KR101180668B1 - Power transfer switch - Google Patents

Abstract

PURPOSE: A main shaft structure of a power transfer switch is provided to minimize momentum loss of a driving part and reduce manufacturing costs by simplifying the main shaft structure. CONSTITUTION: A power up coil(120) is installed on a horizontal piece(114) of a base(110). A moving plunger(130) is installed movably by a magnetic force generated from the power up coil. A connection member(140) is installed on the upper side of the moving plunger. A main shaft(150) is rotated by the movement of the moving plunger. The main shaft includes a head(152) and a shaft section(154).

Description

Main shaft structure of power switchgear {Power transfer switch}

The present invention relates to a main shaft used for a power switchgear, and more particularly, by improving the structure of the main shaft used when alternatively switching two different power sources such as commercial power and emergency power of the power switchgear The present invention relates to a main shaft structure of a power switching switch with a simplified structure such as to facilitate manufacture.

In general, when the power supply is switched off from a substation in a workplace or a building equipped with its own power generation facilities, the internal wiring terminal is automatically switched to the generator side to continuously receive power, and the power supply to the substation side is normally performed. The ground is automatically switched back to supply power to the substation.

Such a power switching switch is to connect two different power sources, such as a commercial power supply and an emergency power supply, or a star connection power supply and a delta connection power supply, to the load side, and various forms have been developed and used according to their capacity and use.

Korean Utility Model Publication No. 87-1383 discloses a power switching switch comprising an operating lever, a control shaft, a movable contactor, a point plate and a latch. In addition, the present applicant has developed a more improved power switching switch than the invention of the utility model has been filed as a patent application 1998-0024896 (filed June 29, 1998).

1 is a plan view showing a power switchgear for use in a small capacity, including a general household, referring to this, the conventional power switchgear (1) is largely divided into two, such as commercial power supply and emergency power or star connection power supply and delta connection power supply. It is configured to connect or cut off two different power sources, each phase (R, S, T, N) is composed of a blocking unit 10 that is expressed to the outside and a drive unit 20 for generating a magnetic force transmission side According to the ground of the substation side, the contact point with the indoor wiring terminal, which is the load side, is changed so that the continuous power supply is smoothly performed on products requiring power.

Specifically, referring to Figure 1, the conventional power switching switch (1) is directly connected to the breaker 10 and the drive unit 20, the breaker 10 is a plurality of normal (current) is supplied A commercial power source 11, a plurality of emergency power sources 12 supplied with an emergency current, a plurality of current supply terminals 13 connected to the commercial power source 11 or an emergency power source 12 for flowing a current, It may be made of a load 14 connected to the conducting terminal 13, respectively.

Also, as shown in FIG. 2, the driving unit 20 includes a pair of operation coils 21 for moving the pair of moving plungers 25 to the left and right by magnetic force, and the pair of operation coils 21. A connecting member 22 for connecting the movable plunger 25, one end of which is connected to the connecting member 22, and a main shaft 23 that rotates left and right according to the transfer of the connecting member 22, and the main shaft. Coupled with (23), it may include an operating lever 24 to be in contact with the plurality of energizing terminal 13 in accordance with the rotation of the main shaft 23 to apply power.

In the conventional power switching switch 1 having such a configuration, the breaker 10 is operated by the operation of the driving unit 20 to supply commercial power at ordinary times, and to cut off power supply from the substation as in the case of a power failure. When the indoor wiring terminal is automatically switched to its own generator side to continuously receive power, when the power supply of the substation side is normally performed, it is automatically switched back to supply power to the substation side.

However, the above-described conventional power switching switch 1 has a disadvantage in that the structure of the main shaft 23 of the driving unit 20 is complicated and difficult to manufacture. In addition, there is a disadvantage that the manufacturing cost is increased because of the complex structure.

Accordingly, the present applicant has devised a main shaft structure of the power switching switch that can solve the conventional problems as described above.

