposite direction of gravity).

Due to this, the second input terminal 250 of the first terminal block 200 is separated from the second through hole 421 of the second terminal box 420 of the second terminal block 400, and the second terminal block 400 The first input terminal 240 of the first terminal block 200 is separated from the first through hole 411 of the first terminal box 410 of the . In addition, the N-phase terminal 270 of the first terminal block 200 is separated from the third through hole 431 of the third terminal box 430 of the second terminal block 400 .

Due to this, when the first terminal block 200 is damaged or out of order, the first terminal block 200 can be easily separated from the second terminal block 400 .

Therefore, in the current sensor 230 integrated uninterruptible replacement terminal block according to the present invention, even when the first terminal block 200 is fastened to the watt-hour meter, the watt-hour meter can be easily separated from the first terminal block 200. In addition, even when the second terminal block 400 is fastened to the first terminal block 200, the first terminal block 200 can be easily separated from the second terminal block 400.

Therefore, even when one of the watt-hour meter or the first terminal block 200 is out of order, the watt-hour meter or the first terminal block 200 can be separately separated and replaced or repaired.

In addition, in the current sensor integrated uninterruptible replacement terminal block 100 according to the present invention, the second bypass 500 is fastened to the second terminal block 400, and the first terminal block 200 or the first A separable structure capable of uninterruptively separating the integrated current sensor 230 included in the terminal block 200 is applied, so that even when the first terminal block 200 or the current sensor 230 is damaged or broken, the first terminal block 200 ) Or the current sensor 230 is separated without interruption, and there is an effect that can be replaced or repaired.

In the current sensor integrated uninterruptible replacement terminal block 100 according to the present invention, the first bypass 300 is fastened to the first terminal block 200 including the current sensor 230 to separate the watt-hour meter from the first terminal block 200. Even if the watt-hour meter is damaged or out of order, the watt-hour meter can be separated without interruption and replaced or repaired.

In addition, in the current sensor-integrated uninterruptible replacement terminal block 100 according to the present invention, a 400/5A current sensor 230 capable of accommodating contract power of 237 kW or less is applied, and a 250/5A current that can accommodate up to a conventional contract power of 148 kW or less Compared to the sensor 230, the range of contract power is extended, and the size of the current sensor 230 is remarkably reduced.

As described above, the main technical idea of the present invention is to provide a current sensor integrated uninterruptible replacement terminal block 100, and the embodiment described above with reference to the drawings is only one embodiment, and the true rights of the present invention The scope is based on the claims, but will extend to equivalent embodiments that may exist in various ways.

100: current sensor integrated uninterruptible replacement terminal block
200: first terminal block 201: first case
205: first cover 206: first coupling hole
210: fixing member 211: board terminal
212: Fastening hole 220: Bus bar on RST
221: head part 222: first leg part
223: second leg 230: current sensor
231: through hole 240: first input terminal
250: second input terminal 260: N-phase bus bar
270: N-phase terminal 300: first bypass
310: first bypass terminal 400: second terminal block
401: second case 402: second coupling hole
405: second cover 406: third coupling hole
407: fourth coupling hole 408: fifth coupling hole
410: first terminal box 411: first through hole
412: first fastening hole 420: second terminal box
421: second through hole 422: second fastening hole
430: third terminal box 431: third through hole
432: third fastening hole 450: no-head bolt
451: insertion hole 500: second bypass
510: second bypass bus bar 520: second bypass small terminal
530: second bypass large terminal 531: insulation tube

Claims (5)

