KR101764335B1 - Voltage forecast system of electric power distribution line - Google Patents

Abstract

The present invention relates to a voltage predicting system of a distribution line, and more particularly, to a voltage predicting system of a distribution line, in which the distribution line which horizontally passes is pushed by a measurement pin installed in a vertical direction so as to measure the voltage of the distribution line while detecting a voltage signal, the measurement pin in contact with the distribution line reciprocates up and down together when the distribution line is finely shaken due to an external force from the outside so as to maintain a contact force with the distribution line without applying an impact to the distribution line, thereby preventing a contact failure between the measurement pin and the distribution line, and a wire insertion hole is blocked in order to prevent the corrosion, failure, malfunction, etc. of a current and voltage sensor unit due to moisture, etc.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voltage predicting system for electric power distribution lines,

More particularly, the present invention relates to a voltage predicting system for a distribution line, and more particularly, to a voltage predicting system for a distribution line, When the distribution line is slightly shaken by an external external force, the measuring pin contacting with the distribution line travels back and forth in the vertical direction to maintain the contact force with the distribution line without impacting the distribution line, And more particularly, to a voltage forecasting system for a distribution line to prevent corrosion or failure of the current voltage sensor unit due to moisture or the like and to prevent an operation error.

The transformer used for power distribution functions to transform the high voltage sent from the substation to a low voltage that can be used in the factory and the home.

The transformer is equipped with a load sensing system that can monitor in real time the voltage and current in the wire flowing from the transformer to the consumer, the internal temperature of the system body, and the external temperature of the transformer.

The load monitoring system includes phase current detecting means for detecting a current flowing in a wire of a transformer, phase voltage detecting means for detecting a voltage of each phase induced in a coil of the transformer, internal temperature detecting means External temperature detection means for detecting the external temperature of the transformer, and components for digitizing the detected signal and transmitting it to the central control room.

Korean Patent Registration No. 10-1627773 (Jun. 6, 2016) discloses a voltage measuring system for a distribution line.

However, in such a conventional voltage measuring system for a distribution line, it is difficult to prevent erroneous operation or malfunction of the current-voltage sensor unit, which may be caused by the inflow of moisture such as rain or the like through the wire insertion port into the body bracket, There is a problem.

Korea Patent Registration No. 10-1627773 (June 6, 2016) 'Voltage Measurement System for Distribution Line'

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a method and a device for measuring a voltage of a distribution line by detecting a voltage signal by pressing a distribution line passing horizontally through a measurement pin provided in a vertical direction , When the distribution line is slightly shaken by an external external force, the measuring pin which contacts with the distribution line travels back and forth together to maintain the contact force with the distribution line without impacting the distribution line, And to provide a system for predicting the voltage of a distribution line to prevent erosion, malfunction, and operation errors of the current voltage sensor unit due to moisture or the like by sealing the wire insertion port.

