KR101922152B1 - Driving apparatus for 3-position switch connected to fuse - Google Patents

Abstract

And a coil spring which is rotatably installed on the fixed shaft and is compressed by an external force, the first and second rotating parts being rotatably connected to the first and second rotating parts, A first power transmitting portion connected to the first rotating portion and rotating the first rotating portion by an external force, a second power transmitting portion connected to the first rotating portion and rotating the first rotating portion by an external force, A second rotation part that is rotated by a restoring force of the coil spring, a rotation shaft that is assembled with the second rotation part and rotates in conjunction with the second rotation part, and a stopper part that is provided on the rear plate and adjusts rotation of the second rotation part And the second power transmission unit, so that the second power transmission unit is rotated when the fuse is operated It is a fuse connected to switch 3-phase drive system which includes a stopper unit is disclosed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-

The present invention relates to a fuse-connected three-phase switch drive apparatus.

In general, the switchboard may be equipped with a fuse-equipped power distribution booth with a load break switch (LBS), ie a three-phase switch. That is, in order to prevent the abnormally high voltage entering from outside or connected to the power line in the power cycle, the power distribution panel is provided with a fuse power distribution booth for the purpose of safety of the equipment.

On the other hand, the fuse distribution booth is provided with a three-phase switch driving device for driving the three-phase switch.

However, the three-phase switch provided in the fuse distributing booth is not connected to the fuse, so that the three-phase switch can not be driven more quickly than when the fuse is blown.

Further, in recent years, it has been necessary to develop a three-phase switch driving device which can precisely control the driving of the three-phase switch provided in the fuse distribution booth and has a simpler structure.

Korean Patent Publication No. 2000-0074358

The present invention provides a fuse-connected three-phase switch drive device having a simple structure and excellent assembling performance.

Further, it provides a fuse-connected three-phase switch drive device capable of controlling the three-phase switch more precisely in operation of the fuse.

The fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention includes a front and rear plates spaced apart from each other by a predetermined distance, a fixed shaft connected to at least one of the front and rear plates, A first power transmitting portion connected to the first rotating portion and rotating the first rotating portion by an external force, and a second power transmitting portion connected to the first rotating portion, A second rotating portion rotated by a restoring force of the coil spring, a rotating shaft assembled to the second rotating portion and rotated in association with the second rotating portion, A stopper portion provided on the rear plate for adjusting the rotation of the second rotating portion, and a stopper portion provided on the front and rear plates Installation and includes a stopper unit for causing the first rotating portion 2, a power transmission during operation of the fuse.

The first power transmission portion may include a first power transmission member rotatably installed on the fixed shaft portion and a power transmission bar installed on the first power transmission member and rotating the first rotation portion in one direction.

A second power transmitting member rotatably coupled to the power transmitting shaft and rotated by an external force; and a second power transmitting member rotatably coupled to the power transmitting shaft, wherein the second power transmitting member is rotatably installed on the front and rear plates, A second rotary member that is spaced apart from the first rotary member by a predetermined distance and is rotatably installed on the second power transmission unit fixed shaft, A second power transmission link member connected to the rotary member through a connection shaft; a link shaft fixed to an end of the second power transmission link member to rotate the first rotation unit in the other direction; And a driving force which is connected to the engaging member through a wire and rotates the first rotating part when the fuse is operated, And a second power transmitting portion spring unit for providing the second power transmitting portion spring unit.

The second power transmitting portion spring unit includes a mounting plate fixedly installed on the front and rear plates, a dowel rotatably installed on the mounting plate and guiding the wire, A spring inserted into the housing, and a support member movably installed at an end of the housing to compress the spring when the wire is moved.

Wherein the first rotation part is rotatably installed on the fixed shaft part and is rotated in one direction or the other direction by the first and second power transmission parts, and a coil spring connected to the arm unit and being expanded / contracted by rotation of the arm unit, And a spring unit provided with the spring unit.

The arm unit includes a first arm member rotatably installed on the fixed shaft portion and rotatable by the first power transmitting portion and having a bent shape on one side, and a second arm member rotatably installed on the fixed shaft portion, A second arm member which is rotated by the power transmission unit and has a shape bent to the other side; and a second arm member which is rotatably installed on the fixed shaft unit and has one end fixed to the spring unit and the other end connected to the second power transmission unit, A third arm member rotatable in association with the second arm member when the second arm member rotates, and a second arm member rotatably installed on the fixed shaft portion and having an end fixed to the spring unit, And a fourth arm member rotated in conjunction with the first arm member.

The spring unit includes an upper support member connected to the ends of the second and third arm members, the coil spring having one end supported by the upper support member, and a second spring member supporting the other end of the coil spring, And a guide member connecting the upper support member and the lower support member to each other.

The upper and lower support members may have a circular annular shape and include the upper and lower supporters for supporting the coil springs and upper and lower supporters installed to penetrate the upper and lower supporters.

The guide member may include an upper guide hole for guiding the movement of the upper support shaft and a lower guide hole for guiding movement of the lower support shaft.

Wherein one end of the upper support shaft is fixed to the second arm member and the other end is fixed to the third arm member, one end of the lower support shaft is fixed to the first arm member and the other end is fixed to the fourth arm member Can be fixedly installed.

The first power transmission unit includes a first power transmission member having a power transmission bar protruded toward the first and second arm members. The first and second arm members are inserted with the power transmission bar when assembled to the fixed shaft unit The first and second power transmission bar insertion grooves may be formed to form the insertion holes.

A third arm member stopper for preventing rotation in the other direction when power is transmitted is formed in the third arm member, and a fourth arm member stopper for preventing rotation in the other direction when power is transmitted to the fourth arm member, Can be formed.

The third arm member is formed with a third arm member round portion formed to extend in a direction opposite to the side where the third arm member stopper is formed, and the fourth arm member stopper is formed on the fourth arm member A fourth arm member round portion formed to extend in a direction opposite to the first arm member portion may be formed.

A first stopper member rotatably mounted on the plate unit so as to be rotatable about the first pivot shaft, and a second stopper member fixed to the plate unit so as to have a predetermined angle with respect to the first stopper member, And a second stopper member rotatably installed around the second pivot shaft.

The plate unit includes a first plate fixed to the rotating shaft, a second plate fixed to the rotating shaft so as to be spaced apart from the first plate by a predetermined distance, A third stopper member fixed to the circular plate, and a fourth stopper member fixed to the circular plate so as to be spaced apart from the third stopper member.

The plate unit includes a first connection member protruding from the first plate so that an end thereof is connected to the interlocking rotary plate provided in the first power transmission unit, and a second connection member protruding from the first plate to be separated from the first plate, And a second connection member having an end connected to the interlocking rotary plate.

The plate unit may further include a support shaft having both ends fixed to the first and second plates, and a leaf spring attached to the support shaft and having both ends contacted with the first and second stopper members.

The first and second stopper members may include first and second pivot portions pivotably installed on the first and second pivot shafts, and first and second pivot portions extending from the first and second pivot portions, 2 first and second extension bars for pivoting the pivot portion.

Wherein the stopper portion includes a first stopper portion for restricting rotation of the first stopper member and a second stopper portion for restricting rotation of the second stopper member, wherein the first stopper portion is composed of three stopper members, The second stopper portion may be formed of two stopper members.

Wherein the stopper unit includes a stopper shaft rotatably installed on the front and rear plates and formed with a passage groove for rotating the power transmitting unit, a handle portion connected to one side of the stopper shaft so as to be protruded from the front plate, A spring member inserted into the other end of the stopper shaft and having one end supported by a support pin provided on the rear plate; a mounting pin fixedly installed on the stopper shaft so that the other end of the spring member is installed; And a wire mounting member fixed to the stopper shaft and having a fuse connecting wire for connection with a fuse.

The fuse-connected three-phase switch driving device is fixed to a mounting plate installed on the rear plate so as to be disposed adjacent to the stopper unit. The solenoid includes a solenoid protruding to the outside and a stopper shaft And an interlocking plate fixedly installed on the upper surface of the base plate.

The fuse-connected three-phase switch driving device may further include a driving unit fixed to at least one of the front and rear plates and rotating the second power transmission unit.

According to another aspect of the present invention, there is provided a fuse-connected three-phase switch drive adjustment device comprising: a front and rear plates spaced apart from each other by a predetermined distance; a fixed shaft connected to and fixed to at least one of the front and rear plates; A first power transmitting portion connected to the first rotating portion and rotating the first rotating portion by an external force, and a second power transmitting portion connected to the first rotating portion, A second rotation part rotated by a restoring force of the coil spring, a rotation shaft assembled to the second rotation part and rotated in association with the second rotation part, A stopper portion provided on the rear plate and adapted to adjust the rotation of the second rotating portion, A solenoid fixed to the mounting plate installed on the rear plate so as to be adjacent to the stopper unit and fixed to the mounting plate so that the push pin protrudes to the outside, An interlocking plate fixed to the stopper shaft so as to be in contact with the push pin, and a driving unit fixed to at least one of the front and rear plates and rotating the second power transmission unit.

There is an effect that the number of parts is reduced through the coil spring and the assembling property is improved.

Further, there is an effect that the three-phase switch can be driven to change from the energized state to the disconnection state more quickly through the stopper unit.

1 is a schematic perspective view showing a distribution booth for a fuse installed with a fuse-connected three-phase switch driving device according to an embodiment of the present invention.
2 is a perspective view illustrating a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
FIG. 3 is a perspective view of the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention, viewed from an angle different from FIG.
FIG. 4 is a perspective view of the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention, viewed from an angle different from FIG. 2 and FIG.
5 is an explanatory diagram illustrating a first power transmission unit and a first rotation unit included in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
FIG. 6 is an exploded perspective view illustrating a first rotating unit included in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
7 is an explanatory diagram illustrating a second power transmission unit included in the fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
8 is an explanatory diagram of a second power transmission unit provided in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention, viewed from an angle different from that of FIG.
FIG. 9 is an explanatory diagram illustrating a second rotary part of the fuse-connected three-phase switch driving device according to the embodiment of the present invention.
10 is an exploded perspective view for explaining a second rotary part of a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
FIG. 11 is an explanatory view for explaining the operation of the fuse-connected three-phase switch driving apparatus provided in the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention.
FIG. 12 is an explanatory view of the operation of the fuse-connected three-phase switch driving apparatus provided in the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention, viewed from an angle different from FIG.
FIG. 13 is an explanatory diagram for explaining operation of a fuse-connected three-phase switch driving device by a driving unit included in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.
14 is a perspective view illustrating a fuse holder according to an embodiment of the present invention.
15 is a partially exploded perspective view showing a fuse holder according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. The shape and size of elements in the drawings may be exaggerated for clarity.