Korean Utility Model Publication No. 87-1383 Republic of Korea Patent Application No. 1998-0024896

One embodiment of the present invention is to provide a main shaft structure of a power switching switch to simplify the configuration of the main shaft rotated during power switching, and to reduce the manufacturing cost.

According to an aspect of the present invention, the power supply coil, a moving plunger movably installed by a magnetic force generated by the power supply coil, and is connected by the moving plunger and the connecting member and rotates in accordance with the movement of the moving plunger It includes a main shaft, wherein the main shaft is coupled to the link of the connecting member and a head portion formed with a curved guide hole therein, characterized in that it comprises a shaft portion protruding in one direction of the front of the head portion The main shaft structure of the power switchgear is provided.

In addition, the main shaft is characterized in that it is rotatably coupled through a link and a link pin provided in the connecting member.

In addition, the guide hole is located between the first rotary groove and the second rotary groove to rotate the main shaft, the first rotary groove and the second rotary groove of the link connecting the connecting member and the main shaft It may include a first via groove and a second via groove that the link pin is moved according to the rising and falling.

In addition, the first rotary groove and the second rotary groove is formed in the lower left and right both sides of the guide hole, the second via groove and the second via groove is characterized in that it is formed to be located above the guide hole. do.

In addition, the first rotary groove and the second rotary groove is characterized in that it is formed in a trapezoidal shape so that the width of the first via groove and the second via groove is small.

The connecting member may include a guide pin coupled to the moving plunger, and a link to one end rotatably coupled to the guide pin.

According to an embodiment of the present invention, the power input coil structure of the driving unit operated at the time of power switching is formed by using a single power input coil, and the structure of the main shaft is simplified, thereby simplifying the structure. Therefore, it is possible to minimize the momentum loss of the drive unit and reduce the manufacturing cost.

1 is a plan view showing a conventional power switching switch.
2 is a perspective view schematically showing a driving unit of a conventional power switching switch.
3 is a perspective view schematically showing a power switching switch using a main shaft according to an embodiment of the present invention.
4 is a perspective view schematically illustrating the driving unit of FIG. 3.
5 is an exploded perspective view of FIG. 4.
6 is a front view of a power switching switch using a main shaft according to an embodiment of the present invention.
7 is a side view of FIG. 6.
8A and 8B are operation diagrams of a power switching switch using a main shaft according to an embodiment of the present invention.

Hereinafter, the main shaft structure of the power switching switch according to the embodiments of the present invention with reference to the drawings will be described in more detail.

3 is a perspective view schematically showing a power switching switch using a main shaft according to an embodiment of the present invention, FIG. 4 is a perspective view schematically showing a driving unit of FIG. 3, and FIG. 5 is an exploded perspective view of FIG. 4. to be.

3 to 5, the power switching switch 100 using the main shaft according to an embodiment of the present invention by using a single power supply coil 120, it is possible to reduce the manufacturing cost by simplifying the structure At the same time, it is possible to minimize the momentum loss of the drive unit 100a required to rotate the main shaft 150, the base unit 110, the power supply coil 120, and the moving plunger (moving plunger 130) And a connection member 140 and a main shaft 150.

The base unit 110 is to support and fix the components described below, it may be formed in a plate shape having a predetermined area. At this time, in an embodiment of the present invention, one side may be formed to be bent in an upward direction to be formed in a right angle shape to be made of a vertical piece 112 and a horizontal piece 114, and in some cases both sides protrude upward. It may be formed in the shape of "C" to partition the driving unit (100a) and the blocking unit (100b) of the power switching switch (100).

The power supply coil 120 may be installed to be seated on an upper side of the horizontal piece 114 of the base portion 110. At this time, the power supply coil 120 is to be supplied with power to generate a magnetic force, it is formed in a cylindrical shape, it is made of a single, rather than a pair as in the conventional power switch.

Here, the base portion 110 is installed so that the power supply coil 120 is seated is securely supported by fixing the power supply coil 120 between the bent in the upper direction as shown in the figure It may be provided with a partition 116 to be made.