The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

The present invention is directed to a portable electronic device that includes a body bracket 101 that forms an electric wire insertion port 105 to be exposed at an upper center portion thereof and a hinge portion 102 that is connected to the upper side of the body bracket 101, And a pushing adjusting member 104 for screwing in a vertical direction at the center of the upper surface of the body bracket 101 is rotatably connected to the pushing member 104a so that the pushing member 104 The pressing member 104a is pressed to press the power line 10 placed on the wire insertion port 105 passing through the inside of the body bracket 101 to press the inside of the body bracket 101, The measuring pin 126 positioned vertically at the center of the electric wire 101a has a distal end protruding perpendicularly to the electric wire inserting port 105 so that when the electric wire 10 is pushed by the pusher 104a, So that the inside of the furnace (10) And a current voltage sensor part (100) for detecting a current signal and a voltage signal of the electric wire path (10) and transmitting the current signal and the voltage signal through a line, and the body bracket (101) One side of the coupling 106 is coupled to the lower surface of the coupling projection 106a and one side of the coupling 106 is coupled to the coupling 106 by a reciprocating movement of the lever 111, The latching frame 127 which is hooked on the bent portion 110 in a state in which the ring 106 is in contact with the bent portion 110 of the lever 111 so as to reciprocate in the same direction as the lever 111, And a first link portion 113 pivoting about a hinge 112 coupled to a lower end of the lever 111 is pivotally coupled and the first link portion 113 The second link portion 114 is formed at the lower end of the second link portion 114, And a push button 121 is coupled to a lower surface of the fixing table 120. The push button 121 is provided at a lower portion of the push button 121 with a groove 122 and the push button 121 The measuring pin 126 is urged in a downward direction when the power line 10 is shaken by an external force of the outside. And the lever 111 is moved downward so that the first link portion 113 connected to the lever 111 is reciprocated in the vertical direction while rotating about the hinge 112, The second link portion 114 coupled to the link portion 113 also reciprocates in the vertical direction so that the fixing table 120 and the push button 121 reciprocate in the vertical direction, ) To shock the distribution line (10) Wherein the electric wire is inserted into the body bracket (101) from the outside by sealing the electric wire insertion port (105) The hermetically sealed part 300 has both ends open and one end coupled to the wire insertion port 105 from the inside of the body bracket 101, An inner casing (310) through which the distribution line (10) passes; An outer casing 320 having both ends opened to be coupled to the outside of the inner casing 310; A sealing member (330) provided between the inner casing (310) and the distribution line (10); And a pressing member 340 provided between the outer casing 320 and the body bracket 101. The inner casing 310 is formed with threads on the outer circumferential surface thereof, The outer casing 320 is screwed to the inner casing 310 while being screwed to the inner casing 310 while the inner casing 310 is threaded, And the outer casing 320. The sealing member 330 is made of a tube and is expanded by air supplied from the outside so as to seal between the power distribution line 10 and the inner casing 310, And buffering a shock caused by the shaking of the power distribution line (10).

According to the present invention, when a force is applied to a measuring pin that contacts the distribution line in a vertical direction to detect a voltage signal to the distribution line, the measurement pin is reciprocated in the vertical direction, It is possible to predict the voltage of an accurate distribution line by preventing contact failure between the measurement pin and the distribution line.

Further, it is possible to seal the electric wire insertion port into which the distribution line is inserted, thereby preventing the coating of the distribution line due to moisture or the like from hardening, thereby preventing leakage and short circuit.

The effects of the present invention are not limited to those mentioned above, and other solutions not mentioned may be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a voltage predicting system for a distribution line according to the present invention.
2 is a cross-sectional view showing a configuration of a current voltage sensor unit in a voltage predicting system for a distribution line according to the present invention.
3 is a block diagram schematically showing a voltage forecasting system for a distribution line according to the present invention.
4 is a partially enlarged cross-sectional view showing a sealing part in a voltage forecasting system for a distribution line according to the present invention.
And
5 is a front view showing an outer casing in a voltage predicting system for a distribution line according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. And should not be construed as limited to the embodiments described herein.

Since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein.

It should be understood that the embodiments according to the concept of the present invention are not limited to the particular mode of disclosure but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

Since the present invention uses the later-described prior art 1627773 as it is, all of the features of the device configuration described below can be understood as those described in the registered patent No. 1627773. [

However, in the present invention, the 'distribution line voltage measurement system' among the configurations disclosed in the above-mentioned Japanese Patent No. 1627773 is replaced with 'distribution line voltage estimation system' and further includes a structure for sealing the wire insertion port and a description of its operation This is the most essential configuration feature.

Therefore, the device structure, characteristics, and operation relationship described below will be incorporated by reference in the above-mentioned Japanese Patent No. 1627773, and the structure related to the main features of the present invention will be described in detail at the rear end.

The voltage forecasting system for a distribution line according to the present invention includes a current voltage sensor unit 100 and a power quality measurement unit 200.

