KR101441462B1 - Control System for Separating Fault Section of Distribution Line - Google Patents

Abstract

A control system for separating the fault section of a distribution line determines the error of a distribution line by using the detection signal of a sensor unit installed in the constant range of the distribution line, thereby operating an automatic switchgear to block an existing line and pauselessly connecting the current and voltage of the distribution line through a bypass line. The present invention determines the error range of a distribution line, prevents wide area blackout by quickly connecting a bypass line when there is an error in the distribution line, and pauselessly connects the current and voltage of the distribution line. The present invention stably performs separation and return when there is an error in the distribution line, thereby reliably controlling the current and voltage of the distribution line.

Description

Technical Field [0001] The present invention relates to a control system for a fault section of a distribution line,

More particularly, the present invention relates to a control system for a failure section of a distribution line, and more particularly, to a failure detection system for a distribution line, The present invention relates to a fault section separation control system for a distribution line that disconnects a line and continuously connects a current and a voltage to a distribution line through a bypass line.

In the past, when a fault current and a voltage are generated in a distribution line, a substation operator is operated by a substation operator in order to find a faulty current and a voltage. It was a common method to find out the merits by exchanging them.

However, this method consumes a lot of time and manpower, and as the recovery time becomes longer, the power outage time becomes longer, which causes a problem of inconveniencing power consumers.

Therefore, there is a need for a method of improving the reliability of the power supply and the quality of service for the customer by quickly recognizing and recovering the position of the advantage in case of an accident with the power distribution line and shortening the power failure time.

At present, there is a line automatic switch at the branch point or the entrance of the customer in the substation system.

In case of a ground fault, the line automatic switch interlocks with the line open / close control device installed in the circuit breaker of the substation and the distribution line, so that the fault section can be quickly or precisely blocked or opened to prevent expansion of the fault section and minimize the damage.

However, in the conventional line automatic switch, when a failure occurs in the power distribution system, it is judged and separated from the failure section of the power distribution line. However, unnecessary wide-area power failure still occurs due to the simple cutoff method, and the non- There is a problem that a power interruption time of moisture occurs.

If a fault current is detected from the distribution line and the automatic line switch is continued for a certain period of time, the distribution line is completely opened and the line is not reclosed.

When a line failure occurs in the distribution line, the line operator of the line is turned off at the judgment of the operator of the operation room, and the line automatic switch is connected to the associated line.

In such a distribution line, there is a problem that a power failure occurs in a malfunction of a healthy section or a malfunction section and a distant section because a certain time is delayed in separating and returning a malfunction section.

Korean Registered Patent No. 10-0537217 (Registered on Dec. 09, 2005), entitled "Distribution control system for separating fault section of distribution line"

In order to solve the problems and necessity of the related art, the present invention determines whether the distribution line is broken by the detection signal of the sensor means installed in a certain section of the distribution line, and accordingly, the automatic opening / And disconnecting the current and voltage from the distribution line through the bypass line without interruption.

In order to achieve the above object, a failure section separation control system for a distribution line according to the present invention is provided between a sensor unit (S1) (S2) as a part of a distribution line (10) And a controller (not shown) connected to a lower portion of the automatic opening / closing device 100 to control the automatic opening / closing device 100. The automatic opening / closing device 100 200,

The control device 200 includes a control device body 201 having a predetermined space and a first through hole 202 and a second through hole 204 passing through the upper and lower surfaces of the control device main body 201, A rack gear 300 formed to extend vertically through the first through hole 202 and the second through hole 204 in a vertical direction and to be coupled with the rack gear 300, A pinion gear 304 and a drive motor 302 for providing a driving force for rotating the pinion gear 304 are provided on the upper surface of the main body 201. Inside the control device main body 201, A communication unit 214 for receiving a measurement signal of the sensor means for detecting a voltage and a current and for transmitting the received signal value in real time, and a communication unit 214 for receiving a signal value transmitted from the communication unit 214, A control unit 210 connected to the control unit 210 for determining in real time, A power supply unit 212 which is charged by a power source flowing through the power supply unit 10 and supplies power to the power supply unit and the opening and closing device main body 102 is connected to an upper end of the rack gear 300,