The moving plunger 130 is lifted up and down by a magnetic force generated by the power supply coil 120 and is formed so that one end can be inserted into or withdrawn from the power supply coil 120 having a cylindrical shape. do.

In this case, the movable plunger 130 may be formed to have an elastic restoring force with respect to the power input coil 120. That is, in one embodiment of the present invention, after the coil flange 117 having the through hole 117a formed on the upper side of the power supply coil 120 is fixedly installed on the vertical piece 112, the coil flange ( By installing the elastic member 118 between the 117 and the moving plunger 130, the movable plunger 130 can be elastically supported.

The elastic member 118 is a compression coil spring, and when the magnetic force is generated in the power supply coil 120, the moving plunger 130 is moved downward, and when the magnetic force is dissipated in the power supply coil 120 The moving plunger 130 is to be moved upward by the elastic restoring force of the elastic member 118.

In addition, as shown in FIG. 6, the connecting member 140 may be installed on the upper side of the movable plunger 130. The connecting member 140 may connect the movable plunger 130 and the main shaft 150 to be described later to rotate the main shaft 150 as the movable plunger 130 moves up and down.

In detail, the connection member 140 may include a guide pin 142 coupled to the moving plunger 130 and a link 144 one end of which is pivotably coupled to the guide pin 142. That is, the guide pin 142 is coupled to the vertical piece 112 of the base 110 so that one end can be moved up and down in the vertical direction, the other end may be coupled to the link 144.

In this case, a guide groove 112a may be formed on the vertical piece 112 of the base to which one end of the guide pin 142 is coupled to move up and down in the vertical direction. That is, the guide pin 142 may be formed to move up and down in the vertical direction by guiding the guide pins 142 when the moving plunger 130 moves up and down.

In addition, as described above, when the vertical piece 112 is formed to protrude from both ends of the base 110, after the link 144 on the guide pin 142 of the guide pin 142 Both ends may be coupled to the vertical piece 112 to be lifted up and down to allow the guide pin 142 to be lifted up and down in a more stable state.

That is, guide grooves 112a are formed in the vertical pieces 112 formed to protrude upwards on both sides of the base 110, and the guide pins 142 are moved up and down in the guide grooves 112a. By combining so as to prevent the guide pin 142 from moving left and right when the guide pin 142 is raised and lowered, it is possible to prevent the force from being dispersed.

Meanwhile, one end of the link 144 rotatably coupled to the guide pin 142 may be coupled to the other end of the link movably with the main shaft 150 through the link pin 145. The main shaft 150 rotates an energization terminal (not shown) of the blocking unit 100b as the moving plunger 130 moves up and down to allow a current such as a commercial power source or an emergency power source to flow.

Specifically, the main shaft 150 is formed to protrude in one direction of the front of the head portion 152, the head portion 152 formed with a curved guide hole 153, the conductive terminal can be coupled One shaft portion 154 to be made.

As shown in FIG. 7, the guide hole 153 of the head 152 is connected to the link 144 through the link pin 145 on the upper side thereof, and thus the main shaft (152) moves up and down. The link 144 is located between the first rotary groove 153a and the second rotary groove 153b and the first rotary groove 153a and the second rotary groove 153b to rotate 150. It may include a first via groove 153c and a second via groove 153d to which the link pin 145 moves according to the rising and falling of the.

In this case, the first rotary groove 153a and the second rotary groove 153b are formed at both the lower left and right sides of the guide hole 153, and the first via groove 153c and the second via groove 153d. ) Is formed to be located above the guide hole 153, the first via groove 153c and the second via groove 153d with respect to the first rotary groove 153a and the second rotary groove 153b. It may be formed in a trapezoidal shape so that the width of the).

That is, as shown in FIG. 8A, in the state where the power supply coil 120 is not initially excited, no press force is generated, and thus the movable plunger 130 is raised by the elastic force of the elastic member. Therefore, the guide pin 142 coupled to the upper side of the movable plunger 130 is also located on the upper side and the link 144 is also positioned on the upper side and the link pin 145 coupled to one end of the link 144 is a guide hole ( It is located in the first via groove 153c of 153.