The current voltage sensor unit 100 includes a body bracket 101 which forms an electric wire inserting opening 105 so as to be exposed at an upper center portion thereof and a hinge portion 102 which is connected to the upper side of the body bracket 101 to be opened and closed , A pushing adjuster 104 which is screwed vertically to the center of the upper surface of the body bracket 101 is rotatably connected to the pusher 104a so that the pusher 104 is pushed 104a can press-fit the power line 10 placed in the wire insertion port 105 passing through the inside of the body bracket 101 by pressing.

The body bracket 101 is fastened to a fastening hole (not shown) through a fastening locking hole 103 provided on the other side so that the upper part of the body bracket 101 is locked.

The measuring pin 126 positioned vertically at the center of the inner space 101a of the body bracket 101 is positioned such that its distal end protrudes perpendicularly to the wire inserting port 105 so that the power distributing line 10 is pushed by the pusher 104a, The distribution line 10 is brought into contact with the measurement pin 126 when it is pressed.

In this state, when the push button 104 located at the upper center of the body bracket 101 is turned, the pushing-out port 104a is lowered to push the power distribution line 10 placed on the wire insertion port 105, The measuring pin 126 protruding from the bottom of the wire insertion port 105 is brought into contact with the inside of the distribution line 10.

The information (current signal, voltage signal) measured by the measuring pin 126 in contact with the power distribution line 10 is transmitted to the current signal converting section 130 and the voltage signal converting section 132 through a line do.

The body bracket 101 has a column 12 vertically erected on the lower surface thereof and a power quality measuring unit 200 is provided on one side of the column 12. [

The power quality measuring unit 200 receives and stores the power information including the voltage and the current from the current voltage sensor unit 100 by radio communication and compares the measured power information with the preset reference measurement value and then transmits the measurement data included in the reference measurement value To the external system.

2, the current-voltage sensor unit 100 includes a fastening protrusion 106a coupled to a lower surface of the measurement pin 126, and a coupling 106 is formed on a lower surface of the fastening protrusion 106a. .

One side of the coupling 106 is engaged with the bent portion 110 of the lever 111 such that the coupling 106 reciprocates in the same direction as the lever 111 in accordance with the reciprocating movement of the lever 111, The latching frame 127 which is hooked to the coupling portion 110 is formed to be longer in the horizontal direction than the opening of the coupling 106.

On the lower surface of the coupling 106, a vertical bar 107 is elongated in the vertical direction and a spring member 108 is coupled around the vertical bar 107.

A first link part 113 pivoted about a hinge 112 coupled to a lower end of the lever 111 is pivotally coupled and a second link part 113 vertically installed from one end of the first link part 113, (114).

The second link portion 114 has a fixing base 120 having a predetermined thickness formed in a horizontal direction at a lower end thereof.

When the power distribution line 10 is shaken by an external force such as wind, the measuring pin 126 is forced downward and the lever 111 moves downward, And the second link portion 114 coupled to the first link portion 113 also reciprocates in the vertical direction together with the hinge 112. [

Therefore, the fixing table 120 coupled to the lower end of the second link portion 114 receives a certain amount of downward force.

A push button 121 is coupled to the lower surface of the fixing table 120 and a flexible elastic member such as a rubber material supporting the lower portion of the push button 121 A corrugated buffer member 123 is provided. A lower part of the push button 121 is supported by a support base 124 which is connected to the push button 121 in the vertical direction and has a buffer member 123 fitted on the outer periphery thereof and a support base 124 which supports the support base 124, (125).

When the fixing table 120 receives a force in the up-and-down direction, the push button 121 reciprocates in the vertical direction by the buffer member 123 to perform buffering action.

When the power distribution line 10 is shaken by an external external force such as wind or the like, the measurement pin 126 is positioned so that the labyrinth 111, the first link portion 113, the second link portion 114, So as to maintain a contact force with the power distribution line 10 without giving a shock to the power distribution line 10.