The opening and closing device main body 102 has a rectangular shaped body and a driving gear 162 connected to a motor 164 on an inner bottom surface thereof and a main gear 160 engaged with the driving gear 162, A rod-shaped operation connecting member 172 vertically installed at a central portion of the gear 160 and rotated by the motor 164, a bar-shaped operation connecting member 172 horizontally installed at an upper end of the rotating rod 170, 120, 130, and 140 formed vertically upright on each of the inner inner surfaces of the rectangular opening and closing device body 102 and the inner side of the fixed support rods 110, 120, 130, The rack gears 111, 121, 131, and 141 are formed with upper rack gears 111, 121, 131, and 141 and upper pinion gears 112, 122, 132, and 142, Lower pinion gears 115, 125, 135, and 145 meshed with the lower pinion gears 112, 122, 132, And lower motors 116, 126, 136 and 146, which are driving means connected to the lower pinion gears 115, 125, 135 and 145 and move up and down, Shaped upper ground portions 114, 124, 134 and 134 are formed at the ends of the upper pinion gears 112, 122, 132, and 142 and the lower pinion gears 115, 125, 135, The upper pinion gears 112, 122, 132 and 142 move in the downward direction and the lower pinion gears 117, 127, 137 and 147 are moved by the lower limit switches 118, 128, 138 and 148, The lower pinion gears 115, 125, 135 and 145 are moved in the upward direction and the moving distance is limited by the upper limit switches 119, 129, 139 and 149, And the lower ground portions 117, 127, 137, 147 spaced apart from the inner surface of the opening and closing device main body 102 by a predetermined distance from the inner surface of the opening and closing device main body 102, 10, a third grounding member and a fourth grounding member are provided on the bypass line 20 perpendicular to the power distribution line 10,

The controller 210 operates the first upper motor 113 and the second upper motor 123 to operate the first upper pinion gear 112 and the first upper pinion gear 112, The first lower pinion gear 115 and the second lower pinion gear 125 are moved in the upward direction by operating the first lower motor 116 and the second lower motor 126, The first upper pinion gear 112 and the first lower pinion gear 115 are formed with a first upper grounding portion 114 and a second upper grounding portion 112. The first upper grounding portion 114 and the second upper grounding portion 112 are formed in the longitudinal direction at the respective ends of the first upper pinion gear 112 and the first lower pinion gear 115, A second upper ground portion 124 which is the second ground member formed in the longitudinal direction at each end of the second upper pinion gear 122 and the second lower pinion gear 125, The second lower grounding portions 127 are spaced away from each other, and the rotating rod 170 is rotated by 90 degrees so that the operation connecting member 172 Is separated and separated from the space between the first upper ground 114 and the first lower ground 117 and the space between the second upper ground 124 and the second lower ground 127 A space between the third upper grounding part 134 and the third lower grounding part 137 as the third grounding member and a space between the fourth upper grounding part 144 and the fourth lower grounding part 137 as the fourth grounding member, (14), and connects the current and voltage of the distribution line (10) through the bypass line (20)

The first grounding member of the first upper grounding part 114 and the first lower grounding part 117, the second grounding member of the second upper grounding part 124 and the second lower grounding part 127, The third grounding member of the third upper grounding part 134 and the third lower grounding part 137 and the fourth grounding member of the fourth upper grounding part 144 and the fourth lower grounding part 147 are made of a conductive material A plurality of conductive plates 150 and 180 bent at a predetermined angle and fixed ends 152 and 182 at one ends of the conductive plates 150 and 180 and a semicircular protrusion Shaped protrusions 154 and 184 and balls 156 and 186 protruding from the other ends of the conductive plates 150 and 180 and connected to the balls 156 and 186 inwardly of the conductive plates 150 and 180 Spring members 158 and 188, respectively.

According to the present invention having the above-described structure, it is possible to determine a fault section of a distribution line and quickly connect to a bypass line in case of failure of the distribution line, thereby preventing unnecessary wide-area power failure and connecting the current and voltage to the distribution line without interruption.