In this state, as the power supply coil 120 is excited, electromotive force is generated, and the movable plunger 130 is vertically lowered. Accordingly, the link 144 connected to the guide pin 142 is lowered so that the link pin 145 is positioned in the first rotary groove 153a of the guide hole 153 and thus the link is lowered by the continuous link 144. The pin 145 presses the first rotary groove 153a so that the main shaft 150 is rotated.

In addition, when the excitation of the power supply coil 120 ends, the electromotive force is extinguished so that the movable plunger 130 is raised by the elastic restoring force of the elastic member that elastically supports the movable plunger 130. Is raised so that the link pin 145 is moved to the second via groove 153d via the first via groove 153c.

In other words, by the operation as described above it is switched from the commercial power source to the emergency power it is possible to continuously supply power to the consumer side.

On the other hand, when switching from the emergency power source to the commercial power source, as shown in Figure 8b, the power supply coil 120 is excited while the moving plunger 130 is lowered and the link pin 145 of the connection member 140 The second rotary groove 153b of the guide hole 153 is lowered to rotate the main shaft 150 to supply commercial power to the consumer side.

In this state, when the excitation of the power supply coil 120 is finished, the moving plunger 130 is raised, and thus the link 144 is raised so that the link pin 145 passes through the second via groove 153d. It is to be moved to the first via groove (153c).

Therefore, the main shaft structure of the power switching switch according to an embodiment of the present invention is formed of a single power input coil 120 to form a configuration that used the existing two power input coil 120, the single power input coil By configuring the main shaft 150 to rotate only by (12), it is possible to simplify the structure to minimize the momentum loss of the drive unit (100a) and at the same time reduce the manufacturing cost.

As mentioned above, although embodiments of the present invention have been described, those skilled in the art may add, change, delete, or add components without departing from the spirit of the present invention described in the claims. The present invention may be modified and changed in various ways, which will also be included within the scope of the present invention.

100: power switching switch 100a: drive unit
100b: blocking unit 110: base unit
112: vertical piece 112a: guide groove
114: horizontal piece 116: partition wall
117: coil flange 117a: through hole
118: elastic member 120: power supply coil
130: moving plunger 140: connecting member
142: guide pin 144: link
145: link pin 150: main shaft
152: head 153: guide ball
153a: first rotating groove 153b: second rotating groove
153c: first via groove 153d: second via groove
154: shaft portion

Claims (6)

Power supply coil;
A moving plunger movably installed by a magnetic force generated by the power input coil;
The main shaft is connected by the movable plunger and the connecting member and rotates according to the movement of the movable plunger.
The main shaft
A head portion coupled with a link of the connection member and having a guide hole formed therein with a bend,
The main shaft structure of the power switching switch characterized in that it comprises a shaft portion protruding in one side of the front of the head portion.
The method according to claim 1, wherein the main shaft
The main shaft structure of the power switching switch characterized in that it is rotatably coupled through a link and a link pin provided in the connecting member.
The method of claim 1, wherein the guide ball
A first rotary groove and a second rotary groove for rotating the main shaft;
The power switching switch is located between the first rotary groove and the second rotary groove and including a first via groove and a second via groove that the link pin is moved in accordance with the lifting and lowering of the link connecting the connecting member and the main shaft. Main shaft structure.
The method of claim 3, wherein the first rotary groove and the second rotary groove is formed on the lower left and right both sides of the guide hole, the first via groove and the second via groove to be located on both the upper left and right sides of the guide hole. Main shaft structure of the power switching switch characterized in that it is formed.
The main shaft structure of the power switchgear of claim 4, wherein the first rotary groove and the second rotary groove are formed in a trapezoidal shape so that the widths of the first and second via grooves become smaller.
The method according to claim 1, wherein the connecting member
A guide pin coupled to the moving plunger,
The main shaft structure of the power switching switch, characterized in that consisting of a link that is rotatably coupled to one end of the guide pin.

Images