KR101830843B1 - An electric power fuse of distribution board - Google Patents

Abstract

The present invention relates to a power fuse regulating the flow of a high-voltage current while being installed in a switchboard. The power fuse includes a support, a fuse bar, a first insulator, a second insulator, and a switch bar. The support is coupled to an inner frame of a container while facing the outer surface. The fuse bar is arranged in parallel with the support and is placed apart from the outer surface and inner frame of the container by the minimum insulation spacing distances, respectively. The first insulator has an end coupled to a side of the support and the other end coupled to an end of the fuse bar through a first conductor inputting a current from a power source. The second insulator has an end coupled to the other end of the support and the other end coupled to the body of the fuse bar through a clamp. The switch bar has an end coupled to a first extension section extended from the other end of the support by hinges and the other end detachably coupled to the other end of the fuse bar through a second conductor outputting the current to a load. The switch bar rotates around the first extension section to electrically connect the fuse bar and the first conductor or cut off the connection to reduce the minimum insulation spacing distances.

Description

An electric power fuse of distribution board

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power fuse for a power switchgear, and more particularly, to a power fuse installed inside a power switchgear for interrupting a flow of a high voltage current.

A power distribution system is a power system that collects current from a generator or a transformer and distributes it to various places. It is a power system that collects and installs a facility for monitoring and controlling the voltage and power supply status and facilities for protecting the generator and the transformer .

The instruments and facilities installed in the switchboard are installed in a rigidly built housing with a certain standard and protected from the outside. Generally, the facilities installed in the enclosure are as follows. The interior of the housing is provided with an inlet for connecting an external power cable from the outside, an automatic fault section switch connected to the inlet, a power fuse connected to the automatic fault section switch, a transformer for a meter connected to the power fuse, A transformer connected to the transformer current transformer is installed. And the cable that branches off between the automatic fault section switch and the power fuse is connected to the lightning arrester.

Here, as shown in FIG. 4, the power fuse 1 is provided inside the power switchboard, and functions as a switch for interrupting the current flow during the inspection and maintenance of the line. The power fuse 1 generally includes a pair of insulators 20 vertically installed on the inner frame 13 of the enclosure and equipped with a conductive part 23 at its end, A conductive fuse bar 30 connected to the conductive part 23 of the insulator 20 and hinged to the conductive part 23 of the insulator 20 and disconnected from the conductive part 23 of the insulator 20, And a transfer cable 42 for connecting the conductive part 23 of the insulator 20 and the transformer 15 for the instrument to each other.

The power fuse 1 should be installed at a distance of at least a minimum insulation distance r from the inner frame 13 and the outer side surface 14 of the enclosure to prevent accidents such as electric shock, It is specified that a minimum insulation distance r of at least 210 mm is secured in an indoor high-voltage switchboard usually having a capacity of 22.9 KV or less.

The conventional power fuse 1 has a structure in which the fuse bar 30 approaches the outer surface 14 of the enclosure while rotating about the end of the insulator 20 below. Therefore, in the conventional switchboard, the enclosure must be designed by adding the distance l that the fuse bar 30 approaches the enclosure to the minimum insulation distance r between the enclosure and the fuse bar 30.

As a result, the increase in the size of the switchgear increases the manufacturing and transporting burdens, and the space occupied by the switchgear within the building is widened.

Korean Registered Patent No. 10-0715627 (Registered on Aug. 5, 2007, entitled "High-voltage bushing type fuse holder for distribution and distribution structure using the same"

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a fuse capable of opening and closing a power fuse without affecting a minimum insulation separation distance required for a power plant, A power supply fuse of a power distribution system is provided.

The fuse for power of the switchgear according to the present invention includes a support 100 coupled to the inner frame 12 of the enclosure 10 in such a manner as to face the outer side 11 of the enclosure 10, ); A fuse bar 150 disposed in parallel to the support 100 and spaced apart from the outer surface 11 and the inner frame 12 of the enclosure 10 by a minimum insulation distance r; One end of the fuse bar 150 is coupled to one side of the support 100 and the other end is connected to one end of the fuse bar 150 via a first conductive part 210, 200); A second insulative insulator 250 coupled at one end to the other side of the support 100 and at the other end to the body of the fuse bar 150 via a clamp 260; And one end is hinged to a primary extension section 101 extending from the other side of the support 100 and the other end is connected to the fuse bar 150 via a second conductive part 310, And a switch bar 300 detachably coupled to the other end of the fuse bar 150. The switch bar 300 is pivotally moved downward about the first extension section 101, The minimum insulation distance r is reduced by electrically connecting or disconnecting the second conductive part 310 and the secondary insulation section 102 extending further in the primary extension section 101 of the support 100 An intermediate contact point 350 provided on the upper side; A transfer cable 400 connecting the intermediate contact 350 to the load side; A flexible wire 450 connecting the intermediate contact 350 and the second conductive part 310 and flexing freely according to the rotation of the switch bar 300; And a stopper 500 spaced apart from the intermediate contact 350 and coupled to the secondary extension section 102 such that the rotation angle of the switch bar 300 is within a predetermined range. do.