First, a brief description will be given of a fuse-type power distribution booth in which a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention is installed. A fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention will now be described .

1 is a schematic perspective view showing a distribution booth for a fuse installed with a fuse-connected three-phase switch driving device according to an embodiment of the present invention.

Referring to FIG. 1, the power distribution booth 10 for a fuse may include, for example, a fuse section body 20, a fuse-connected three-phase switch drive device 100, and a fuse holder 300.

The fuse section body 20 has an internal space and a three-phase switch (not shown) may be provided therein.

Further, the fuse section body 20 may be provided with one end of the fuse 30 exposed to the outside. In other words, the fuse 30 may be installed in the fuse holder 300 so that one end may be exposed to the outside of the fuse section body 20.

Meanwhile, the fuse holder 300 may be connected to the fuse-connected three-phase switch driving device 100 through the fuse connecting wire 370.

That is, in operation of the fuse 30, the fuse connecting wire 370 is pulled by the fuse holder 300, and the fuse connecting three-phase switch driving device 100 by the fuse connecting wire 370 applies the three- State to the disconnected state.

A detailed description thereof will be described later.

On the other hand, the fuse-connected three-phase switch driving apparatus 100 is fixed to the fuse section body 20 and can be disposed adjacent to the fuse holder 300.

FIG. 2 is a perspective view of a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention, FIG. 3 is a perspective view of a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention, And FIG. 4 is a perspective view of the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention, viewed from an angle different from FIG. 2 and FIG.

2 to 4, a fuse-connected three-phase switch driving apparatus 100 according to an embodiment of the present invention includes a front plate 110, a rear plate 120, a fixed shaft 130, The first power transmitting unit 140, the first rotating unit 150, the second power transmitting unit 170, the second rotating unit 180, the rotating shaft 195, the stopper unit 200, the stopper unit 210, 220, a solenoid 230, and an interlocking plate 240.

The front plate 110 may have a rectangular plate shape. Meanwhile, the front plate 110 may be formed with an exposure hole 112 through which the rotary shaft 195 and the fixed shaft 130 are exposed.

The front plate 110 is disposed adjacent to the exposure hole 112, and the first rotation state or the hole 114 may be formed so that the extended line is arc-shaped. That is, the front plate 110 may be formed so that the first rotation state of the first power transmission unit 150 can be recognized, or the holes 114 may be disposed adjacent to the exposure holes 112.

A drive bar or the like is connected to the first power transmission part 150 exposed through the hole 110 in the first rotation state or the like to allow the operator to directly rotate the first power transmission part 150 It is possible.

The front plate 110 is spaced apart from the first rotating state or hole 114 and has a second rotating state or hole 116 capable of recognizing the rotating state of the second power transmitting part 170 .

A driving bar or the like is connected to the second power transmitting portion 170 exposed from the front plate 110 through the hole 116 in the second rotating state so that the operator manually rotates the second power transmitting portion 170 .

The rear plate 120 is spaced apart from the front plate 110 by a predetermined distance and may have the same shape as the front plate 110.

The rear plate 120 may have a through hole (not shown) through which the rotation shaft 195 passes so that the rotation shaft 195 can be projected outward. The stopper portion 200 may be provided on the inner surface of the rear plate 120.

The front plate 110 and the rear plate 120 are coupled through the coupling member 102 and the front and rear plates 120 can be spaced apart from each other by a distance corresponding to the length of the coupling member 102.

The fixed shaft portion 130 may be connected to and fixed to at least one of the front and rear plates. 5, the fixed shaft portion 130 may serve as a center shaft in which the first rotation portion 140 is rotatably installed.

Meanwhile, the fixed shaft portion 130 may be formed by assembling a plurality of members, and a detailed description thereof will be omitted.

FIG. 5 is an explanatory view illustrating a first power transmission unit and a first rotation unit included in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention.

5, the first power transmission unit 140 is connected to the first rotation unit 150 to rotate the first rotation unit 150 by an external force. The first power transmitting portion 140 includes a first power transmitting member 142 rotatably installed on the fixed shaft portion 130 and a first power transmitting member 142 installed on the first power transmitting member 142 to rotate the first rotating portion 150 And a power transmission bar 144 for rotating the power transmission bar 144. [

In addition, the first power transmission unit 140 may further include an interlocking rotation plate 146 that can be rotated in conjunction with the second rotation unit 180. [ Meanwhile, the interlocking rotary plate 146 may be installed on the outer peripheral surface of the first power transmitting portion 142 so as to be rotated separately from the first power transmitting portion 142.

Meanwhile, the first power transmitting member 142 may be provided with a drive bar installation hole 142a exposed through the hole 114 in the first rotation state. The driving bar mounting hole 142a may be disposed in the first rotating state or in the hole 114 or may be disposed apart from the hole 114 when the first power transmitting member 142 rotates.

That is, the drive bar installation hole 142a is disposed in the hole 114 in the first rotation state only when the three-phase switch (not shown) is in the disconnected state or the grounded state by the rotation shaft 195, The drive bar installation hole 142a is disposed apart from the hole 114 in the first rotation state.

Therefore, when the three-phase switch is in the energized state, the operator can not rotate the first power transmitting member 142 through the driving bar.

In other words, the first power transmitting member 142 serves to transmit the power when rotating the rotary shaft 195 such that the three-phase switch changes from the disconnected state to the grounded state or from the grounded state to the disconnected state.

The sixth aspect of the present invention is an exploded perspective view for explaining a second rotating part included in the fuse-connected three-phase switch driving device according to an embodiment of the present invention.

The first rotary part 150 may include a coil spring 160 that is rotatably installed on the fixed shaft part 130 and is compressed by an external force.

The first rotary part 150 may include a female unit 151 and a spring unit 156, as shown in more detail in FIG.

First, referring to the arm unit 151, the arm unit 151 is rotatably installed on the fixed shaft part 130 and can be rotated in one direction or the other direction by the first and second power transmission parts 140 and 170.

The arm unit 151 may include a first arm member 152, a second arm member 153, a third arm member 154, and a fourth arm member 155.

The first arm member 152 may be rotatably mounted on the fixed shaft 140 and may be rotated by the first power transmission unit 140 and may have a bent shape.

That is, when the first power transmitting member 142 of the first power transmitting portion 140 is rotated in one direction, the first arm member 152 may be rotated in one direction in association with the first power transmitting member 142. The first arm member 152 may have a shape curved to one side for connection with the spring unit 156.

That is, the first arm member 152 may have a substantially 'A' shape when engaged with the fixed shaft portion 130, and may include a first arm member engaging hole 152a at one end thereof for engaging with the fixed shaft portion 130, Can be formed. In addition, the other end of the first arm member 152 may be connected to the spring unit 156.

Meanwhile, a first power transmission bar insertion groove 152b into which the power transmission bar 144 is inserted may be formed at a portion where the first arm member 152 is rounded. As the power transmission bar 144 is inserted and disposed in the first power transmission bar insertion groove 152b, the first arm member 152 can be rotated in one direction when the power transmission bar 144 is rotated in one direction .

However, when the power transmitting bar 144 is rotated in the other direction, since the power transmitting bar 144 is separated from the first power transmitting bar inserting groove 152b, the power transmitting bar 144 is rotated in the other direction The rotation of the first arm member 152 can be prevented.

When the first arm member 152 rotates, the spring unit 156 may be rotated in conjunction with the rotation of the first arm member 152, so that the coil spring 160 can be compressed by the rotation of the first arm member 152.

The second arm member 153 is rotatably installed on the fixed shaft portion 130 and is rotated by the first and second power transmission portions 140 and 170 and is bent in a direction opposite to the direction in which the first arm member 152 is bent Lt; / RTI >

In other words, the second arm member 153 may have a substantially 'B' shape when engaged with the fixed shaft portion 130.

On the other hand, a second arm member engaging hole 153a for engaging with the fixed shaft portion 130 may be formed at the center of the second arm member 153. [ A spring unit 156 may be connected to one end of the second arm member 153.

That is, one end of the second arm member 153 may be connected to the spring unit 156 at the other side of the portion where the first arm member 152 is connected. In other words, when the first arm member 152 is connected to a portion supporting one side of the coil spring 160, the second arm member 153 may be connected to a portion supporting the other side of the coil spring 160.

The coil spring 160 provided on the spring unit 156 is rotated by the rotation of the second arm member 143. In this case, Lt; / RTI >

The second arm member 153 may be formed at the center thereof with a second power transmission bar insertion groove 153b into which the power transmission bar 144 is inserted.

Meanwhile, the first and second power transmission bar insertion grooves 152b and 153b may form an insertion hole into which the power transmission bar 144 is inserted. In other words, when the first and second arm members 152 and 153 are installed on the fixed shaft portion 130, the first and second power transmission bar insertion grooves 152b and 153b may form one insertion hole. For this, the first and second power transmission bar insertion grooves 152b and 153b may have a semicircular shape.

When the power transmission bar 144 is inserted into the second power transmission bar insertion groove 153b and the power transmission bar 144 is rotated in the other direction, the second arm member 153 is rotated in the other direction , And the second arm member 153 may not be rotated when the power transmission bar 144 is rotated in one direction.

Meanwhile, the second arm member 153 may be provided with a second power transmitting portion connecting portion 153c for connecting with the second power transmitting portion 170. The second power transmitting portion connecting portion 153c may be provided with a mounting hole 153d for connection with the second power transmitting portion 170. [

Accordingly, the second arm member 153 can be rotated by the second power transmitting portion 170 as well.

A detailed description thereof will be described later.

The first and second arm members 152 and 153 may be coupled to the fixed shaft 130 so as to be adjacent to the front plate 110.

The third arm member 154 is rotatably installed on the fixed shaft portion 130 and has one end fixed to the spring unit 156 and the other end connected to the second power transmission portion 170 to form a second arm member 153 The second arm member 153 can be rotated.

To be more specific, the third arm member 154 may be formed with a third arm member engaging hole 154a so as to be rotatably installed on the fixed shaft portion 130. That is, the third arm member 154 is installed on the fixed shaft portion 130 so that the fixed shaft portion 130 passes through the third arm member engaging hole 154a. Accordingly, the third arm member 154 can be rotated about the fixed shaft portion 130.