Disclosure of the Invention The present invention is capable of stably performing separation and return when a distribution line fails, and has an effect of controlling the flow of current and voltage to a reliable distribution line.

1 is a perspective view showing a configuration of a fault section separation control system for a distribution line according to an embodiment of the present invention.
2 is a cross-sectional view showing a configuration of a failure section separation control system for a distribution line according to an embodiment of the present invention.
FIG. 3 is a view illustrating a failure-section separation control system of a distribution line according to an embodiment of the present invention.
4 is a side view showing the concept of the up-and-down moving means according to the embodiment of the present invention.
5 is a block diagram briefly showing a configuration of a control apparatus according to an embodiment of the present invention.
And
6 is a view showing a configuration of a grounding member according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Conventionally, when a fault occurs in a line automatic switch to a power distribution line, there is a problem that an unnecessary wide-area power interruption lasts for several minutes in a simple cut-off mode.

In such a distribution line, there is a problem that a power failure occurs in a malfunction of a healthy section or in a section located far from a fault section because a certain time is delayed in separating and returning the fault section.

FIG. 1 is a perspective view showing a configuration of a failure section separation control system for a distribution line according to an embodiment of the present invention, FIG. 2 is a sectional view showing the configuration of a failure section separation control system for a distribution line according to an embodiment of the present invention, 4 is a side view showing the concept of the up-and-down moving means according to the embodiment of the present invention, and FIG. 5 is a cross- FIG. 1 is a block diagram briefly showing a configuration of a control apparatus according to an embodiment of the present invention.

The present invention is applicable to an automatic opening and closing apparatus (or an automatic opening / closing apparatus) by detecting signals of sensor means (S1) and (S2) installed on the leading end side and the rear end side of a distribution line (10) 100 are operated to temporarily shut off the flow of the distribution line 10 when the distribution line 10 fails and to connect the distribution line 10 to the bypass line 20.

The failure section separation control system of the distribution line 10 of the present invention includes an automatic opening and closing apparatus 100 installed between the sensor means S1 and S2 as a certain portion of the distribution line 10, And a control device 200 connected to a lower portion of the control device 200 for controlling the automatic opening and closing device 100.

The control device 200 includes a control device body 201 having a predetermined space and a first through hole 202 and a second through hole 204 passing through the upper and lower surfaces of the control device main body 201 A rack gear 300 which is formed by vertically extending up and down through the first through hole 202 and the second through hole 204 in a vertical direction, A pinion gear 304 and a drive motor 302 for providing a driving force for rotating the pinion gear 304 are provided on the upper surface.

The rack gear 300 is fixed to the bottom plate 203 through the second through hole 204 of the control apparatus main body 201.

The control device body 201 is movable up and down along the rack gear 300. [

The control unit main body 201 includes a control unit 210, a power supply unit 212, a communication unit 214, and a user interface module 216.

The communication unit 214 receives the measurement signal of the sensor means S1 and S2 for detecting the voltage and current at the lower stage and transmits the received signal value in real time in a wired or wireless manner.

The control unit 210 determines a signal value transmitted from the communication unit 214 in real time based on a fault current and a fault voltage.

The power supply unit 212 is connected to the control unit 210 and is charged by a power source flowing through the power distribution line 10 to supply power to the configuration apparatus.

The power supply unit 212 may further be connected to the solar light unit T1 using solar light as a power source, so that the power supply unit 212 can receive power when the power distribution line 10 fails.

The user interface module 216 controls the display device such that the user operates the control device 200 in the field and confirms the operating environment of the automatic switching device 100 and the control device 200 and the state of the distribution line 10. [ And includes a plurality of operation buttons.

The opening and closing device main body 102 is connected to an upper end of the rack gear 300 and a driving gear 162 connected to the motor 164 is engaged with the driving gear 162, The main gear 160 is formed.

A rotation rod 170 vertically erected is coupled to the center of the main gear 160.

The main gear 160 is rotated in the opposite direction as the driving gear 162 rotates in one direction by the motor 164 so that the rotating rod 170 connected to the main gear 160 rotates.

