KR102099186B1 - Safety system for maintenance work of distribution line - Google Patents

Abstract

The present invention relates to a safety system during maintenance work of a distribution line, and more specifically, to a safety system during maintenance work of a distribution line which measures current and voltage in the distribution line at all times, and when overcurrent is energized in the distribution line due to causes of failure and the like, failure information is transmitted to a reception device or an intermediate information collector of a central control room to perform the maintenance work while inspection or maintenance work for the inside of a case is stably performed.

Description

Safety system for maintenance work of distribution lines {SAFETY SYSTEM FOR MAINTENANCE WORK OF DISTRIBUTION LINE}

The present invention relates to a safety system during maintenance work of a distribution line in the field of distribution technology, and more specifically, to measure the current and voltage of the distribution line at all times and to fail when an overcurrent is applied to the distribution line due to a cause such as a failure. It is related to a safety system during maintenance work of a distribution line to transmit information to a receiving device or an intermediate information collector in the central control room to perform maintenance work, and to inspect or repair the inside of the case stably.

In general, electricity is a power source having a great influence on industrial and daily life, and is usually supplied to users through substations in power plants.

At this time, a telephone pole is installed to supply electricity from the substation to the final consumer, such as a factory or house, and power is supplied by installing a distribution line on the telephone pole.

A high-voltage current flows through the distribution line installed on the telephone pole, and the distribution line is connected like a net.

However, substations or electrical supply protection devices when insulation of distribution lines is destroyed due to obsolescence of appliances such as telegraphist insulators that fix distribution lines connected in such a complicated structure, burnout by lightning, or contact with trees or birds, etc. When a power failure occurs due to the operation of a switch such as a switch to cut off the electricity supply, the operation of industrial equipment is stopped, and the operation of household appliances such as refrigerators in the home is stopped, causing enormous damage. Rapid repair work should be done within a short time.

Nevertheless, at present, there is no way to quickly identify where the overcurrent has flowed due to the destruction of insulation in a distribution line that is widely distributed like a net because the search for the failure point of the distribution line is not automatically performed. It takes a lot of time to find a branch.

As a prior art that partially improves these problems, Korean Patent Registration No. 10-1840033 (2018.03.19.) Discloses an 'automation system for distribution lines'.

However, such a conventional automation system of a distribution line has a problem that it is difficult to carry out inspection or maintenance work on the inside of the case.

Republic of Korea Patent Registration No. 10-1840033 (2018.03.19.) 'Automation system of distribution lines'

The present invention was devised to solve the above-mentioned problems, and the object of the present invention is to measure the current and voltage of the distribution line at all times, and to control the failure information when the overcurrent is energized on the distribution line due to a cause such as a failure. It is to provide a safety system during maintenance work of the distribution line so that the maintenance work can be performed stably by checking the inside of the case or sending it to the receiving device or the intermediate information collector.

The problem to be solved of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention is a case 110 through which the through hole 110a through which the distribution line 1 passes is formed; An iron core 120 provided in the case 110 and surrounding the distribution line 1 passing through the through hole 110a; An induction coil 130 wound around the iron core 120 to generate an induction current by electromagnetic induction when the distribution line 1 is energized; A current sensing unit 140 measuring a current induced in the induction coil 130; A control unit 160 that generates fault information when the current measured through the current sensing unit 140 is an overcurrent; A signal transmitting unit 170 transmitting the fault information generated by the control unit 160 to the central control room 200 or the intermediate information collector 220 connected to the central control room 200; A power supply unit 180 that supplies driving power of the control unit 160; And a voltage sensing unit 150 for measuring the voltage induced in the induction coil 130, and the control unit 160 includes constant current measured by the current sensing unit 140 and the voltage sensing unit 150. And a voltage transmitter outputting voltage information to the signal transmitter 170, and the signal transmitter 170 converting the failure information output from the controller 160 into a radio signal and a radio transmitter module 172. In the maintenance system of the distribution line consisting of the antenna 174 transmitted to the receiving device 210 or the intermediate information collector 220 of the central control room 200, in the safety system, check or repair the inside of the case 110 Further comprising a check unit 300 to make the work is done, the check unit 300, the support plate 310 disposed under the case 110; Support means (320) for supporting the support plate (310) from the distribution line (1); It includes a mounting means 330 for supporting the case 110 from the support plate 310, the support means 320, the hook 321a is formed on the upper portion so as to be adjacent to both ends of the case 110 A support bar 321 coupled to the distribution line 1 and having a lower portion passing through the support plate 310; A support ring 322 provided below the support bar 321; A support member 323 supporting the support ring 322 while being screwed to the support bar 321; And a spring 324 coupled to the outside of the support bar 321 so as to be positioned between the support plate 310 and the support ring 322, wherein the spring 324 lowers the support ring 322. While pressing in the direction so that the hook (321a) is in close contact with the power distribution line (1), the support member (323), characterized in that to adjust the elastic force of the spring 324 while being raised and lowered according to rotation A safety system is provided for maintenance work of distribution lines.