On the other hand, a third arm member stopper 154b protruding downward may be formed at the center of the third arm member 154. [ That is, the third arm member 154 may be protruded so that the third arm member stopper 154b is disposed below the third arm member engaging hole 154a to prevent the third arm member 154 from rotating in the other direction when the power is transmitted . Furthermore, the third arm member stopper 154b can form a semicircular groove.

Further, the third arm member 154 may be formed with a third arm member round portion 154c formed to extend in a direction opposite to the side where the third arm member stopper 154b is formed and rounded.

The inner circumferential surface of the third arm member round portion 154c serves to rotate the second rotating portion 180, and a detailed description thereof will be described later.

A spring unit connecting portion 154d extending in the same direction as the extending direction of the third arm member round 154c is formed on the opposite side of the third arm member 154 on which the third arm member round portion 154c is formed, Can be formed.

That is, the third arm member 154 is connected to the portion supporting the other side of the coil spring 160 together with the second arm member 153, so that when the second arm member 153 rotates, And can be rotated in conjunction with the second arm member 153 as shown in FIG.

In this manner, the coil spring 160 provided in the spring unit 156 can be compressed by rotating the second and third arm members 153 and 154.

Further, the third arm member 154 may be provided with a second power transmitting portion 154e for connecting with the second power transmitting portion 170 like the second arm member 153. [ Further, a mounting hole 154f for connection with the second power transmitting portion 170 may be formed in the second power transmitting portion connecting portion 154e.

The third arm member 154 is connected to the second power transmitting portion 170 through the second power transmitting portion connecting portion 154e so that the third arm member 154 can be moved by the second power transmitting portion 170, Can be rotated together with the second arm member 153 and rotated.

The fourth arm member 155 is rotatably installed on the fixed shaft portion 130 and has an end fixed to the spring unit 156 so that when the first arm member 152 rotates, .

A fourth arm member engaging hole 155a may be formed in the fourth arm member 155 so as to be rotatably mounted on the fixed shaft portion 130. [ That is, the fourth arm member 155 is installed on the fixed shaft portion 130 so that the fixed shaft portion 130 passes through the fourth arm member engaging hole 155a. Accordingly, the fourth arm member 155 can be rotated around the fixed shaft portion 130.

On the other hand, a fourth arm member stopper 155b may be formed at the center of the fourth arm member 155 to protrude upward. That is, the fourth arm member 155 may be protruded such that a fourth arm member stopper 155b for preventing the first arm member 155 from rotating in one direction during power transmission is disposed on the fourth arm member engaging hole 155a . Further, the fourth arm member stopper 155b can form a semi-circular groove.

Further, the fourth arm member 155 may be formed with a fourth arm member round portion 155c formed to extend in a direction opposite to the side where the fourth arm member stopper 155b is formed and rounded.

The inner circumferential surface of the fourth arm member round part 155c serves to rotate the second rotating part 180, and a detailed description thereof will be described later.

A spring unit connecting portion 155d extending in the same direction as the extending direction of the fourth arm member round 155c is formed on the opposite side of the fourth arm member 155 on which the fourth arm member round portion 155c is formed, Can be formed.

That is, the fourth arm member 155 is connected to the portion supporting one side of the coil spring 160 together with the first arm member 152, so that when the first arm member 152 rotates, And can be rotated in conjunction with the first arm member 152.

In this way, the coil spring 160 provided in the spring unit 156 can be compressed by rotating the first and fourth arm members 152 and 155.

The fourth arm member 155 may be coupled to the fixed shaft portion 130 so as to be disposed closer to the rear plate 120 side than the third arm member 154.

The spring unit 156 may be connected to the arm unit 151 and may include a coil spring 160 that is expanded and contracted by the rotation of the arm unit 151.

The spring unit 156 may include an upper support member 157, a lower support member 158, a guide member 159, and a coil spring 160.

The upper support member 157 is connected to the ends of the second and third arm members 153 and 154 to compress the coil spring 160 when the second and third arm members 153 and 154 rotate. The upper support member 157 has a circular annular shape and includes an upper support table 157a for supporting one end of the coil spring 160 and an upper support shaft 157b for passing through the upper support table 157a can do.

The second arm member 153 is connected to one side of the upper support shaft 157b and the third arm member 154 is connected to the other side of the upper support shaft 157b to rotate the upper support member 157 And the coil spring 160 is compressed.

The lower support member 158 is connected to the ends of the first and fourth arm members 152 and 155 to compress the coil spring 160 when the first and fourth arm members 152 and 155 rotate. To this end, the lower support member 158 also has a circular annular shape and includes a lower support shaft 158a for supporting the other end of the coil spring 160 and a lower support shaft 158b for penetrating the lower support shaft 158a can do.

The first arm member 151 is connected to one side of the lower support shaft 158b and the fourth arm member 155 is connected to the other side of the lower support shaft 158b to rotate the lower support member 158 And the coil spring 160 is compressed.

The guide member 159 connects the upper support member 157 and the lower support member 158. [ In more detail, the guide member 159 is installed on the upper support shaft 157b and the lower support shaft 158b. The guide member 159 is provided with upper and lower guide holes 159a and 159b for moving the upper and lower support shafts 157b and 158b when the upper and lower support members 157 and 158 compress the coil spring 160, Can be formed.

That is, when the coil spring 160 is compressed by the upper support member 157, the upper support shaft 157b is moved through the upper guide hole 159a and the coil spring 160 is moved by the lower support member 158, The lower support shaft 158b can be moved through the lower guide hole 159b.

One end of the coil spring 160 is supported by the upper support member 157 and the other end is supported by the lower support member 158. Accordingly, when the upper support member 157 is rotated by the second and third arm members 153 and 154, the upper support member 157 is compressed by the first and fourth arm members 152 and 155, 158 are rotated by the lower support member 158 when they are rotated.

Here, the operation of the first rotating part 150 will be briefly described.

The first rotary part 150 rotates the rotary shaft 195 so that the three-phase switch (not shown) is changed to the disconnected state, the grounded state, and the energized state.

Meanwhile, as described above, the first power transmission unit 140 serves to transmit power when rotating the rotary shaft 195 such that the three-phase switch is changed from the disconnected state to the grounded state or from the grounded state to the disconnected state .

Hereinafter, a case where the first rotating part 150 is operated through the first power transmitting part 140 will be described first.

The first power transmitting member 142 is rotated in one direction by the operator. Accordingly, the power transmission bar 144 provided on the first power transmitting member 142 is rotated in one direction about the fixed shaft portion 130.

The first arm member 152 of the arm unit 151 is rotated in one direction by the rotation of the power transmission bar 144. [ At this time, the second arm member 153 remains fixed to the fixed shaft portion 130 without being rotated.

When the first arm member 152 is rotated in one direction, the lower support shaft 158b of the spring unit 156 is rotated together with the first arm member 152. At the same time, the lower support shaft 158b is installed The lower support member 158 is rotated together with the first arm member 152. At this time, the lower support shaft 158b is moved along the lower guide hole 159b formed in the guide member 159 of the spring unit 156. [

The fourth arm member 155 fixed to the other side of the lower support shaft 158 is also rotated together with the lower support shaft 158b.

At this time, the second arm member 153 and the third arm member 154 of the arm unit 151 can be kept fixed without being rotated.

Thus, only the lower support rod 158 supporting the coil spring 160 rotates and the upper support rod 157 maintains the original position, so that the coil spring 160 can be compressed.

When the power transmitting member 142 is rotated in the other direction by the operator, the power transmission bar 144 provided on the first power transmitting member 142 is rotated in the other direction around the fixed shaft 130.

The second arm member 153 of the arm unit 151 is rotated in the other direction by the rotation of the power transmission bar 144. [ At this time, the first arm member 152 of the arm unit 151 is kept fixed to the fixed shaft portion 130 without being rotated.

When the second arm member 153 is rotated in the other direction, the upper support shaft 157b of the spring unit 156 is rotated together with the second arm member 153, and at the same time, 2 arm member 153 as shown in Fig. At this time, the upper support shaft 157b is moved along the upper guide hole 159a formed in the guide member 159 of the spring unit 156.

The third arm member 154 fixed to the other side of the upper support shaft 157b is also rotated together with the upper support shaft 157b.

At this time, the first arm member 152 and the fourth arm member 155 of the arm unit 156 can be kept fixed without being rotated.

Thus, only the upper support table 158 supporting the coil spring 160 is rotated and the lower support table 162 is held in the original position, so that the coil spring 150 can be compressed.

Meanwhile, as described above, the second and third arm members 153 and 154 are connected to the second power transmission unit 170. Accordingly, the second and third arm portions (153, 154) can be rotated by the second power transmission portion (170).

The first and fourth arm members 152 and 155 are not connected to the second power transmitting unit 170 and the first and fourth arm members 152 and 155 can be rotated only by the first power transmitting unit 140.

The rotation of the second and third arm members 153 and 154 by the second power transmission unit 170 is the same as the operation by the first power transmission unit 140 described above.

That is, when the second and third arm members 153 and 154 are rotated in the other direction by the second power transmission unit 170, the upper arm 157 is rotated together with the second arm member 153 at the same time. At this time, the upper support shaft 157b is moved along the upper guide hole 159a formed in the guide member 159 of the spring unit 156.

The third arm member 154 fixed to the other side of the upper support shaft 157b is also rotated together with the upper support shaft 157b.

At this time, the first arm member 152 and the fourth arm member 155 of the arm unit 156 can be kept fixed without being rotated.

Thus, only the upper support table 158 supporting the coil spring 160 is rotated and the lower support table 162 is held in the original position, so that the coil spring 150 can be compressed.

Details of the rotation operation by the second power transmitting portion 170 will be described later.

FIG. 7 is an explanatory view for explaining a second power transmission unit included in a fuse-connected three-phase switch driving apparatus according to an embodiment of the present invention. FIG. 8 is a cross- 7 is an explanatory view of the second power transmitting portion provided in the switch driving device viewed from an angle different from that of Fig. 7. Fig.

The second power transmission unit 170 is connected to the first rotation unit 150 to rotate the first rotation unit 150 by an external force.

7 and 8, the second power transmitting portion 170 includes a power transmitting shaft 171, a second power transmitting member 172, a first rotating member 173, A second power transmission link member 175, a link shaft 176, an engaging member 177, and a second power transmission spring unit 178. The first power transmission link member 175,

The power transmission shaft 171 may be rotatably installed on the front and rear plates 110 and 120. The power transmitting shaft 171 may be installed on the front and rear plates 110 and 120 so as to be spaced apart from the first rotating part 150.

Further, the power transmitting shaft 171 can be rotated by the operator, the driving unit 220, and the fuse 30, and a detailed description thereof will be described later.