3, the current-voltage sensor unit 100 is configured such that the information (current signal, voltage signal) measured (detected) by the measuring pin 126 passes through a line (not shown) 1 voltage is received and converted into a second voltage, the first current is received and converted into a second current, and the signal is transmitted through wireless communication by signal processing using the converted second voltage and the second current. The current voltage sensor unit 100 includes a current signal converter 130, a voltage signal converter 132, a main power unit 134, and a sensor controller 140.

The current signal converter 130 receives the first current of the wiring line 10 through a line (not shown) and detects a current signal measured (detected) by the measuring pin 126, The current is converted into a second current proportional to a voltage change amount at a constant rate using a coil. The current signal converter 130 converts the first current into a second current, which is different from the first current, and converts the first current into a second current, which is changed by a predetermined amount of voltage change.

The voltage signal converter 132 receives the first voltage of the wiring line 10 through a line (not shown) and converts the voltage signal measured by the measuring pin 126 into a second voltage do.

The main power supply unit 134 uses the induced electromotive force to change the first voltage to a constant voltage and power amount to supply the main power.

Here, the main power supply unit 134 may use the induced electromotive force to change the first voltage to a constant voltage and power amount, store it in the large capacity condenser, and use it as the main power source.

The sensor control unit 140 receives the main power supplied from the main power unit 134 and converts the main power into the operation power and supplies the second voltage from the second current and voltage signal conversion unit 132 from the current signal conversion unit 130 Receives signals, and transmits them through wireless communication. The sensor control unit 140 includes a charging unit 142, a first signal processing unit 144, and a wireless communication transmission unit 146.

The charging unit 142 receives the main power supplied from the main power unit 134, converts the main power into operating power, stores the converted power, and supplies the operating power. The charging unit 142 converts an AC power source, which is a DC power source for driving the sensor controller 140 (PCB controller), to an internal capacitor (not shown) by using a main power source, which is AC input power supplied through the main power unit 134, .

The first signal processing unit 144 receives the operating voltage from the charging unit 142 and receives the second voltage from the second current and voltage signal converting unit 132 from the current signal converting unit 130. The first signal processing unit 144 measures .

The wireless communication transmission unit 146 transmits the second current and the second voltage, which have been measured, analyzed, and signal processed, to the power quality measurement unit 200 using wireless communication.

The power quality measuring unit 200 receives the second voltage and the second current from the current voltage sensor unit 110 through wireless communication and compares the measured values of the second voltage and the second current with the reference measured value, To the centralized system not shown in detail in the attached drawings using wireless communication.

The power quality measuring unit 200 includes a control power supply unit 210, a field control unit 211, a data storage unit 212, a signal display unit 213, a voltage current input unit 214, a second signal processing unit 215, And a central communication transmission unit 220.

The control power supply unit 210 supplies a main power for operating the power quality measurement unit 200. The control power supply unit 210 may convert AC power to DC power for a main power source for operating the power quality measurement unit 200 as a power supply unit.

The field operation unit 211 can receive the main power from the control power supply unit 210 and operate the power quality situation on the field.

At least one of the field operating units 211 is disposed, and in case of setting in the field for a power quality situation, the user can set the user through a button and a signal display unit 213 (LCD) to be described later.

The data storage unit 212 stores a measurement value, a reference measurement value, and measurement data for the second voltage and the second current transmitted from the current voltage sensor unit 110. The data storage unit 212 stores the measurement values, reference measurement values, and measurement data for the second voltage and the second current in real time, and may store the measurement values separately when a specific event occurs.

The signal display unit 213 displays the measurement value, the reference measurement value and the measurement data for the second voltage and the second current in the field so that the set value can be changed.

The voltage and current input unit 214 is electrically connected to the signal display unit 213 and changes the range of the reference measurement value according to the surrounding environment. The voltage and current input unit 214 may be configured as a separate module so that the voltage and current input unit 214 can be selected according to the type and the number and the range of the voltage and the current. Also, the voltage / current input unit 214 changes the range of the reference measurement value, and can perform A / D conversion sampling processing for a predetermined period.