According to the present invention, first, by measuring the failure information of the distribution line and transmitting current and voltage, etc. of the distribution line that the transmission device supplies electricity in real time, and notifying it to the central control room, during the overcurrent and overvoltage caused by the failure In the event of an occurrence, it is possible to shorten the maintenance work time of the distribution line as the place of occurrence is immediately identified.

Second, by using the electromagnetic induction method to secure the driving power from the distribution line, there is an effect that can be driven independently and semi-permanently without receiving a separate power supply.

Third, it is possible to stably inspect or repair the inside of the case.

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

1 is a perspective view showing a safety system during maintenance work of a distribution line according to the present invention.
2 is a longitudinal sectional view showing a safety system during maintenance work of a distribution line according to the present invention.
FIG. 3 is a longitudinal sectional view of line AA of FIG. 1.
4 is a block diagram showing a safety system during maintenance work of a distribution line according to the present invention.
5 is a use state diagram showing a safety system during maintenance work of a distribution line according to the present invention.
6 is a side view showing a state in which the inspection unit is provided in the safety system during maintenance work of the distribution line according to the present invention.
7 is a front view showing a state in which the inspection unit is provided in the safety system during maintenance work of the distribution line according to the present invention.
And
8 is a front view showing a state in which the pressing member is provided in FIG. 7.

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

Referring to Figures 1 to 5, the safety system (hereinafter referred to as "safety system") 100 during the maintenance work of the distribution line according to the present invention (100) of the distribution line (1) which is a wire supplying a high voltage of 22,900V Current and voltage are measured at all times, and when overcurrent is applied to the distribution line (1), failure information can be transmitted to the receiving device (210) or the intermediate information collector (220) of the central control room (200) in real time to quickly recover. To let you know.

It can be understood that the distribution line 1 is mounted on the insulator 30 as an insulating material on the support 20 installed on the support structure 10 including a pylon or a telegraph pole, and is hypothesized.

The safety system 100 according to the present invention includes a case 110 in which a through hole 110a through which the distribution line 1 passes is formed, and a distribution line passing through the through hole 110a in the case 110. The iron core body 120 provided to surround the furnace 1 is wound around the iron core body 120, and when electricity is energized through the distribution line 1, an induction coil 130 that generates an induction current by electromagnetic induction , The current sensing unit 140 for measuring the current induced in the induction coil 130, the voltage sensing unit 150 for measuring the voltage induced in the induction coil 130, the current sensing unit 140 If the current measured through is overcurrent, the control unit 160 that generates fault information, and transmits the fault information generated by the control unit 160 to the receiving device 210 or the intermediate information collector 220 of the central control room 200. It consists of a signal transmission unit 170 and a power supply unit 180 for supplying the driving power of the control unit 160.

The case 110 is formed in a cylindrical shape as a whole, and is formed with a through hole 110a through which the distribution line 1 penetrates in the center, so that it is easy to install at an arbitrary position of the previously installed distribution line 1 , It is preferably made of a structure divided into two cases (112,114).

At this time, when fastening the first and second cases 112 and 114, the first and second cases 112 and 114 are formed using a tie band 116 made of metal as a fastening means so as to be securely fixed to the distribution line 1. Will tighten.