The second power transmitting member 172 is rotated by an external force and rotated in conjunction with the power transmitting shaft 171. Meanwhile, the second power transmitting member 172 may be composed of a disc portion 172a and a cam portion 172b.

Meanwhile, the disc portion 172a may be provided with a drive bar installation hole 172c which is exposed through the hole 116 in the second rotation state of the front plate 110. [ On the other hand, when the disk portion 172a of the second power transmitting member 172 rotates, the drive bar installation hole 172c is disposed in the second rotation state, the hole 116, or the second rotation state, .

That is, the drive bar installation hole 172c is disposed in the hole 116 in the second rotation state only when the three-phase switch (not shown) is in the disconnected state or the energized state by the rotation shaft 195, When the switch is in the grounded state, the drive bar installation hole 172c is disposed apart from the hole 116 in the second rotation state.

As a result, the rotation of the second power transmitting member 172 by the operator may be possible only when the three-phase switch is in the disconnected state or the energized state.

The cam portion 172b may be installed on the disk portion 172a and rotated in conjunction with the disk portion 172a. Meanwhile, the cam portion 172b serves to rotate the second power transmitting member 172 by the driving portion 220. [ In other words, the cam portion 172b is rotated by the driving portion 220 so that the second power transmitting member 172 can be rotated.

The first rotary member 173 is fixed to the power transmitting shaft 171 and rotated together with the power transmitting shaft 171. The first rotating member 173 may be connected to the power transmitting member 172 and the second rotating member 174 and rotated in conjunction with the power transmitting members 172 and 174. [

Furthermore, the first power transmission link member 175 may be connected to the first rotary member 173 via a connection shaft 175a.

That is, when the first rotary member 173 is rotated together with the power transmission shaft 171, the second power transmission link member 175 is moved together with the first rotary member 173.

The second rotary member 174 is spaced apart from the first rotary member 173 by a predetermined distance and is rotatably installed on the second power transmitting portion fixing shaft 174a.

Meanwhile, the second rotary member 174 may be connected to the first rotary member 173 and rotated in conjunction with the first rotary member 173. Furthermore, the second power transmitting link member 175 may be connected to the second rotating member 174 via a connecting shaft 175a. That is, when the second rotating member 174 is rotated about the second power transmitting portion fixing shaft 174a, the second power transmitting portion link member 175 is moved together with the second rotating member 174. [

The second rotary member 174 may be provided with a locking portion 174b for restricting the rotation of the second rotary member 174 by being supported by the stopper unit 210. [

The engaging portion 174b extends radially from one side of the second rotary member 174, that is, from the second power transmitting portion fixed shaft 174a.

That is, the second rotating member 174 may have a substantially V shape.

One side of the latching portion 174b may be rounded and the other side thereof may be formed to have an edge so as not to be detached from the stopper unit 210 when the stopper unit 210 is supported by the stopper unit 210. [

Furthermore, an extension 174c may be provided at the end of the latching portion 174b so as to be more easily supported by the stopper unit 210. [ In other words, the thickness of the end of the locking part 174 may be made thicker, and the extension part 174c may be formed by attaching a separate member and may be formed thicker than the remaining part of the locking part 174b .

When the end of the engagement portion 174b and the extended portion 174c are supported by the stopper unit 210 and the three-phase switch is in the energized state by the second power transmitting member 172, 172 can be maintained at a constant position without being rotated.

The second power transmission link member 175 is connected to the first and second rotary members 173 and 174 via a connection shaft 175a. That is, a connecting shaft 175a is coupled to one end of the second power transmission link member 175, and first and second rotating members 173 and 174 are provided on the connecting shaft 175a.

Accordingly, when the first and second rotary members 173 and 174 rotate, the second power transmission link member 175 can be moved in conjunction with rotation of the first and second rotary members 173 and 174.

A link shaft 176 may be connected to the other side of the second power transmission link member 175. The link shaft 176 can be rotated about the fixed shaft 130 when the second power transmission link member 175 and the first and second rotating members 173 and 174 are moved.

The link shaft 176 is fixed to the other side of the second power transmission link member 175 to rotate the first rotation unit 140. One end of the link shaft 176 is connected to the second arm member 153 of the arm unit 151 and the other end is connected to the third arm member 154.

Thus, the link shaft 176 can be rotated around the fixed shaft portion 130. [ That is, when the second power transmission link member 175 is moved, the second and third arm members 153 and 154 can be rotated about the fixed shaft portion 130 by the link shaft 176.

The engaging member 177 is provided with a ring portion 177a which is in contact with the link shaft 176 and is rotatably installed on the fixed shaft portion 130. [ The link part 177a may be formed as a pair and a link shaft coupling groove 177b into which the link shaft 176 is inserted may be formed in the link part 177a.

Furthermore, a connection hole 177c for connection with the locking member wire 179 may be formed at the end of the ring portion 177a. That is, a connection hole 177c for coupling with the coupling member wire connection member 179a through a connection shaft (not shown) may be formed at the end of the loop 177a.

The second power transmitting portion spring unit 178 is connected to the engaging member 177 through the engaging member wire 179 and provides driving force for rotating the first rotating portion 150 when the fuse is operated.

The second power transmitting portion spring unit 178 for this purpose may include a mounting plate 178a, a pulley 178b, a housing 178c, a spring 178d, and a supporting member 178e.

The mounting plate 178a may be fixed to the front and rear plates 110 and 120. [ The mounting plate 178 may be installed on the front and rear plates 110 and 120 so as to be adjacent to the first and second rotary units 150 and 180.

On the other hand, the mounting plate 178a may be provided with a drum 178b on one side and a housing 178c on the other side. The engaging member wire 179 is arranged to penetrate the mounting plate 178a.

The pulley 178b is rotatably installed on one side of the mounting plate 178a to guide the locking member wire 179 as described above. As described above, the engaging member wire 179 is moved along the outer peripheral surface of the pulley 178b, and the engaging member wire 179 can be stably moved when the engaging member 177 is moved.

Meanwhile, the housing 178c is fixed to the other surface of the mounting plate 178a and has an internal space. As an example, the housing 178c may have a cylindrical shape, with one side closed by the mounting plate 178a and the other side closed by the support member 178e.

The spring 178d is inserted into the housing 178c and one end thereof is supported by the mounting plate 178a and the other end thereof is supported by the supporting member 178e.

The supporting member 178e is movably installed at the end of the housing 178c and moves along the inner circumferential surface of the housing 178c to compress the spring 178d when the engaging member wire 179 moves .

The retaining member 177 is moved by the rotation of the retaining member 177 so that the retaining member 178e to which the retaining member wire 179 is connected is housed in the housing 178c, And the spring 178d is in a compressed state.

Thereafter, when the second power transmitting portion 170 is in a rotatable state, the engaging member 177 is returned to its original position by the restoring force of the spring 178d, and the first rotating portion 140 is rotated.

FIG. 9 is an explanatory view for explaining a second rotary part of a fuse-connected three-phase switch driving device according to an embodiment of the present invention, FIG. 10 is a cross- Fig. 3 is an exploded perspective view for explaining a second rotating part provided in the driving device;

The second rotation part 180 can be rotated by the restoring force of the coil spring 160. 9 and 10, the second rotating portion 180 may include a plate unit 181, a first stopper member 182, and a second stopper member 183 .

The plate unit 181 is fixed to the rotating shaft 195. That is, by the rotation of the plate unit 181, the rotating shaft 195 can rotate in conjunction with the plate unit 181.

The plate unit 181 includes a first plate 184, a second plate 185, a circular plate 186, a third stopper member 187, a fourth stopper member 188, a first connecting member 189 A second linking member 190, a support shaft 191, and a leaf spring 192. The second link member 190 may be a plate spring.

The first plate 184 may be fixed to the rotating shaft 195. For this purpose, the first plate 184 may be formed with a rotation shaft coupling hole 184a through which the rotation shaft 195 passes.

A third stopper member through hole 184b and a fourth stopper member engaging hole 184c formed to extend in the circumferential direction around the rotating shaft coupling hole 184a may be formed in the first plate 178 .

A first connection member through hole 184d may be formed in the first plate 184 so as to be disposed on the upper portion of the third stopper member through hole 184b and may be formed in the lower portion of the fourth stopper member through hole 184c. The second connection member through hole 184e may be formed to be disposed in the second connection member through hole 184e.

The first plate 184 may be provided with a support shaft mounting hole 184f on which a support shaft 191 for fixing the second plate 185 is installed.

The second plate 185 may be fixed to the rotating shaft 195 so as to be spaced apart from the first plate 148 by a predetermined distance.

Also, the second plate 185 may be formed with a rotation shaft coupling hole 185a through which the rotation shaft 195 passes.

A third stopper member mounting hole 185b and a fourth stopper member mounting hole 185c may be formed on the second plate 185 such that the extending line is formed around the rotational axis coupling hole 185a as a circle, .

The second plate 185 may be provided with a first connection member installation hole 185d so as to be disposed on the upper portion of the third stopper member installation hole 185b. The second connection member installation hole 185e may be formed to be disposed in the second connection member mounting hole 185e.

The second plate 185 may be connected to the first plate 184 through the support shaft 191.

The circular plate 186 is installed on the rotary shaft 195 so as to be disposed in the space between the first and second plates 184 and 185.

Meanwhile, the circular plate 186 serves to fix the third and fourth stopper members 187 and 188, and rotates in conjunction with the rotary shaft 195.

The circular plate 186 may be connected to the first and second plates 184 and 185 by an engaging member (not shown) and rotated in conjunction with the first and second plates 184 and 185.

The third stopper member 187 protrudes through the first plate 184 and protrudes into the space between the front and rear plates 110 and 120 and guides the rotation direction of the first rotation unit 150.

That is, the third stopper member 187 supports the third arm member stopper 154b of the first rotation part 150 to prevent the third arm member 154 from being rotated when power is transmitted from the fourth arm member 155 To prevent rotation in the direction of rotation.

Further, when the entire first rotating part 150 is rotated in the other direction, the third stopper member 187 pushes the third arm member stopper 154b so that the entire first rotating part 150 rotates in the other direction.

A detailed description thereof will be described later.

The fourth stopper member 188 also protrudes through the first plate 184 in the space between the front and rear plates 110 and 120 and guides the rotation direction of the first rotation unit 150.

That is, the fourth stopper member 188 supports the fourth arm member stopper 155b of the first rotating unit 150 to transmit the fourth arm member 155 in one direction during power transmission of the third arm member 154, Thereby preventing rotation of the motor.