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The second conductive part 310 may include a fixing part 311 coupled to the other end of the switch bar 300 and a fixing part 311 formed on both sides of the fixing part 311, A pair of side pieces 312 formed vertically and detachably attached to the other end of the fuse bar 150 and a connection terminal 313 coupled to the fixing piece 311 and connected to the load side, The side piece 312 includes a protruding section 312a protruding from the fixing piece 311 and a contact section 312b extending from an end of the protruding section 312a and surrounding the other end of the fuse bar 150, A tightening connector 550 which is divided into an extension section 312c extending in parallel with the protrusion section 312a at an end of the close section 312b and penetrating the extension section 312c of the side piece 312; A cam lever 600 coupled to one end of the tightening coupling 550 and having a cam surface 610 that abuts the extended section 312c and has a turning radius varying about the pin p, ; And a fixing nut 650 which is fastened to the other end of the tightening connector 550. The cam lever 600 rotates about the pin p in a direction in which the rotation radius of the cam surface 610 increases The fuse bar 150 is fixed to the second conductive part 310 while the extension part 312c is narrowed and when the cam lever 600 is rotated in the opposite direction, So that the fuse bar 150 can be separated from the second conductive part 310.

According to the power fuse of the present invention, it is possible to provide a more compact and lighter weight switchgear by opening and closing the power fuse while the switch bar which does not affect the minimum insulation gap rotates up and down, The burden can be reduced, and the space efficiency of the building can be increased.

Further, since the flexible wire connecting the intermediate contact point and the second conductive portion is bent freely according to the rotation of the switch bar, the switch bar can be smoothly rotated, and the rotation angle of the switch bar is limited by the stopper, Can be prevented from deteriorating.

Particularly, the second conductive portion can be easily and easily attached to and detached from the fuse bar by opening or pulling the cam lever, and the second conductive portion can be firmly and stably fixed to the fuse bar using the lever principle.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view of a power fuse installed in a cabinet according to an embodiment of the present invention,
FIG. 2 is a view showing a state in which a power fuse of the power switchboard of FIG. 1 is opened and closed,
FIG. 3 is a view for explaining a structure in which a second conductive part included in a power fuse of the switchboard of FIG. 1 is detachably attached to a fuse bar,
FIG. 4 is a view showing a state in which a power fuse of a conventional switchboard is opened and closed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of power fuses according to the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

FIG. 1 is a side view of a power fuse installed in a cabinet according to an embodiment of the present invention, FIG. 2 is a view showing a power fuse of a power plant in FIG. 1 being opened and closed, Is a view for explaining a structure in which the second conductive part included in the power fuse of the power switch of Fig. 1 is detachably attached to the fuse bar.

1 to 3, a fuse for power in a switchboard according to an embodiment of the present invention controls a flow of a high-voltage current in a switchboard, and includes a support 100, a fuse bar 150, A first insulative insulator 200, a second insulative insulator 250, and a switch bar 300.

The support 100 is coupled to the inner frame 12 of the enclosure 10 in a manner facing the outer surface 11 of the enclosure 10. The support 100 includes a planar portion to which the first and second insulative insulators 200 and 250 are fixed and a side portion to which the switch bar 300 is hingedly bent at both sides of the planar portion, Form.

The fuse bar 150 is disposed in parallel with the support 100 and is disposed at a minimum distance of separation r from the outer side 11 of the enclosure 10 and the inner frame 12 respectively. The minimum insulation separation distance r is a minimum distance for preventing insulation breakdown due to a high voltage, that is, a minimum distance required for safety to prevent electricity from flowing between the fuse bar 150 and the enclosure 10, The distance increases.

The fuse bar 150 functions as a fuse to cut off the current when an accident current or an overcurrent flows through the line, and when the line is inspected, the switch cable 300 opens and closes the output cable 400 (load side) As shown in Fig.

One end of the first insulative insulator 200 is coupled to one side of the supporter 100 and the other end of the first insulative insulator 200 is coupled to one end of the fuse bar 150 through a first conductive part 210, do.

The conventional conductive part has a structure in which one end of the fuse bar is detachably attached, whereas the structure in which the first conductive part 210 according to the present embodiment can simply fix the fuse bar 150 is sufficient. Specifically, the first conductive portion 210 is configured in a form of a rod-shaped copper bus bar coupled to a strap clamp having a "C" shape.