It is fastened to the front of the first terminal block 200 by the first terminal block 200 fastened to the watt-hour meter, and the first bypass terminal 310 provided in plurality on the bottom, so that the watt-hour meter can be moved from the first terminal block 200. A first bypass 300 for separation, a second terminal block 400 fastened to the lower portion of the first terminal block 200, a plurality of second bypass small terminals 520 and a second large bypass provided on the bottom surface It is fastened to the front of the second terminal block 400 by the terminal 530 and is configured to include a second bypass 500 for separating the first terminal block 200 from the second terminal block 400 In the current sensor integrated uninterruptible replacement terminal block 100,
The first terminal block 200 is
A plurality of board terminals 211 are provided in the upper center of the first terminal block 200, and a board terminal 211 fastened to the watt-hour meter protrudes from the upper surface toward the watt-hour meter, and the first bypass terminal 310 is inserted and fixed on the front surface. a fixing member 210 in which the hole 212 is recessed;
It is provided inside the first terminal block 200, but the head part 221 is formed in a curved shape on the upper part, and the first leg part 222 and the second leg part ( 223) are respectively protruded busbars 220 on the RST;
a current sensor 230 having a through-hole 231 penetrating the upper surface so that the second leg 223 of the busbar 220 on the RST can be inserted therethrough;
A first input terminal 240 coupled and fixed to the lower part of the first leg part 222 of the bus bar 220 on the RST;
a second input terminal 250 coupled and fixed to the lower part of the second leg part 223 of the bus bar 220 on the RST;
An N-phase busbar 260 provided on one side of the RST-phase busbar 220; and
A current sensor-integrated uninterruptible replacement terminal block comprising a; N-phase terminal 270 coupled and fixed to the lower portion of the N-phase bus bar 260. According to claim 1,
The second terminal block 400 is
A plurality of the second terminal block 400 is provided on the inner front side, and a first through hole 411 through which the first input terminal 240 is inserted and coupled is formed on the upper surface, and the first through hole ( 411) and a first terminal box 410 through which a first fastening hole 412 communicating with the first terminal box 412 is formed;
A plurality of second through-holes 421 through which the second input terminal 250 is inserted and coupled are formed on the upper surface of the inner rear of the second terminal block 400, and the second through-hole ( 421) and a second terminal box 420 through which a second fastening hole 422 communicated is formed;
It is provided on one side of the first terminal box 410, and a third through hole 431 through which the N-phase terminal 270 is inserted and coupled is formed on the upper surface, and the third through hole 431 on the upper front surface a third terminal box 430 through which a third fastening hole 432 communicates with;
The first fastening hole 412 of the first terminal box 410, the second fastening hole 422 of the second terminal box 420, and the third fastening hole 432 of the third terminal box 430 A current sensor integrated uninterruptible replacement terminal block, characterized in that it includes; a headless bolt 450 having an insertion hole 451 penetrating the front side and corresponding to each. According to claim 1,
The second bypass 500 is
A plurality of second bypass busbars 510 provided inside the second bypass 500;
The second bypass large terminal 530 is
It is provided on one side of the rear side of the second bypass busbar 510, and after the end is inserted through the insertion hole 451 of the headless bolt 450 coupled to the lower front surface of the second terminal box 420, the It is fastened to the second fastening hole 422 of the second terminal box 420,
The second bypass small terminal 520 is
It is provided on the other side of the rear surface of the second bypass busbar 510, and after the end is inserted through the insertion hole 451 of the headless bolt 450 coupled to the lower front surface of the first terminal box 410, the It is fastened to the first fastening hole 412 of the first terminal box 410,
The length of the second bypass large terminal is
Current sensor integrated uninterruptible replacement terminal block, characterized in that formed longer than the length of the second bypass small terminal. According to claim 3,
The second bypass large terminal 530 is
A current sensor integrated uninterruptible replacement terminal block, characterized in that an insulation tube 531 is provided on the other side of the outer circumferential surface to surround the other side of the second bypass large terminal 530 for insulation. According to claim 1,
The second leg part 223 is
The current sensor integrated uninterruptible replacement terminal block, characterized in that the outer surface of the second leg portion 223 is inserted and coupled to line contact with the inner circumferential surface of the through hole 231 of the current sensor 230.

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