Further, when the entire first rotating part 150 is rotated in one direction, the fourth stopper member 188 pushes the fourth arm member stopper 155b so that the entire first rotating part 150 is rotated in one direction.

A detailed description thereof will be described later.

The first linking member 189 has a length longer than that of the third and fourth stopper members 187 and 188 and may be connected to the interlocking rotary plate 146 provided on the first power transmitting unit 140. One end of the first linking member 189 is fixed to the first and second plates 184 and 185 and the other end of the first linking member 189 is connected to the linking rotary plate 146 of the first power transmission unit 140, And rotates in conjunction with the first power transmission unit 140 when the first power transmission unit 140 rotates.

The second connecting member 190 has a length corresponding to the first connecting member 189 and may be connected to the interlocking rotary plate 146 provided on the first power transmitting unit 140. One end of the second linking member 190 is fixed to the first and second plates 184 and 185 and the other end of the second linking member 190 is connected to the interlocking rotary plate 146 of the first power transmission unit 140, And rotates in conjunction with the first power transmission unit 140.

The support shaft 191 connects the first and second plates 184 and 185 and supports the plate spring 192 as described above. That is, the plate spring 192 is disposed so as to surround the support shaft 191 and presses the plate spring 192 about the support shaft 191.

On the other hand, the plate spring 192 is assembled to the support shaft 191, and both end portions thereof can be brought into contact with the first and second stopper members 182 and 183. That is, the plate spring 192 serves to provide a restoring force by which the first and second stopper members 182 and 183 can be returned to the original position after the first and second stopper members 182 and 183 are rotated.

The first stopper member 182 is disposed inside the plate unit 181 and can be pivoted about the first pivot shaft 182a. The first stopper member 182 includes a first pivot portion 182b that is rotatably installed on the first pivot shaft 182a and a second pivot portion 182b that is extended from the first pivot portion 182b and is rotated by the first rotation portion 150 And a first extension bar 182c for pivoting the first pivot portion 182b.

In more detail, the first extension bar 182c is supported by the third arm member round portion 154c of the third arm member 154. [ When the third arm member 154 is rotated in one direction, the first extension bar 182c is moved along the third arm member round portion 154c, whereby the first pivot portion 182b is moved in the first direction And is rotated about the pivot shaft 182a.

Thereafter, when the first pivot portion 182b is rotated by a predetermined angle or more, the first pivot portion 182b releases the restraint from any one of the stoppers constituting the stopper portion 200. [

Accordingly, the entire second rotary part 180 is rotated in one direction together with the rotary shaft 195 by the restoring force of the coil spring 160. [

Thereafter, when the first pivot portion 182b is rotated by a predetermined angle or more, the first pivot portion 182b is rotated by the leaf spring 192 to be restored to its original position. Accordingly, the first pivot portion 182b is restrained by the other stopper constituting the stopper portion 200, and the second rotation portion 180 can no longer be rotated.

The second stopper member 183 is also disposed inside the plate unit 181 and can be rotated around the second rotation shaft 183a. The second stopper member 183 includes a second pivot portion 183b rotatably installed on the second pivot shaft 183a and a second pivot portion 183b extended from the second pivot portion 183b by the first rotation portion 150 And a second extension bar 183c for rotating the first pivot portion 183b.

More specifically, the second extension bar 183c is supported by the fourth arm member round portion 155c of the fourth arm member 155. [ When the fourth arm member 155 is rotated in the other direction, the second extension bar 183c is moved along the fourth arm member round portion 155c, whereby the second pivot portion 183b is moved to the second And is rotated about the pivot shaft 183a.

Thereafter, when the second pivot portion 183b is rotated by a predetermined angle or more, the second pivot portion 183b is released from any one of the stoppers constituting the stopper portion 200. [

Accordingly, the entire second rotating portion 180 is rotated in the other direction together with the rotating shaft 195 by the restoring force of the coil spring 160. [

Thereafter, when the second pivot portion 183b is rotated by a predetermined angle or more, the second pivot portion 183b is rotated by the leaf spring 192 so as to be restored to its original position. Accordingly, the second pivot portion 183b is restrained by the other stoppers constituting the stopper portion 200, so that the second rotation portion 180 can no longer be rotated.

The rotating shaft 195 is assembled with the second rotating portion 180 and rotated in conjunction with the second rotating portion 180. One end of the rotary shaft 195 is connected to a three-phase switch (not shown) so that the three-phase switch can realize a ground, energized, or disconnected state.

That is, the rotary shaft 195 is rotated at a predetermined angle together with the second rotary part 180 to perform the three-phase switch to realize the ground, energized, and disconnected states.

The stopper unit 200 is installed on the rear plate 120 and adjusts the rotation of the second rotation unit 180. Meanwhile, the stopper unit 200 may include first and second stoppers 202 and 204.

That is, the stopper portion 200 may include a first stopper portion 212 for supporting the first stopper member 182 and a second stopper portion 204 for supporting the second stopper member 183 have.

The first stopper portion 202 may be formed of three stoppers, and the second stopper portion 204 may be formed of two stoppers.

Instead, the fuse-connected three-phase switch driving apparatus 100 according to the embodiment of the present invention includes the stopper unit 210 for regulating the case where the three-phase switch is changed from the energized state to the disconnection state.

The stopper unit 210 is installed on the front and rear plates 110 and 120 so as to be adjacent to the second power transmission unit 170 and serves to rotate the second power transmission unit 170 when the fuse 30 is operated .

To this end, the stopper unit 210 may include a stopper shaft 211, a handle 212, a spring member 213, a mounting pin 214, and a wire fitting member 215.

The stopper shaft 211 is rotatably installed on the front and rear plates 110 and 120 and a passage groove 211a for rotating the second power transmitting portion 170 may be formed. The second rotary member 174 of the second power transmitting portion 170 is passed through the passage groove 211a so that the second rotary member 174 can be supported on the stopper shaft 211. [

More specifically, when the second rotary member 174 of the second power transmitting portion 170 is rotated by an external force, the end of the fastening portion 174b of the second rotary member 174 and the extended portion 174c of the second rotary member 174, Passes through the passage groove 211a of the stopper shaft 211. [ At this time, the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c rotate the stopper shaft 211 by a predetermined angle.

Thereafter, when the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c pass through the passage groove 211a, the stopper shaft 211 is locked by the spring member 213 to the end of the locking portion 174b And the extension portion 174c.

Thus, the end of the locking portion 174b and the extending portion 174c are supported on the outer peripheral surface of the stopper shaft 211. [

When the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are rotated to be supported by the stopper shaft 211, the second power transmitting portion spring unit 178, The spring 178d of the spring 178 is in a compressed state.

When the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are rotatable, by the restoring force of the spring 178d of the second power transmitting portion spring unit 178, The member 174 is rotated.

The handle portion 212 is connected to one side of the stopper shaft 211 so as to be projected from the front plate 110. That is, the handle portion 212 is protruded from the front plate 110 so that the operator can rotate the handle portion 212.

As described above, when the worker pushes the stopper shaft 211 through the handle 212 in a state where the end of the stopper portion 174b and the extended portion 174c are supported on the outer peripheral surface of the stopper shaft 211, The through groove 211a of the stopper shaft 211 is rotated so as to face the end of the engaging portion 174b and the extended portion 174c side and thereby the end of the engaging portion 174b of the second rotating member 174 And the extension portion 174c are released.

The end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are caused to pass through the passage groove 211a by the restoring force of the spring 178d of the second power transmitting portion spring unit 178 .

Thus, the handle 212 functions to allow the second rotary member 174 to be manually rotated by the operator.

The spring member 213 is inserted into the other end of the stopper shaft 211 and one end is supported by a support pin 129 provided on the rear plate 120. That is, the spring member 213 serves to provide a restoring force by which the stopper shaft 211 can be restored to its original position.

In other words, when the stopper shaft 211 is rotated by the second rotary member 174 of the second power transmission portion 170 or after the stopper shaft 211 is rotated manually by the handle portion 212 The spring member 213 serves to return the stopper shaft 211 to its original position.

The mounting pin 214 is fixed to the stopper shaft 211 and serves to provide the other end of the spring member 213. That is, the spring member 213 is supported on the mounting pin 214 so that the spring member 213 can be compressed and expanded.

The wire mounting member 215 is fixed to the stopper shaft 211 so as to be adjacent to the front plate 110 and has a fuse connecting wire 370 for connection with the fuse 30. [ That is, the wire installation member 215 rotates the stopper shaft 211 when the fuse connection wire 370 is pulled. For this purpose, the wire installation member 215 is fixed to the stopper shaft 211 will be.

That is, when the fuse connecting wire 370 is pulled by the operation of the fuse 30, the stopper shaft 211 is fixed to the outer surface of the stopper shaft 211 by the wire fitting member 215, And rotates the stopper shaft 211 in a state in which the portion 174c is supported. As a result, the passage groove 211a of the stopper shaft 211 is rotated so as to face the end of the engaging portion 174b and the extending portion 174c side, so that the end of the engaging portion 174b of the second rotating member 174 And the extension portion 174c are released.

The end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are moved by the restoring force of the spring 178d of the second power transmitting portion spring unit 178, And is then rotated so as to pass through the opening 211a.

The driving unit 220 is fixed to at least one of the front and rear plates 110 and 120 and rotates the second power transmission unit 170. That is, the driving unit 220 rotates the second power transmission unit 170 by the power source.

To this end, the driving unit 220 includes a first driving unit mounting plate 221, a second driving unit mounting plate 222, a driving motor 223, a plurality of gear members 224, A transmission gear 225, and a cam member 226. [

The first driving part mounting plate 221 is fixed to the rear plate 120, and may have, for example, a shooting plate shape.

The second driving part mounting plate 222 may be connected to the first driving part mounting plate 221 so as to be spaced apart from the first driving part mounting plate 221 through the spacing member 221a. The second driving part mounting plate 222 may have a shape corresponding to the first driving part mounting plate 221.

The driving motor 223 is installed to penetrate the second driving part mounting plate 222. That is, the driving motor 223 may be installed on the second driving part mounting plate 222 such that the driving shaft (not shown) of the driving motor 223 passes through the second driving part mounting plate 222.

The plurality of gear members 224 are rotatably installed on the first and second driving part mounting plates 221 and 222 so as to be disposed in the spaces between the first and second driving part mounting plates 221 and 222. The plurality of gear members 224 transmit the driving force transmitted from the driving motor 223 to the power transmission gear 225.