At the end of the rotation bar 170, an operation connecting member 172 in the form of a rod is provided in the horizontal direction. The operation connecting member 172 is preferably formed in a rod shape having a square cross section and having a predetermined length.

In addition, as the material of the operation connecting member 172, it is preferable to use an alloy of copper and aluminum or a mixture of copper and aluminum because it is a material having high electrical conductivity.

The operating connecting member 172 is inserted into or removed from the grounding member while the operating connecting member 172 is also rotated by the rotation of the rotating rod 170 when the rotating rod 170 is rotated by the driving of the motor 164 Thereby connecting and disconnecting the voltage and current.

The opening / closing device body 102 is formed in a rectangular shape, and vertically moving means including a grounding member is provided on each of the inner side surfaces of the opening / closing device main body 102. The vertically moving means is divided into an upper moving member and a lower moving member, And the lower movable member moves upward to form one grounding member.

Two vertically moving means are provided on the distribution line 10 of the sensor means S1 and S2 and two are provided on the bypass line 20 perpendicular to the distribution line 10.

The first and second vertical moving means and the second vertical moving means provided on the power distribution line 10 of the sensor means S1 and S2 are provided on the bypass circuit 20 in the direction perpendicular to the power distribution line 10, And third up-and-down moving means.

The first up-and-down moving means includes a first fixed support 110 formed vertically upright and a first rack gear 111 formed in an inner direction of the first fixed support 110.

The first rack gear 111 is meshed with the first upper pinion gear 112 at the upper portion thereof and meshed with the first lower pinion gear 115 at the lower portion thereof.

The first upper pinion gear 112 and the first lower pinion gear 115 are connected to a first upper motor 113 and a first lower motor 116 which are driving means for moving up and down.

The first upper pinion gear 112 and the first lower pinion gear 115 have a first upper ground portion 114 and a first lower ground portion 117 formed at the ends thereof, respectively.

The first upper pinion gear 112 is moved in the lower direction and the moving distance is limited by the first lower limit switch 118. The first lower pinion gear 115 is moved in the upper direction, 119 are limited.

That is, when the first upper pinion gear 112 and the first lower pinion gear 115 are moved, when the first upper limit switch 119 and the first lower limit switch 118 operate, Receives an operation stop signal from the upper limit switch 119 and the first lower limit switch 118 and turns off the power of the first upper motor 113 and the first lower motor 116.

When the movement of the first upper pinion gear 112 and the first lower pinion gear 115 is stopped, the first upper pinion gear 114 and the first upper pinion gear 114 are separated from each other by a predetermined distance The first grounding member is formed by a pair of the lower grounding portions 117.

The second up-and-down moving means includes a second fixed support 120 formed vertically upright and a second rack gear 121 formed in an inward direction of the second fixed support 120.

The second rack gear 121 is meshed with a second upper pinion gear 122 at its upper portion and a second lower pinion gear 125 at its lower portion.

The second upper pinion gear 122 and the second lower pinion gear 125 are connected to a second upper motor 123 and a second lower motor 126 as drive means for moving the upper and lower pinions.

The second upper pinion gear 122 and the second lower pinion gear 125 have a second upper ground portion 124 and a second lower ground portion 127 at their respective ends in the longitudinal direction.

The second upper pinion gear 122 is moved in the lower direction and the moving distance is limited by the second lower limit switch 128. The second lower pinion gear 125 is moved in the upper direction and the second upper limit switch 129).

That is, when the second upper limit switch 129 and the second lower limit switch 128 operate when the second upper pinion gear 122 and the second lower pinion gear 125 move, Receives an operation stop signal from the upper limit switch 129 and the second lower limit switch 128 and turns off the power of the second upper motor 123 and the second lower motor 126. [

When the movement of the second upper pinion gear 122 and the second lower pinion gear 125 is stopped, the second upper pinion gear 124 and the second upper pinion gear 124 are separated from each other by a predetermined distance And the second grounding member 127 is formed as a pair.