Instead of using the tie band 116, the first and second cases 112 and 114 are integrally fastened using a fastening means (not shown) such as bolts and nuts, or a loop-shaped fastener is used. It is also preferable to directly attach to the distribution line 1 by using.

On the other hand, the inside of the case 110 is provided with an iron core 120, the iron core 120 is also divided into two first and second iron cores (122,124) in the first and second cases (112,114) Each is provided to surround the distribution line 1, and an induction current is generated when the induction coil 130 is wound on one side of the iron core 120 so that the distribution line 1 is energized.

The control unit 160 provided inside the case 110 compares whether it is overcurrent when the current information is input from the current sensing unit 140 measuring the current of the induction coil 130, and if it is overcurrent, unique information of the device Fault information including (for example, device number and installation location information) is generated and output.

The control unit 160 always senses the current through the current sensing unit 140 and senses the voltage through the voltage sensing unit 150 to include unique information (for example, device number and installation location information). The information is transmitted to the receiving device 210 or the intermediate information collector 220 of the central control room 200 at regular time intervals to inform the operating state.

The current sensing unit 140 converts an analog-type induced current value into digital-type current information, and the voltage sensing unit 150 converts an analog-type induced voltage value into digital-type voltage information to control the controller ( 160), and the controller 160 determines whether or not it is overcurrent by using digital current and voltage information.

The control unit 160 is preferably configured as a microcomputer having an internal memory storing fault information and always-information information including unique information (for example, device number and installation location information).

On the other hand, the signal transmission unit 170 for transmitting the failure information generated by the control unit 160 to the receiving device 210 or the intermediate information collector 220 of the central control room 200 is implemented in various ways, such as wired or wireless It may be, but the wireless method is used in consideration of the ease of installation.

The signal transmission unit 170 converts the failure information and the normal information output from the control unit 160 into a wireless signal, and the wireless transmission module 172 and the failure information and the constant information of the wireless transmission module 172 in the central control room 200 ) Consists of an antenna 174 that transmits wirelessly to the receiving device 210 or the intermediate information collector 220.

At this time, the wireless transmission module 172 is GSM, CDMA, IMT 2000, WiBro, wireless TRS, UHF, VHF to transmit fault information and always information to the receiving device 210 of the central control room 200 located at a remote location. , AM, FM and other commercially available long-distance communication modules are used.

In addition, the wireless transmission module 172 is a Bluetooth (to transmit fault information and always information to the intermediate information collector 220 that is located at a short distance and transmits information to the receiving device 210 of the central control room 200, etc. Blue tooth), ZIPBee, etc. are used for modules capable of short-range communication.

The antenna 174 may be embedded inside the case 110, but is preferably configured to be smoothly transmitted by being exposed to the outside.

The power supply unit 180 that supplies the driving power of the control unit 160 is made of a rechargeable battery 182. The rechargeable battery 182 serves to charge the induced current generated in the induction coil 130.

Since the charging power of the rechargeable battery 182 may not be suitable as the driving power of the controller 160, it is preferable to further include a constant voltage IC and a DC / DC converter for stable power supply, and such constant voltage IC and DC / The configuration of the DC converter is a general known configuration.

By charging the rechargeable battery 182 of the power supply unit 180 with a current induced in the induction coil 130 by such a configuration and supplying it as a driving power supply of the control unit 160, it is driven semi-permanently even without a separate power supply. It will be able to supply power.

Hereinafter, an operation process of the safety system 100 according to the present invention will be described in detail with reference to FIGS. 1 to 5.

First, the safety system 100 according to the present invention is installed on the distribution line 1, and when electricity is applied to the distribution line 1, the iron core 120 is magnetized and thereby induced to the induction coil 130. Current is generated.

When an induction current is generated in the induction coil 130, power is charged to the rechargeable battery 182 constituting the power supply unit 180, and the control unit 160 is driven by the rechargeable battery 182 power.

The control unit 160 receives induction current and voltage information sensed through the current sensing unit 140 and the voltage sensing unit 150.

The control unit 160 compares whether the current information exceeds the set allowable current from the current sensing unit 140 measuring the current of the induction coil 130, and when the allowable current is exceeded, the overcurrent on the distribution line 1 It is judged as energized, and fault information including unique information such as a device number and an installation location is generated and output.