The power transmission gear 225 is connected to at least one of the plurality of gear members 224 and fixed to the gear member rotation shaft 227. That is, the driving force transmitted from the plurality of gear members 224 is received by the power transmission gear 225 and rotates the gear member rotation shaft 227.

The cam member 226 is fixed to the gear member rotational shaft 227 and rotates in conjunction with the gear member rotational shaft 227.

That is, when the cam member 226 is rotated together with the gear member rotational shaft 227, the end of the cam member 226 rotates the second power transmitting portion 170.

More specifically, the end of the cam member 226 contacts the cam portion 172b of the second power transmitting member 172 to rotate the cam portion 172b when the end of the cam member 226 rotates. Accordingly, the second power transmitting member 172 is rotated in the direction opposite to the rotating direction of the cam member 226, and the second power transmitting portion 170 is rotated.

Accordingly, the second power transmitting portion 170 rotates the first rotating portion 150 so that the rotary shaft 195 ultimately changes the three-phase switch (not shown) from the disconnected state to the energized state.

In other words, the three-phase switch can be changed from the disconnected state to the energized state by the driving unit 220. [

In this manner, the second power transmission unit 170 can change the three-phase switch from the disconnected state to the energized state by rotating the first rotating unit 150 by an external power source or by an operator.

Also, the change from the energized state to the disconnected state of the three-phase switch can be made by the operator through the handle 212 or the operation of the fuse 30 as described above.

The solenoid 230 is fixed to a mounting plate 232 installed on the rear plate 120 so as to be adjacent to the stopper unit 210 as shown in more detail in FIGS. 11 to 12, and the push pin 234, Can be projected to the outside.

Meanwhile, the interlocking plate 240 may be fixed to the stopper shaft 211 so that the interlocking plate 240 contacts the push pin 234 when the push pin 234 is operated.

That is, when power is supplied to the solenoid 230, the push pin 234 is moved so that the push pin 2340 pushes the interlocking plate 240. In this case, the interlocking plate 240 moves the stopper shaft 211 at a predetermined angle .

In other words, the stopper shaft 211 rotates the stopper shaft 211 in a state where the end of the engaging portion 174b and the extending portion 174c are supported by the outer peripheral surface of the stopper shaft 211 by the interlocking plate 240. [ As a result, the passage groove 211a of the stopper shaft 211 is rotated so as to face the end of the engaging portion 174b and the extending portion 174c side, so that the end of the engaging portion 174b of the second rotating member 174 And the extension portion 174c are released.

As described above, the stopper shaft 211 is also rotated through the solenoid 230 so that the rotary shaft 195 can ultimately change the three-phase switch (not shown) from the energized state to the disconnected state.

Hereinafter, the operation of the fuse-connected three-phase switch driving apparatus according to the embodiment of the present invention will be described with reference to the drawings.

Meanwhile, in the fuse-connected three-phase switch driving apparatus 100 shown in the figure, the rotary shaft 195 shows a state in which the three-phase switch (not shown) is in the disconnected state.

First, a case where the three-phase switch is driven by the operator from the disconnected state to the energized state will be described.

The operator connects the drive bar (not shown) to the second power transmitting member 172 of the second power transmitting portion 170 to rotate the second power transmitting member 172.

The first and second rotary members 173 and 174 of the second power transmitting portion 170 are rotated in conjunction with the second power transmitting member 172 and the first and second rotary members 173 and 174 are rotated 2 power transmission link member 175 is moved.

The second power transmission link member 175 rotates the link shaft 176 about the fixed shaft portion 130 so that the engaging member 177 is rotated about the fixed shaft portion 130.

At this time, the spring 178d of the second power transmission spring unit 178 is compressed by the support member 178e. That is, the retaining member wire 179 connected to the retaining member 177 is rotated together with the retaining member 177 to move the retaining member 178e into the interior of the housing 178c.

Thus, the spring 178d, which is supported at one end by the support member 178e, is compressed.

The second and third arm members 153 and 154 of the first rotating portion 150 are rotated about the fixed shaft portion 130 together with the link shaft 176 by the rotation of the link shaft 176. [ At this time, the first and fourth arm members 152 and 155 of the first rotation part 150 are not rotated and maintain their original positions.

As a result, the coil spring 160 of the spring unit 156 is compressed by the second and third arm members 153, 154.

The first extending bar 182c of the first stopper member 182 before the rotation of the third arm member 154 is supported at the end of the third arm member round portion 153c of the third arm member 153 do.

The first extension bar 182c is moved along the third arm member round portion 153c of the third arm member 154 by the rotation of the third arm member 154. [ Thus, the first pivot portion 182b of the first stopper member 182 is rotated about the first pivot shaft 182a.

Thereafter, when the first pivot portion 182b is rotated over a predetermined angle, the first pivot portion 182b is released from the first stopper portion 202. That is, the first pivot portion 182b of the first stopper member 182 restricting the rotation of the second rotation portion 180 is released from the first stopper portion 202.

At the same time, the third arm member 154 is rotated by the restoring force of the coil spring 160 while restraining the lower support member 158 supporting the compressed coil spring 160.

The third stopper member 187 for supporting the third arm member stopper 154b of the third arm member 154 is pushed and rotated by the third arm member stopper 154b.

The rotation of the third stopper member 187 rotates the entire plate unit 181 while rotating the first plate 184 to which the third stopper member 187 is fixed.

Accordingly, the rotary shaft 195, to which the second rotary part 180 is fixed, is rotated in conjunction with the plate unit 181, and the three-phase switch is changed from the disconnected state to the energized state.

The second rotating member 174 of the second power transmitting portion 170 is rotated so that the end of the holding portion 174b of the second rotating member 174 and the extended portion 174c are engaged with the stopper shaft 211 And is supported on the outer peripheral surface of the stopper shaft 211 after passing through the passage groove 211a.

Here, a case where the rotating shaft 195 is rotated by the driving unit 220 will be described. First, when power is supplied to the drive motor 223,

Power is transmitted to the plurality of gear members 224 by the drive motor 223, and then the power transmission gear 225 is rotated. The rotation of the power transmission gear 225 causes the gear member rotational shaft 227 to be fixed together with the power transmission gear 225 to rotate together with the power transmission gear 225.

The cam member 226 is rotated together with the gear member rotational shaft 227 by the rotation of the gear member rotational shaft 227.

Thereafter, the cam member 226 rotates the second power transmitting portion 170. More specifically, the end of the cam member 226 contacts the cam portion 172b of the second power transmitting member 172 to rotate the cam portion 172b when the end of the cam member 226 rotates. As a result, the second power transmitting member 172 is rotated in the direction opposite to the rotating direction of the cam member 226, so that the second power transmitting portion 170 is rotated.

The first and second rotary members 173 and 174 of the second power transmitting portion 170 are rotated in conjunction with the second power transmitting member 172 and the first and second rotary members 173 and 174 are rotated 2 power transmission link member 175 is moved.

The second power transmission link member 175 rotates the link shaft 176 about the fixed shaft portion 130 so that the engaging member 177 is rotated about the fixed shaft portion 130.

At this time, the spring 178d of the second power transmission spring unit 178 is compressed by the support member 178e. That is, the retaining member wire 179 connected to the retaining member 177 is rotated together with the retaining member 177 to move the retaining member 178e into the interior of the housing 178c.

Thus, the spring 178d, which is supported at one end by the support member 178e, is compressed.

The second and third arm members 153 and 154 of the first rotating portion 150 are rotated about the fixed shaft portion 130 together with the link shaft 176 by the rotation of the link shaft 176. [ At this time, the first and fourth arm members 152 and 155 of the first rotation part 150 are not rotated and maintain their original positions.

As a result, the coil spring 160 of the spring unit 156 is compressed by the second and third arm members 153, 154.

The first extending bar 182c of the first stopper member 182 before the rotation of the third arm member 154 is supported at the end of the third arm member round portion 153c of the third arm member 153 do.

The first extension bar 182c is moved along the third arm member round portion 153c of the third arm member 154 by the rotation of the third arm member 154. [ Thus, the first pivot portion 182b of the first stopper member 182 is rotated about the first pivot shaft 182a.

Thereafter, when the first pivot portion 182b is rotated over a predetermined angle, the first pivot portion 182b is released from the first stopper portion 202. That is, the first pivot portion 182b of the first stopper member 182 restricting the rotation of the second rotation portion 180 is released from the first stopper portion 202.

At the same time, the third arm member 154 is rotated by the restoring force of the coil spring 160 while restraining the lower support member 158 supporting the compressed coil spring 160.

The third stopper member 187 for supporting the third arm member stopper 154b of the third arm member 154 is pushed and rotated by the third arm member stopper 154b.

The rotation of the third stopper member 187 rotates the entire plate unit 181 while rotating the first plate 184 to which the third stopper member 187 is fixed.

Accordingly, the rotary shaft 195, to which the second rotary part 180 is fixed, is rotated in conjunction with the plate unit 181, and the three-phase switch is changed from the disconnected state to the energized state.

The second rotating member 174 of the second power transmitting portion 170 is rotated so that the end of the holding portion 174b of the second rotating member 174 and the extended portion 174c are engaged with the stopper shaft 211 And is supported on the outer peripheral surface of the stopper shaft 211 after passing through the passage groove 211a.

Here, a description will be given of an operation in which the rotary shaft 195 is changed from a conducting state to a disconnected state by a three-phase switch (not shown).

The operation in which the rotary shaft 195 changes the three-phase switch from the energized state to the disconnection state can be performed by the operation of the fuse 30, by the manual operation of the operator, or by the operation of the solenoid 230.

First, a case where the rotation shaft 195 changes the three-phase switch from the energized state to the disconnection state by the operation of the fuse 30 will be described.

When the fuse 30 is activated, the fuse connecting wire 370 is pulled. Accordingly, the stopper shaft 211 is rotated by a certain angle by the wire fitting member 215 on which the fuse connecting wire 370 is installed.

That is, the stopper shaft 211 is rotated in a state where the end of the locking part 174b and the extended part 174c are supported on the outer peripheral surface of the stopper shaft 211. Accordingly, the passage groove 211a of the stopper shaft 211 And is rotated toward the end of the locking portion 174b and the extended portion 174c side.

As a result, the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are released, and the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c Is passed through the passage groove 211a of the stopper shaft 211 by the restoring force of the spring 178d of the second power transmitting portion spring unit 178. [

Accordingly, the second power transmitting portion 170 is rotated, and the second power transmitting portion 170 is rotated by the second rotating portion 180 so that the rotating shaft 195 is finally rotated.