The third up-and-down moving means is vertically erected, and the third rack gear 131 is formed in the third fixed support 130 and the third fixed support 130, which are long and long.

The third rack gear 131 is meshed with a third upper pinion gear 132 at its upper portion and meshed with a lower third pinion gear 135 at its lower portion.

The third upper pinion gear 132 and the third lower pinion gear 135 are connected to a third upper motor 133 and a third lower motor 136 which are driving means for moving up and down.

The third upper pinion gear 132 and the third lower pinion gear 135 are formed at their respective ends with a third upper ground portion 134 and a third lower ground portion 137 in the longitudinal direction.

The third upper pinion gear 132 is moved in the lower direction and the moving distance is limited by the third lower limit switch 138. The third lower pinion gear 135 is moved in the upper direction, 139).

That is, when the third upper pinion gear 132 and the third lower pinion gear 135 are moved, when the third upper limit switch 139 and the third lower limit switch 138 operate, Receives an operation stop signal from the upper limit switch 139 and the third lower limit switch 138 and turns off the power of the third upper motor 133 and the third lower motor 136. [

When the movement of the third upper pinion gear 132 and the third lower pinion gear 135 is stopped, the third upper pinion gear 132 and the third upper pinion gear 135 are separated from the third upper pinion gear 132 and the third upper pinion gear 134, The third grounding member is formed by a pair of three lower grounding portions 137.

The fourth up-and-down moving means is vertically erected, and the fourth rack gear 141 is formed in the fourth fixed support rods 140 and the fourth fixed support rods 140, which are vertically extended.

The fourth rack gear 141 is engaged with the fourth upper pinion gear 142 at the upper portion thereof and the fourth lower pinion gear 145 is engaged at the lower portion thereof.

The fourth upper pinion gear 142 and the fourth lower pinion gear 145 are connected to a fourth upper motor 143 and a fourth lower motor 146 which are driving means for moving up and down.

The fourth upper pinion gear 142 and the fourth lower pinion gear 145 have a fourth upper ground portion 144 and a fourth lower ground portion 147 formed at the respective ends thereof in the longitudinal direction.

The fourth upper pinion gear 142 is moved in the lower direction and the moving distance is limited by the fourth lower limit switch 148. The fourth lower pinion gear 145 is moved in the upper direction, The movement distance is limited.

That is, when the fourth upper pinion gear 142 and the fourth lower pinion gear 145 move, when the fourth upper limit switch and the fourth lower limit switch 148 are operated, the control unit 210 controls the fourth upper limit switch 148, And the fourth downward limit switch 148 to turn off the power of the fourth upper motor 143 and the fourth lower motor 146. [

When the movement of the fourth upper pinion gear 142 and the fourth lower pinion gear 145 is stopped, the fourth upper pinion gear 144 and the fourth upper pinion gear 144 are separated from each other by a predetermined distance And a fourth grounding member is formed by a pair of four lower grounding portions 147. [

In other words, the first up-down moving means and the second up-down moving means are provided on the power distribution line 10 and the third up-down moving means and the fourth up-down moving means are provided on the bypass line 20 perpendicular to the power distribution line 10, As shown in FIG. The first up-down moving means and the second up-down moving means simultaneously operate, and the third up-down moving means and the fourth up-down moving means simultaneously operate.

The first vertical moving means includes a first fixed support base 110, a first rack gear 111, a first upper pinion gear 112, a first lower pinion gear 115, a first pair of first ground members An upper ground portion 114, and a first lower ground portion 117. [

The second up-and-down moving means includes a second fixed support base 120, a second rack gear 121, a second upper pinion gear 122, a second lower pinion gear 125, a pair of second ground members, An upper ground portion 124, and a second lower ground portion 127.

The third up-and-down moving means includes a third upper support pinion 130, a third upper pinion gear 132, a third lower pinion gear 135, a third upper grounding portion 134 which is a pair of third grounding members, 3 lower grounding portion 137. [

The fourth up-and-down moving means includes a fourth fixed support rod 140, a fourth rack gear 141, a fourth upper pinion gear 142, a fourth lower pinion gear 145, An upper ground portion 144, and a fourth lower ground portion 147. [

The operation connecting member 172 is disposed in a space between the first upper grounding portion 114 and the first lower grounding portion 117 provided on the power distribution line 10 when the current and voltage flow of the power distribution line 10 is normal, (The first ground member) and the space (the second ground member) between the second upper ground 124 and the second lower ground 127.