The second insulative insulator 250 has one end coupled to the other side of the support 100 and the other end coupled to the body of the fuse bar 150 via a clamp 260. The second insulative insulator 250 functions to hold the fuse bar 150 so as not to shake. The clamp 260 is equally used as a strap clamp applied to the first conductive portion 210 for convenience of manufacturing.

Conventionally, if the fuse bar is hinged to the clamp fixed to the insulator, the fuse bar 150 according to the present embodiment is fixed by the first and second insulating insulators 200 and 250 and does not move .

The switch bar 300 is an insulator having one end hinged to the primary extension 101 extending from the other side of the support 100 and the other end hinged to the fuse bar 150 via the second conductive part 310. [ As shown in Fig.

The second conductive part 310 has the same structure as the first conductive part 210 and is installed vertically symmetrically with the first conductive part 210.

In this embodiment, the fuse bar 150 and the second conductive part 310 are electrically connected or disconnected as the switch bar 300 rotates downward about the first extension section 101 .

In the prior art, the fuse bar rotates relative to the end of the lower insulator and approaches the outer surface of the enclosure. For this reason, when fabricating the enclosure, the width of the enclosure had to be designed by adding the distance required for the fuse bar to approach the enclosure to the minimum insulation separation distance required between the enclosure and the fuse bar.

The housing 10 of the switchboard, also called a cubicle, increases the manufacturing cost including the inner partition in proportion to the size, and the size of the floor foundation work and the pad installation work in which the housing is placed can not but increase. In particular, the larger the size and weight of the switchboard (typically 800 to 1,200 kg), the more difficult it is to carry, and the space occupied by the switchboard in the building becomes wider. For example, a switchboard installed in an apartment is mainly installed in an underground parking lot. The larger the size, the smaller the total parking area.

In contrast, in the present embodiment, the fuse bar 150, which affects the minimum insulation distance r, remains fixed, and the switch bar 300, which does not affect the minimum insulation distance r, The fuse bar 150 and the second conductive part 310 are electrically connected or disconnected. In other words, the required minimum insulation clearance r is reduced.

With this structure, since the width of the housing 10 can be minimized, the present embodiment can provide a more compact and lighter weight switchgear, reduce the manufacturing and transportation burden of the switchgear, There are advantages to be able to.

However, the present embodiment is different from the conventional one in that the distance between the second conductive portion 310 and the load side, that is, the distance between the second conductive portion 310 and the transfer cable 400 The distance is variable.

Therefore, the switch bar 300 may be configured as follows to allow the switch bar 300 to operate smoothly. 2, an intermediate contact 350 is provided on a secondary extension section 102 which is further extended in the primary extension section 101 of the support 100, and an intermediate contact 350 is provided on the intermediate contact 350) and the load side are connected. The distance between the intermediate contact point 350 and the second conductive portion 310 is changed by the rotation of the switch bar 300. The distance between the intermediate conductive point 310 and the intermediate contact point 350 (450) are freely bent and accommodated.

The greater the rotation angle of the switch bar 300, the weaker the durability of the flexible wire 450 can be. As a countermeasure thereto, it is preferable to arrange the stopper 500 on the secondary extension section 102 at a distance from the intermediate contact point 350 so that the rotation angle of the switch bar 300 is kept within a certain range.

On the other hand, the fuses for electric power of the conventional switchgear can only be designed so that the fuse bars are not released to the outside of the conductive parts. Conventionally, a fuse bar is detachably attached in such a manner that a fuse bar is inserted into a conductive part while a U-shaped latch is fastened to the outside of the conductive part, and then the latch is forcedly locked by pressing the latch.

However, in the present embodiment, the second conductive part 310 is detachably attached to the other end of the fuse bar 150 by the rotation of the switch bar 300 while the fuse bar 150 is fixed. The second conductive part 310 may be firmly fixed to the other end of the fuse bar 150 and the second conductive part 310 may be fixed to the other end of the fuse bar 150 when the power transmission / It should be able to be easily separated from the other end.

To this end, the second conductive portion 310 according to the present embodiment is configured as follows. 3, the second conductive part 310 includes a fixing part 311 coupled to the other end of the switch bar 300, and a fuse bar 150 formed vertically on both sides of the fixing part 311, And a connection terminal 313 coupled to the fixing piece 311 and connected to the load side via the transfer cable 400. The connection terminal 313 is connected to the load side through the transfer cable 400. [

The side piece 312 has a protruding section 312a protruding from the fixing piece 311 and a close contact section 312b extending from the end of the protruding section 312a and surrounding the other end of the fuse bar 150, And an extension section 312c extending in parallel with the protruding section 312a at the end of the protruding section 312b.