The second signal processing unit 215 calculates and processes the range of the reference measurement value changed and set in the voltage and current input unit 214 and determines whether the calculated reference measurement value falls within the range of the reference measurement value.

In addition, the second signal processing unit 215 can determine whether the result to be calculated is within the range of the set reference measurement value or not.

The central communication transmission unit 220 transmits only the measurement data included in the reference measurement value set through the voltage current input unit 214 and the second signal processing unit 215 to the centralized system using wireless communication. The central communication transmission unit 220 may include a local communication processing unit 222 and a remote communication processing unit 224.

The local communication processing unit 222 converts the measurement data included in the reference measurement value and transmits the measurement data to the central system.

The remote communication processing unit 224 transmits the measurement data in accordance with the communication protocol required by the central system. The remote communication processing unit 224 transmits a response according to a periodic request according to a communication protocol requested by the central system, but can notify in advance that it is an emergency when an event occurs even in the absence of a response.

In the present invention, the configuration of the sealing part 300 for sealing the wire insertion port 105 is further realized, as shown in FIGS. 4 to 5, including the above-described configuration.

The sealing part 300 is provided for preventing corrosion or malfunction of the current voltage sensor part 100 which may be generated when moisture such as rain or the like is introduced into the body bracket 101 through the wire inserting opening 105, .

The hermetically sealed part 300 includes an inner casing 310 having both ends opened and one end coupled to the wire insertion port 105 from the inside of the body bracket 101 and passing the distribution line 10 inward, A sealing member 330 provided between the inner casing 310 and the distribution line 10 and an outer casing 320 provided between the outer casing 320 and the body bracket 101, And a pressing member 340.

The wire insertion port 105 has a diameter enough to accommodate the inner and outer casing 310 and the sealing member 330 and the wire insertion port 105 penetrates the front and rear surfaces of the body bracket 101 It can be understood that the sealing portion 300 is provided on the front and rear portions of the body bracket 101, respectively.

The inner casing 310 is in the form of a circular tube having open ends at both ends and is contacted with the inner side surface of the body bracket 101 while forming a release preventing jaw 311 extending outward at the other end.

The inner casing 310 may be formed by wrapping around the power distribution line 10 while branching the power distribution line 10 around the power distribution line 10.

This is for the purpose of facilitating the connection to the distribution line 10.

The outer casing 320 is in the form of a circular tube having open ends at both ends and a flange 321 extending outward at the other end is formed to press the pressing member 340.

Preferably, the inner casing 310 is threaded on the outer circumferential surface, and the outer casing 320 is threadably coupled to the inner casing 310 while being threaded on the inner circumferential surface.

The outer casing 320 may be coupled to each other by a fastener 323 including a bolt and a nut while branching to a pair of outer casing units 322 around the distribution line 10 as shown in FIG. have.

This is for the purpose of facilitating the connection to the distribution line 10.

The pressing member 340 is in the form of a disk ring made of silicone or rubber and is pressed against the outer casing 320 while being screwed to the inner casing 310 to seal the body bracket 101 and the outer casing 320 Lt; / RTI >

The body bracket 101 can be opened while the outer casing 320 is being released and rotated and the outer casing 320 is tightened and rotated together with the body bracket 101 being closed so that the binding state of the inner and outer casings 310, Can be maintained.

The sealing member 330 is made of a tube and is inflated by compressed air supplied from the outside to seal between the power distribution line 10 and the inner casing 310 and to absorb the impact generated by the fluctuation of the power distribution line 10 It is preferable to buffer.

That is, the sealing member 330 is coupled between the power distribution line 10 and the inner casing 310 while being in the form of a donut made of a rubber material, and is supplied with compressed air from a device for supplying compressed air, for example, And airtightly seals between the distribution line 10 and the inner casing 310 while being expanded.

When the distribution line 10 is swung by the external force from the expanded state, the sealing member 330 prevents the shock from being transmitted to the distribution line 10 while buffering the external force.