When a failure occurs in the distribution line 10, the operation connecting member 172 is separated from the first grounding member and the second grounding member and rotates at a right angle of 90 degrees, so that the third upper grounding part 134 and the third lower grounding part 134, (Third grounding member) between the fourth upper grounding part 144 and the fourth lower grounding part 147 (the fourth grounding member).

The operation connecting member 172 indicates the current and voltage flow of the normal distribution line 10 when inserted into the first grounding member and the second grounding member provided on the distribution path of the sensor means and is perpendicular to the distribution line 10, Current and voltage are connected to the third grounding member provided on the bypassing line 20 in the direction and the bypassing line 20 when the fourth grounding member is inserted into the fourth grounding member.

The sensor means provided on the leading end side and the trailing end side of the power distribution line 10 passing the side ladder can be provided for each side ladder and the current or voltage between the side ladder can be measured.

The current or voltage measured by the sensor means is transmitted to the communication unit 214 and the communication unit 214 also transmits or receives the voltage or current value between the neighboring communication units through communication with neighboring communication modules (not shown).

The signal transmitted to the communication unit 214 may be transmitted to a central control system (not shown). In addition, each of the communication units 214 may transmit the detected detection signals to the central control system so as to determine whether a normal voltage or a normal current is supplied between the control units in the central control system.

The signal transmitted to the communication unit 214 is transmitted to the control unit 210. The signal transmitted from the communication unit 214 to the control unit 210, that is, the detection signal that detects the voltage and the current, The controller 210 determines in real time whether there is a failure due to the computation and transmits the result to an upper system. Then, the controller 210 transmits an execution command by the distribution automation algorithm (Algorithm) to the respective means.

The controller 210 determines whether the normal voltage and the current are equal to or more than a predetermined reference value and determines whether the failure has occurred, whether the voltage phase and the current phase exceed a certain range, have.

The controller 210 calculates the signal value transmitted from the sensor means provided at the front end and the rear end of the distribution line 10 to maintain the current connection state when it is determined as a normal signal. However, when it is determined that the signal is a failure signal, The motor 113 and the second upper motor 123 are operated to move the first upper pinion gear 112 and the second upper pinion gear 122 in the upward direction, The motor 126 is operated to move the first lower pinion gear 115 and the second lower pinion gear 125 downward.

The first upper ground portion 114 and the first lower ground portion 117 which are the first grounding members and the second upper ground portion 124 and the second lower ground portion 127 which are the second ground members The grounding force of the operating contact member 172 connected to the first grounding member and the second grounding member is released and separated.

When the motor 164 is rotated by the signal transmitted from the control unit 210, the driving gear 162 connected to the shaft of the motor 164 and the main gear 160 are interlocked and rotated.

The rotation connecting rod 172 coupled to the main gear 160 is rotated and the operating connecting member 172 horizontally installed at the upper end of the rotating rod 170 is rotated 90 degrees as shown in FIG. And the space between the third upper grounding part 134 and the third lower grounding part 137 and the space between the fourth upper grounding part 144 and the fourth lower grounding part 147 As shown in FIG.

At this time, the control unit 210 operates the third upper motor 133 and the fourth upper motor 143 to move the third upper pinion gear 132 and the fourth upper pinion gear 142 in the downward direction, The lower motor 136 and the fourth lower motor 146 are operated to move the third lower pinion gear 135 and the fourth lower pinion gear 145 in the upward direction.

The third upper grounding part 134 and the third lower grounding part 137 and the fourth upper grounding part 144 and the fourth lower grounding part 147 approach each other, 4 grounding member is formed so as to be minimally spaced apart, and the operation connecting member 172 is inserted and engaged in the spacing space of the third grounding member and the fourth grounding member.