A fastening connector 550 made of a flat disk with a head part is inserted through the extension section 312c of the side piece 312 in the shape of a bolt. The cam lever 600 is rotatably coupled to one end of the tightening coupling hole 550 and the fixing nut 650 is coupled to the other end. The cam lever 600 is connected to one end of the tightening coupling 550, that is, to the head, a cam surface 610 which abuts on the extending section 312c and has a turning radius varying about the pin p Respectively.

When the cam lever 600 is rotated in the direction of increasing the radius of rotation of the cam surface 610 about the pin p, the distance between the extended sections 312c becomes narrower, and the fuse bar 150 moves to the second conductive portion 310 When the cam lever 600 is rotated in the opposite direction, the fuse bar 150 is separated from the second conductive portion 310 as the extended portion 312c is widened.

That is, in this embodiment, the cam lever 600 can be pulled easily and the second conductive portion 310 can be easily attached to and detached from the fuse bar 150. By tightening the side piece 312 using the lever principle, The second conductive portion 310 can be firmly and stably fixed to the fuse bar 150.

The power fuse of the present invention constructed as described above can provide a more compact and lighter weight switchgear by opening and closing the fuse for power while the switch bar which does not affect the minimum insulation gap rotates up and down, It is possible to reduce the manufacturing and transportation burden of the building, and the space efficiency of the building can be increased.

Further, since the flexible wire connecting the intermediate contact point and the second conductive portion is bent freely according to the rotation of the switch bar, the switch bar can be smoothly rotated, and the rotation angle of the switch bar is limited by the stopper, Can be prevented from deteriorating.

Particularly, the second conductive portion can be easily and easily attached to and detached from the fuse bar by opening or pulling the cam lever, and the second conductive portion can be firmly and stably fixed to the fuse bar using the lever principle.

The scope of the present invention is not limited to the above-described embodiments and modifications, but can be implemented in various forms of embodiments within the scope of the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

100: Support
150: Fuse bar
200: first insulative insulator
250: Second insulating insulator
300: Switch bar
r: Minimum insulation clearance

Claims (3)

(100) coupled to the inner frame (12) of the housing (10) in a form facing the outer side (11) of the housing (10);
A fuse bar 150 disposed in parallel to the support 100 and spaced apart from the outer surface 11 and the inner frame 12 of the enclosure 10 by a minimum insulation distance r;
One end of the fuse bar 150 is connected to one side of the support 100 and the other end is connected to one end of the fuse bar 150 through a first conductive part 210, 200);
A second insulative insulator 250 coupled at one end to the other side of the support 100 and at the other end to the body of the fuse bar 150 via a clamp 260; And
One end of the fuse bar 150 is hinged to the first extension section 101 extending from the other side of the support 100 and the other end is connected to the fuse bar 150 via the second conductive section 310, And a switch bar 300 detachably coupled to the other end of the switch bar 300,
The switch bar 300 is pivoted downward about the first extension section 101 to electrically connect or disconnect the fuse bar 150 and the second conductive section 310, (r) is reduced,
An intermediate contact 350 provided on the secondary extension section 102 which is further extended in the primary extension section 101 of the support 100;
A transfer cable 400 connecting the intermediate contact 350 to the load side;
A flexible wire 450 connecting the intermediate contact 350 and the second conductive part 310 and flexing freely according to the rotation of the switch bar 300; And
And a stopper 500 spaced apart from the intermediate contact 350 and coupled to the secondary extension section 102 such that the rotation angle of the switch bar 300 is within a predetermined range Power fuse for switchgear. delete The method according to claim 1,
The second conductive portion 310 includes a fixing piece 311 coupled to the other end of the switch bar 300 and a second conductive portion 311 formed vertically on both sides of the fixing piece 311, A pair of side pieces (312) detachably attached to the other end, and a connection terminal (313) coupled to the fixing piece (311) and connected to the load side,
The side piece 312 includes a protruding section 312a projecting from the fixing piece 311 and a contact section 312b extending from an end of the protruding section 312a and surrounding the other end of the fuse bar 150. [ And an extension section 312c extending in parallel with the protrusion section 312a at an end of the close section 312b,
A tightening connector 550 passing through an extension section 312c of the side piece 312;
A cam lever 600 coupled to one end of the tightening coupling 550 and having a cam surface 610 that abuts the extended section 312c and has a turning radius varying about the pin p, ; And
And a fixing nut 650 fastened to the other end of the tightening connector 550,
When the cam lever 600 rotates in the direction of increasing the radius of rotation of the cam surface 610 about the pin p, the interval between the extended sections 312c becomes narrower, The fuse bar 150 is fixed to the conductive portion 310 and the fuse bar 150 is separated from the second conductive portion 310 when the cam lever 600 is rotated in the opposite direction Fuse for power supply of switchgear featuring.

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