The above operation can also be performed manually by the operator. That is, when the operator rotates the handle 212 of the stopper unit 210, the stopper shaft 211 can be rotated by a predetermined angle.

The stopper shaft 211 is rotated while the end of the stopper portion 174b and the extended portion 174c are supported on the outer peripheral surface of the stopper shaft 211. Accordingly, And is rotated toward the end of the locking portion 174b and the extended portion 174c side.

As a result, the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c are released, and the end of the locking portion 174b of the second rotary member 174 and the extended portion 174c Is passed through the passage groove 211a of the stopper shaft 211 by the restoring force of the spring 178d of the second power transmitting portion spring unit 178. [

Accordingly, the second power transmitting portion 170 is rotated, and the second power transmitting portion 170 is rotated by the second rotating portion 180 so that the rotating shaft 195 is finally rotated.

Meanwhile, the above-described operation can be performed by the solenoid 230 as well. That is, when power is supplied to the solenoid 230, the push pin 234 is moved so that the push pin 234 pushes the interlocking plate 240 out. In this case, the interlocking plate 240 rotates the stopper shaft 211 by a predetermined angle.

In other words, the stopper shaft 211 rotates the stopper shaft 211 in a state where the end of the engaging portion 174b and the extending portion 174c are supported by the outer peripheral surface of the stopper shaft 211 by the interlocking plate 240. [ As a result, the passage groove 211a of the stopper shaft 211 is rotated so as to face the end of the engaging portion 174b and the extending portion 174c side, so that the end of the engaging portion 174b of the second rotating member 174 And the extension portion 174c are released.

Next, a case where the operator operates the three-phase switch from the disconnected state to the grounded state will be described.

The operator rotates the first power transmitting member 142 of the first power transmitting portion 140 through the drive bar. The power transmission bar 144 of the first power transmission unit 140 is rotated and the arm unit 151 of the first rotation unit 150 is operated by the rotation of the power transmission bar 144. [

In more detail, the first arm member 152 of the arm unit 151 is rotated by the power transmission bar 144. At this time, the second arm member 153 of the arm unit 151 does not rotate but remains fixed to the fixed shaft portion 130.

When the first arm member 152 is rotated, the lower support shaft 158b of the spring unit 156 rotates together with the first arm member 152, and at the same time, the lower support shaft 158b The support member 158a is rotated together with the first arm member 152. [

The fourth arm member 155 fixed to the other side of the lower support shaft 158a is also rotated together with the lower support shaft 158a.

At this time, the second and third arm members 153 and 154 of the arm unit 151 can be kept fixed without being rotated.

Thus, only the lower support member 158 that supports the coil spring 160 is rotated and the upper support member 157 maintains the original position, so that the coil spring 160 can be compressed.

On the other hand, the rotation of the first arm member 152 rotates the fourth arm member 155 in the same direction. At this time, the second stopper member 183 of the second rotation part 180 is rotated by the fourth arm member 155.

More specifically, the second extension bar 183c is supported by the fourth arm member round portion 155c of the fourth arm member 155. [ When the fourth arm member 155 is rotated, the second extension bar 183c is moved along the fourth arm member round portion 155c so that the second pivot portion 183b is moved along the second pivot axis 183a.

Thereafter, when the second pivot portion 183b is rotated by a predetermined angle or more, the second pivot portion 183b is released from any one of the stoppers of the second stopper portion 204 constituting the stopper portion 200. [

The fourth arm member 155 is rotated by the restoring force of the coil spring 160 while the upper support member 157 supporting the compressed coil spring 160 is released from restraint.

The fourth stopper member 188 for supporting the fourth arm member stopper 155b of the fourth arm member 155 is pushed by the fourth arm member stopper 155b and rotated.

The rotation of the fourth stopper member 188 rotates the first plate 184 to which the fourth stopper member 188 is fixed to rotate the entire plate unit 181.

Accordingly, the rotating shaft 195 fixed to the second rotating portion 180 is rotated together with the second rotating portion 180.

Thereafter, when the second pivot portion 183b is rotated by a predetermined angle or more, the second pivot portion 183b is rotated by the leaf spring 192 so as to be restored to its original position. Accordingly, the second pivot portion 183b is restrained by the other stoppers constituting the stopper portion 200, so that the second rotation portion 180 can no longer be rotated.

As described above, the rotary shaft 195 is rotated by the rotation of the second rotary part 180 so that the three-phase switch can be changed from the disconnected state to the grounded state.

When the operator changes the first power transmitting member 142 of the first power transmitting portion 140 from the disconnected state to the grounded state via the drive bar, In the direction opposite to the direction of rotation in which it is rotated for change. The power transmission bar 144 of the first power transmission unit 140 is rotated and the arm unit 151 of the first rotation unit 150 is operated by the rotation of the power transmission bar 144. [

That is, the second arm member 153 of the arm unit 151 is rotated by the power transmission bar 144. At this time, the first arm member 152 of the arm unit 151 is kept fixed to the fixed shaft portion 130 without being rotated.

When the second arm member 153 is rotated, the upper support shaft 157b of the spring unit 156 is rotated together with the second arm member 153. At the same time, the upper support member 157a is rotated by the second arm member 153, (153).

The third arm member 154 fixed to the other side of the upper support shaft 157b is also rotated together with the upper support shaft 157b.

At this time, the first and fourth arm members 152 and 155 of the arm unit 151 can be kept fixed without being rotated.

Thus, only the upper support member 157 supporting the coil spring 160 rotates and the lower support member 158 maintains the original position, so that the coil spring 160 can be compressed.

On the other hand, the first stopper member 182 of the second rotating portion 180 is rotated by the third arm member 154 by the rotation of the third arm member 154.

That is, the first extending bar 182c of the first stopper member 182 before the rotation of the third arm member 154 is positioned at the end of the third arm member round portion 153c of the third arm member 153 .

The first extension bar 182c is moved along the third arm member round portion 153c of the third arm member 154 by the rotation of the third arm member 154. [ Thus, the first pivot portion 182b of the first stopper member 182 is rotated about the first pivot shaft 182a.

Thereafter, when the first pivot portion 182b is rotated over a predetermined angle, the first pivot portion 182b is released from the first stopper portion 202. That is, the first pivot portion 182b of the first stopper member 182 restricting the rotation of the second rotation portion 180 is released from the first stopper portion 202.

At the same time, the third arm member 154 is rotated by the restoring force of the coil spring 160 while restraining the lower support member 158 supporting the compressed coil spring 160.

The third stopper member 187 for supporting the third arm member stopper 154b of the third arm member 154 is pushed and rotated by the third arm member stopper 154b.

The rotation of the third stopper member 187 rotates the entire plate unit 181 while rotating the first plate 184 to which the third stopper member 187 is fixed.

Accordingly, the rotary shaft 195, to which the second rotary part 180 is fixed, rotates in conjunction with the plate unit 181, and the three-phase switch is changed from the ground state to the disconnected state.

Hereinafter, the operation of interlocking with the fuse will be described with reference to the drawings. That is, the fuse holder will be described, and the interlocking operation of the three-phase switch driving device during the fusing of the fuse will be described.

FIG. 2 is a perspective view showing a fuse holder according to an embodiment of the present invention, and FIG. 3 is a partially exploded perspective view showing a fuse holder according to an embodiment of the present invention.

2 to 3, the fuse holder 300 includes a fuse holder 310, a fuse housing 320, a rotating shaft holder 330, a rotating shaft 340, a link member 350, a coil spring 360 and a fuse connecting wire 370.

The fuse mounting base 310 is fixed to the fuse section body 20. The fuse mounting base 310 includes a bottom plate 312 on which a through hole 312a through which the fuse 30 passes is formed and a fuse mounting plate 320 protruding from the bottom plate 312, (314).

The bottom plate 312 has a plate shape and three through holes 312a can be formed.

Four fuse mounting plates 314 may protrude from the bottom plate 312 to support both sides of the fuse 30.

Meanwhile, the fuse mounting plate 314 may be provided with a fixing member mounting hole 314a for fixing the fuse housing 320.

The fuse housing 320 may be provided in at least one fuse 30 fixed to the fuse mount 310 and may include a pressing member 322.

The fuse housing 320 includes a side portion 324 formed to surround both sides of the outer circumferential surface of the fuse 30 and a lid portion 326 connecting the upper end of the side portion 324 and a lid portion 326 disposed below the lid portion 326 The center plate 328 may be provided on the side surface portion 324 and the strike pin 32 of the fuse 30 may be exposed upward.

The first and second fixing member insertion holes 324a and 324b are formed in the side surface portion 324 and the first and second fixing member insertion holes 324a and 324b are formed in the opposite directions As shown in Fig.

That is, the first and second fixing member insertion holes 324a and 324b may be formed to open in opposite directions from each other to prevent separation from the fuse mounting base 314.

Meanwhile, the center plate 328 may be provided with a pressing member mounting portion 328a on which the pressing member 322 is rotatably mounted.

That is, the pressing member 322 is installed in the pressing member mounting portion 328a and is rotated by the strike pin 32 when the strike pin 32 of the fuse 30 is protruded.

In other words, the pressing member 322 can be brought into contact with the strike pin 32 at one end and the link member 350 at the other end.

The rotary shaft mount 330 is fixed to the fuse section body 20 such that the rotary shaft mount 330 is spaced apart from the fuse mount 310 by a predetermined distance.

A rotating shaft 340 is rotatably mounted on the rotating shaft mounting base 330 and at least one end of the rotating shaft 340 is connected to the rotating shaft mounting shaft 330 to provide a coil spring 360 may be installed.

The link member 350 is fixed to the rotating shaft 340 and is rotated together with the rotating shaft 340 by the pressing member 322. On the other hand, the link member 350 may have a pressing plate portion 352 contacting the pressing member 322.

The link member 350 may be installed on the rotary shaft 340 in a number corresponding to the number of the fuses 30. For example, three link members 350 may be provided on the rotary shaft 340.

That is, when the strike pin 32 of the fuse 30 protrudes, the pressing member 322 is rotated, and the link member 350 is rotated together with the rotating shaft 340 by the rotation of the pressing member 322.

On the other hand, at least one of the link members 350 may be provided with a mounting hole 354 in which a fuse connecting wire 370 is installed.

As described above, the coil spring 360 is disposed at at least one end of the rotary shaft 340, and one end thereof is connected to the rotary shaft mount 330 to provide a restoring force to the rotary shaft 340.

That is, when the rotation shaft 340 is rotated by the rotation of the link member 350, the coil spring 360 provides the driving force so that the rotation shaft 340 can return to the original position.

Meanwhile, the rotating shaft 340 may be arranged to pass through the coil spring 360.