The operating connecting member 172 is released from the grounding force of the first grounding member and the second grounding member while being changed in position and is electrically connected to the third grounding member and the fourth grounding member so that the sensor means S1, So that current and voltage flows of the distribution line 10 are connected through the bypass line 20. [

The control unit 210 controls the existing circuit to be disconnected through the branch circuit inside the sensor means and to be connected to the bypass circuit 20 when the bypass circuit line 20 is selected by the operation connecting member 172. [

That is, the sensor means includes a circuit for branching the normal line and the bypass line 20 therein, and selects and branches the normal line and the bypass line 20 under the control of the control unit 210.

When the failure is corrected and normalized in the power distribution line 10, the third ground member and the fourth ground member are released and separated, and the first upper ground 114 and the first lower ground 117, The first grounding member and the second grounding member are formed so as to be at least spaced apart from each other, and the operation connecting member 172 is disposed between the first grounding member and the second grounding member, And is inserted into the spacing space of the second grounding member.

6 is a view showing a configuration of a grounding member according to an embodiment of the present invention.

The grounding member according to the embodiment of the present invention includes a first grounding member of the first upper grounding unit 114 and the first lower grounding member 117, a second upper grounding member 124 and a second lower grounding member 127, The third grounding member of the third upper grounding part 134 and the third lower grounding part 137, the fourth grounding part of the fourth upper grounding part 144 and the fourth lower grounding part 147, Member.

As shown in FIG. 6, has the same shape as the first upper ground 114, the second upper ground 124, the third upper ground 134, and the fourth upper ground 144, The first lower ground portion 117, the second lower ground portion 127, the third lower ground portion 137, and the fourth lower ground portion 147 have the same shape.

The grounding member includes conductive plates 150 and 180 formed of a conductive material and bent at a predetermined angle, fixed ends 152 and 182 at one end of the conductive plates 150 and 180, And protrusions 154 and 184 protruding and formed in a semicircular shape on the other end of the conductive plates 150 and 180. The balls 156 and 186 protruded from the other end of the conductive plates 150 and 180 and the balls 156 and 186 And spring members 158, 188 connected to the spring members 158, 188.

The grounding member is configured such that the conductive plates 150 and 180 are bent at an angle to narrow one side and are in contact with the actuating connecting member 172 due to the protrusions 154 and 184 and the balls 156 and 186, And the fixing force is increased.

The embodiments of the present invention described above are not implemented only by the apparatus and / or method, but may be implemented through a program for realizing functions corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded And such an embodiment can be easily implemented by those skilled in the art from the description of the embodiments described above.

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, It belongs to the scope of right.

10: Distribution line 20: Bypass line
100: automatic opening / closing device 102: opening / closing device main body
110: first fixed support 118: first downward limiting switch
119: first upper limit switch 120: second fixed support
122: second upper pinion gear 123: second upper motor
124: second upper ground portion 125: second lower pinion gear
130: third fixed support 131: third rack gear
140: fourth fixed support 141: fourth rack gear
142: fourth upper pinion gear 143: fourth upper motor
148: Fourth downward limit switch 149: Fourth upward limit switch
150, 180: conductive plates 152, 182:
154: 184: protrusion 156: 186: ball
158, 188: spring member 160: main gear
162: drive gear 164: motor
170: rotation rod 172:
200: control device 201: control device main body
212: power supply unit 214:
216: User interface module 300: Rack gear
302: drive motor 304: pinion gear

Claims (1)