Further, the sealing member 330 prevents a short circuit or the like which may be generated when the covering of the distribution line 10 is peeled off by the contact with the circumference forming the wire inserting opening 105.

Therefore, the sealing part 300 can be used to seal or break the electric current voltage sensor part 100, which may be generated when moisture is introduced into the inside of the body bracket 101 by sealing the electric wire inserting opening 105, Can be prevented.

100: voltage current sensor unit 101: body bracket
110: bending section 120:
123: buffer member 126: measuring pin
200: power quality measuring unit 300: sealing unit
310: inner casing 311:
320: outer casing 321: flange
330: sealing member 340: compression member

Claims (1)

A body bracket 101 for forming a wire insertion port 105 to be exposed at an upper center portion of the body bracket 101 and a hinge portion 102 connected to the upper side of the body bracket 101 to be opened and closed, A pressing member 104 is screwed vertically onto the center of the upper surface of the upper surface of the pressing member 104 so that the pressing member 104 is rotatably connected to the pressing member 104a, And is press-fitted into a power line 10 placed on a wire insertion port 105 passing through the inside of the body bracket 101,
A measuring pin 126 positioned vertically at the center of the inner space 101a of the body bracket 101 is formed such that its distal end is vertically protruded from the wire insertion port 105, And a current voltage sensor unit (100) which is brought into contact with the inside of the distribution line (10) when pressed by the control unit (104a) to detect a current signal and a voltage signal of the distribution line (10) ,
The body bracket 101 has a fastening protrusion 106a coupled to a lower surface of the measurement pin 126 and a coupling 106 is coupled to a lower surface of the fastening protrusion 106a And one side of the coupling 106 is in contact with the bent portion 110 of the lever 111 so that the coupling 106 reciprocates in the same direction as the lever 111 in accordance with the reciprocating movement of the lever 111 The latching frame 127 is formed to be longer than the opening of the coupling 106 in the horizontal direction and is pivoted about the hinge 112 coupled to the lower end of the lever 111 And a second link portion 114 vertically erected from one end of the first link portion 113. The second link portion 114 is formed at a lower end of the first link portion 113, A fixed base 120 having a predetermined thickness is formed in a horizontal direction, a push button 121 is coupled to a lower face of the fixed base 120, A bellows cushioning member 123 having a soft elasticity and supporting a lower portion of the pushbutton 121 is provided at a lower portion of the base pushbutton 121, The measuring pin 126 is pressed downward and the lever 111 is moved downward so that the first link part 113 connected to the lever 111 is moved in the downward direction, The second link portion 114 coupled to the first link portion 113 is also reciprocally moved upward and downward to thereby reciprocate in the vertical direction while rotating about the hinge 112, And the pushbutton 121 reciprocate in the vertical direction to perform buffering action by the buffer member 123 to maintain a contact force with the distribution line 10 without impacting the distribution line 10 Characteristics of a distribution line voltage prediction system As a result,
And a hermetically sealed part (300) for hermetically closing the wire insertion port (105) to prevent moisture from flowing into the inside of the body bracket (101) from the outside,
The hermetically sealed part (300)
An inner casing (310) having both ends opened and one end coupled to the electric wire insertion port (105) from the inside of the body bracket (101) and passing the distribution line (10) inward;
An outer casing 320 having both ends opened to be coupled to the outside of the inner casing 310;
A sealing member (330) provided between the inner casing (310) and the distribution line (10); And
And a pressing member (340) provided between the outer casing (320) and the body bracket (101)
The inner casing (310)
A thread is formed on the outer peripheral surface,
The outer casing (320)
A screw thread is formed on the inner circumferential surface and is screwed to the inner casing 310,
The pressing member (340)
As the outer casing 320 is screwed to the inner casing 310, the outer casing 320 is compressed while being tightly sealed between the body bracket 101 and the outer casing 320,
The sealing member (330)
And is inflated by the air supplied from the outside to seal the gap between the power distribution line 10 and the inner casing 310 while buffering the impact caused by the shaking of the power distribution line 10 Voltage distribution system.

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