The fuse connecting wire 370 has one end connected to at least one of the link members 350 and the other end connected to the fuse-connected three-phase switch driving apparatus 100. [

That is, when the link member 350 is rotated, the fuse connecting wire 370 is pulled, whereby the fuse-connected three-phase switch driving apparatus 100 is operated by the fuse connecting wire 370.

As described above, when the strike pin 32 of one of the three fuses 30 protrudes, the link member 350 is rotated so that the fuse connecting wire 370 is driven by the fuse- The apparatus 100 can be operated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be obvious to those of ordinary skill in the art.

10: Distribution booth for fuse 30: Fuse
100: fuse connected three-phase switch drive device 110: front plate
120: rear plate 130: fixed shaft portion
140: first power transmitting portion 142: first power transmitting member
144: Power transmission bar 150:
151: female unit 152: first arm member
153: second arm member 154: third arm member
155: fifth arm member 156: spring unit
157: upper support member 158: lower support member
159: Guide member 160: Coil spring
170: second power transmission portion 171: power transmission shaft
172: second power transmitting member 173: first rotating member
174: second rotating member 175: second power transmission link member
176: Link shaft 177: Retaining member
178: second power transmitting portion spring unit 180: second rotating portion
181: Plate unit 182: First stopper member
183: second stopper member 184: first plate
185: second plate 186: circular plate
187: third stopper member 188: fourth stopper member
189: first connecting member 190: second connecting member
191: Support shaft 192: Plate spring
195: rotating shaft 200: stopper part
202: first stopper portion 204: second stopper portion
210: stopper unit 211: stopper shaft
212: handle portion 213: spring member
214: mounting pin 215: wire mounting member
220: driving part 221: first driving part mounting plate
222: second driving part mounting plate 223: driving motor
224: gear member 225: power transmission gear
226: cam member 230: solenoid
240: interlocking plate 300: fuse holder
310: fuse mount 320: fuse housing
330: rotating shaft mounting base 340: rotating shaft
350: link member 360: coil spring
370: Fuse connecting wire

Claims (24)

A front and a rear plate spaced apart from each other by a predetermined distance;
A fixed shaft portion connected to and fixed to at least one of the front and rear plates;
A first rotating part rotatably installed on the fixed shaft part and having a coil spring which is compressed by an external force;
A first power transmission part connected to the first rotation part and rotating the first rotation part by an external force;
A second power transmission part connected to the first rotation part and rotating the first rotation part by an external force;
A second rotating part rotated by a restoring force of the coil spring;
A rotating shaft assembled to the second rotating portion and rotated in association with the second rotating portion;
A stopper installed on the rear plate and adjusting the rotation of the second rotation part; And
A stopper unit installed on the front and rear plates so as to be disposed adjacent to the second power transmission unit and rotating the second power transmission unit when the fuse is operated;
/ RTI >
The first rotating part
A female unit rotatably installed on the fixed shaft and rotated in one direction or another direction by the first and second power transmission parts; And
A spring unit connected to the arm unit and having a coil spring that is expanded and contracted by rotation of the arm unit;
And,
The arm unit
A first arm member rotatably installed on the fixed shaft portion and rotated by the first power transmission portion and having a bent shape at one side;
A second arm member rotatably installed on the fixed shaft portion and rotated by the first and second power transmission portions and bent to the other side;
And a second arm portion that is rotatably installed on the fixed shaft portion and has one end fixed to the spring unit and the other end connected to the second power transmission portion to rotate in conjunction with the second arm member when the second arm member rotates, Arm member; And
A fourth arm member rotatably installed on the fixed shaft portion and having an end fixed to the spring unit and rotated in conjunction with the first arm member when the first arm member rotates;
And a fuse-connected three-phase switch driver. The method according to claim 1,
The first power transmission portion includes a first power transmission member rotatably mounted on the fixed shaft portion and a power transmission bar provided on the first power transmission member for rotating the first rotation portion in one direction, drive. The power transmission apparatus according to claim 1, wherein the second power transmission portion
A power transmission shaft rotatably installed on the front and rear plates;
A second power transmitting member rotated by an external force and rotated in association with the power transmitting shaft;
A first rotary member fixed to the power transmission shaft and rotated together with the power transmission shaft;
A second rotary member disposed at a predetermined distance from the first rotary member and rotatably installed on the second power transmission unit fixed shaft;
A second power transmitting link member connected to the first and second rotating members via a connecting shaft;
A link shaft fixed to an end of the second power transmission link member to rotate the first rotation unit in the other direction;
An engaging member having an annular portion that is in contact with the link shaft and is rotatably installed on the fixed shaft portion;
A second power transmitting spring unit connected to the engaging member through a wire and providing a driving force for rotating the first rotating unit when the fuse is operated;
And a fuse-connected three-phase switch driver. The power unit according to claim 3, wherein the second power transmitting portion spring unit
A mounting plate fixedly installed on the front and rear plates;
A pulley rotatably installed on the mounting plate to guide the wire;
A housing fixed to one side of the mounting plate and having an inner space;
A spring inserted into the housing; And
A support member movably installed at an end of the housing to compress the spring when the wire is moved;
And a fuse-connected three-phase switch driver. delete delete The spring unit according to claim 1, wherein the spring unit
An upper support member connected to an end of the second and third arm members;
The coil spring having one end supported by the upper support member;
A lower support member supporting the other end of the coil spring and connected to an end of the first and fourth arm members; And
A guide member connecting the upper support member and the lower support member;
And a fuse-connected three-phase switch driver. 8. The method of claim 7,
Wherein the upper and lower support members each have a circular annular shape and include upper and lower supporters for supporting the coil springs and upper and lower support shafts penetrating the upper and lower supporters, . 9. The method of claim 8,
Wherein the guide member includes an upper guide hole for guiding movement of the upper support shaft and a lower guide hole for guiding movement of the lower support shaft. 9. The method of claim 8,
Wherein the upper support shaft has one end fixed to the second arm member and the other end fixed to the third arm member,
Wherein the lower support shaft has one end fixed to the first arm member and the other end fixed to the fourth arm member. The method according to claim 1,
Wherein the first power transmitting portion includes a first power transmitting member formed with a power transmitting bar protruded toward the first and second arm members,
Wherein the first and second arm members are formed with first and second power transmission bar insertion grooves that form insertion holes into which the power transmission bar is inserted when assembled to the fixed shaft portion. The method according to claim 1,
A third arm member stopper for preventing rotation in the other direction when power is transmitted is formed on the third arm member,
And a fourth arm member stopper for preventing rotation in the other direction when power is transmitted is formed in the fourth arm member. 13. The method of claim 12,
A third arm member round portion formed to extend in a direction opposite to the side where the third arm member stopper is formed and formed to be round is formed in the third arm member,
And a fourth arm member round portion formed to extend in a direction opposite to the side where the fourth arm member stopper is formed and formed to be round is formed in the fourth arm member. 2. The apparatus according to claim 1, wherein the second rotating portion
A plate unit fixedly mounted on the rotating shaft;
A first stopper member rotatably installed on the plate unit about a first pivot axis; And
A second stopper member rotatably mounted on the plate unit so as to have a predetermined angle with the first stopper member about a second pivot axis;
And a fuse-connected three-phase switch driver. 15. The apparatus of claim 14, wherein the plate unit
A first plate fixed to the rotating shaft;
A second plate fixed to the rotating shaft so as to be spaced apart from the first plate by a predetermined distance;
A circular plate installed on the rotary shaft so as to be disposed in a space between the first and second plates;
A third stopper member fixedly installed on the circular plate; And
A fourth stopper member fixed to the circular plate so as to be spaced apart from the third stopper member;
And a fuse-connected three-phase switch driver. 16. The apparatus of claim 15, wherein the plate unit
A first connecting member protruded from the first plate so that an end of the first connecting member is connected to an interlocking rotary plate provided in the first power transmitting portion; And
A second connection member protruding from the first plate so as to be spaced apart from the first connection member by a predetermined angle and having an end connected to the interlocking rotation plate;
Further comprising a fuse-connected three-phase switch drive device. 16. The apparatus of claim 15, wherein the plate unit
A support shaft having both ends fixed to the first and second plates; And
A leaf spring which is assembled to the support shaft and has both ends thereof contacted with the first and second stopper members;
And a fuse-connected three-phase switch drive device. 15. The method of claim 14,
The first and second stopper members may include first and second pivot portions pivotably installed on the first and second pivot shafts, and first and second pivot portions extending from the first and second pivot portions, 2 fuse-connected three-phase switch drive device comprising first and second extension bars for pivoting the pivot portion. 16. The method of claim 15,
The stopper portion includes a first stopper portion for restricting rotation of the first stopper member and a second stopper portion for restricting rotation of the second stopper member,
Wherein the first stopper portion comprises three stopper members, and the second stopper portion comprises two stopper members. The apparatus according to claim 1, wherein the stopper unit
A stopper shaft rotatably installed on the front and rear plates, the stopper shaft having a passage groove for rotation of the power transmitting portion;
A handle portion connected to one side of the stopper shaft so as to be projected from the front plate;
A spring member inserted into the other end of the stopper shaft and having one end supported by a support pin provided on the rear plate;
A mounting pin fixed to the stopper shaft so that the other end of the spring member is installed; And
A wire mounting member fixed to the stopper shaft so as to be disposed adjacent to the front plate and having a fuse connecting wire for connection with a fuse;
And a fuse-connected three-phase switch driver. 21. The method of claim 20,
A solenoid fixed to a mounting plate installed on the rear plate so as to be adjacent to the stopper unit and having a push pin projected to the outside; And
An interlocking plate fixed to the stopper shaft so as to be in contact with the push pin;
Further comprising a fuse-connected three-phase switch driver. The method according to claim 1,
Further comprising a driving unit fixed to at least one of the front and rear plates to rotate the second power transmission unit. 23. The apparatus of claim 22, wherein the driving unit
A first driving part mounting plate fixedly installed on the rear plate;
A second driving part mounting plate connected to the first driving part mounting plate so as to be spaced apart from the first driving part mounting plate by a predetermined distance through spacing members;
A driving motor installed on the second driving part mounting plate;
A plurality of gear members disposed in the space between the first and second driving part mounting plates and connected to the driving motor and rotated;
A power transmission gear connected to at least one of the plurality of gear members and fixedly mounted on a gear member rotation shaft; And
A cam member fixedly mounted on the gear member rotational shaft and rotated in association with the gear member rotational shaft;
And a fuse-connected three-phase switch driver. delete

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