(12) is installed between the sensor means (S1) and (S2) as a part of the power distribution line (10) and is connected to the bypass line (20) And a control device (200) connected to a lower portion of the automatic opening / closing device (100) and controlling the automatic opening / closing device (100)
The control device 200 includes a control device body 201 having a predetermined space and a first through hole 202 and a second through hole 204 passing through the upper and lower surfaces of the control device main body 201, A rack gear 300 formed to extend vertically through the first through hole 202 and the second through hole 204 in a vertical direction and to be coupled with the rack gear 300, A pinion gear 304 provided on the upper surface of the main body 201 and a drive motor 302 for providing a driving force for rotating the pinion gear 304 are provided in the main body 201, A communication unit 214 receiving a measurement signal of the sensor means for detecting a voltage and a current of the communication unit 214 and transmitting the received signal value in real time, A control unit 210 connected to the control unit 210, Is charged by the power source flows to the electric wire 10, and a power supply 212 for supplying power, switching apparatus body 102 at the upper end of the rack gear 300 is connected,
The opening and closing device main body 102 has a rectangular shaped body and a driving gear 162 connected to a motor 164 on an inner bottom surface thereof and a main gear 160 engaged with the driving gear 162, A rod-shaped operation connecting member 172 vertically installed at the center of the gear 160 and rotated by the motor 164, a bar-shaped operation connecting member 172 horizontally provided at the upper end of the rotating rod 170, (110, 120, 130, 140) formed vertically upright on each inner inner side surface of the opening / closing device body (102) The rack gears 111, 121, 131, and 141 are formed with upper rack gears 111, 121, 131, and 141 and upper pinion gears 112, 122, 132, and 142, Lower pinion gears 115, 125, 135, and 145 meshed with the lower pinion gears 112, 122, 132, And lower motors 116, 126, 136 and 146, which are driving means connected to the lower pinion gears 115, 125, 135 and 145 and move up and down, Shaped upper ground portions 114, 124, 134 and 134 are formed at the ends of the upper pinion gears 112, 122, 132, and 142 and the lower pinion gears 115, 125, 135, The upper pinion gears 112, 122, 132 and 142 are moved downward by the lower limit switches 118, 128, 138 and 148, The moving distance is limited and the lower pinion gears 115, 125, 135 and 145 are moved in the upward direction and the moving distance is limited by the upper limit switches 119, 129, 139 and 149, The lower ground portions 117, 127, 137, 147 spaced downwardly from the inner surface of the opening and closing device main body 102 by a predetermined distance from the inner surface of the opening and closing device main body 102, A third grounding member and a fourth grounding member are provided on the bypass line 20 at a direction perpendicular to the power distribution line 10,
The controller 210 operates the first upper motor 113 and the second upper motor 123 to operate the first upper pinion gear 112 and the first upper pinion gear 112, The first lower pinion gear 115 and the second lower pinion gear 125 are moved in the upward direction by operating the first lower motor 116 and the second lower motor 126, The first upper pinion gear 112 and the first lower pinion gear 115 are formed with a first upper grounding portion 114 and a second upper grounding portion 112. The first upper grounding portion 114 and the second upper grounding portion 112 are formed in the longitudinal direction at the respective ends of the first upper pinion gear 112 and the first lower pinion gear 115, A second upper ground portion 124 which is the second ground member formed in the longitudinal direction at each end of the second upper pinion gear 122 and the second lower pinion gear 125, The second lower grounding portions 127 are spaced away from each other, and the rotating rod 170 is rotated by 90 degrees so that the operation connecting member 172 Is separated and separated from the space between the first upper ground 114 and the first lower ground 117 and the space between the second upper ground 124 and the second lower ground 127 A space between the third upper grounding part 134 and the third lower grounding part 137 as the third grounding member and a space between the fourth upper grounding part 144 and the fourth lower grounding part 137 as the fourth grounding member, (14), and connects the current and voltage of the distribution line (10) through the bypass line (20)
The first grounding member of the first upper grounding part 114 and the first lower grounding part 117, the second grounding member of the second upper grounding part 124 and the second lower grounding part 127, The third grounding member of the third upper grounding part 134 and the third lower grounding part 137 and the fourth grounding member of the fourth upper grounding part 144 and the fourth lower grounding part 147 are made of a conductive material A plurality of conductive plates 150 and 180 bent at a predetermined angle and fixed ends 152 and 182 at one ends of the conductive plates 150 and 180 and a semicircular protrusion Shaped protrusions 154 and 184 and balls 156 and 186 protruding from the other ends of the conductive plates 150 and 180 and connected to the balls 156 and 186 inwardly of the conductive plates 150 and 180 And a spring member (158, 188).

Images