The failure information generated by the control unit 160 is converted into a wireless signal in real time through the wireless transmission module 172 constituting the signal transmission unit 170, and the receiving device of the central control room 200 through the antenna 174 It is transmitted wirelessly to the 210 or the intermediate information collector 220.

The control unit 160 wirelessly transmits the constant information of voltage and current values to the receiving device 210 or the intermediate information collector 220 of the central control room 200 in real-time or at regular time intervals even when it is not a malfunction.

In this case, when the failure information is transmitted to the receiving device 210 of the central control room 200 or the intermediate information collector 220 connected to the receiving device 210, the central control room 200 confirms the installation location of the device through the failure information. Then, the manpower is promptly input to perform maintenance work on the distribution line (1).

Even in the case of a failure state in which no electricity is supplied to the distribution line 1, the safety system 100 according to the present invention is independently operated for a certain period of time by using the power of the rechargeable battery 182, so that It is possible to transmit fault information, so stable signal transmission is possible.

The safety system 100 according to the present invention further includes an inspection unit 300 to smoothly inspect or repair the inside of the case 110 as illustrated in FIGS. 6 to 8.

The inspection unit 300 allows the inside of the case 110 to be inspected or repaired while the case 110 is stably supported by the power distribution line 1.

That is, in the case of separating the tie band 116 for checking or repairing the inside of the case 110, the inspection unit 300 falls as the first and second cases 112 and 114 are separated from the distribution line 1 Prevent it.

The inspection part 300 supports the support plate 310 disposed under the case 110, support means 320 supporting the support plate 310 from the distribution line 1, and the case 110 from the support plate 310. It includes a mounting means 330.

The support plate 310 forms a square plate in which both ends are formed to extend in the longitudinal direction of the distribution line 1 and is disposed under the case 110.

The support means 320 is formed with a hook 321a at the upper portion, coupled to the distribution line 1 so as to be adjacent to both ends of the case 110, and the support bar 321 and the support bar through which the lower portion passes through the support plate 310 ( The support ring 322 provided on the lower portion of the 321, while being screwed to the support bar 321, is positioned between the support member 323 and the support plate 310 and the support ring 322 supporting the support ring 322. It includes a spring 324 coupled to the outside of the support bar (321).

The hook 321a is coupled to the distribution line 1 while forming a shape such as '∩' in which the lower part is opened, and may be formed while the upper part of the support bar 321 is bent downward.

The support bar 321 may be made of an insulating material, or only the hook 321a may be coated with an insulating material.

The spring 324 is contracted as the hook 321a of the support bar 321 is pulled upward, so that the hook 321a is smoothly coupled to the distribution line 1.

In addition, the spring 324 presses the support ring 322 from the support plate 310 downward so that the hook 321a is in close contact with the distribution line 1.

The support bar 321 is screwed to the lower outer circumferential surface, and the support member 323 is screwed to the lower outer side of the support bar 321 while a thread is formed on the inner circumferential surface.

The support member 323 allows the hook 321a to be in close contact with the power distribution line 1 as it moves up and down as it rotates, or to be disengaged.

Accordingly, the support member 323 is to ensure that the hook (321a) is in close contact with the distribution line (1) in accordance with the rotation, or to ensure that the inspection unit 300 is coupled to the distribution line (1), or to be separated while being in close contact You can.

That is, the inspection unit 300 is coupled to the distribution line 1 when it is necessary to inspect or repair the inside of the case 110, and after the inspection of the interior of the case 110 is completed, the distribution line It is separated from the furnace 1.

Mounting means 330 is mounted on the bottom of the case 110, the mounting plate 331, the upper is fixed to the mounting plate 331, the lower mounting bar 332 through which the support plate 310, the mounting bar 332 ) A spring 334 coupled to the outside of the mounting bar 332 so as to be positioned between the supporting member 310 and the mounting plate 331 and the supporting plate 310 so as to be able to move up and down to the supporting plate 310. .

The mounting plate 331 is made of the same curved plate as the lower surface of the case 110, it is preferable that the contact with the case 110 is made stable.

The mounting plate 331 may be provided with a contact member 335 on the upper surface.

The contact member 335 may be made of silicone or rubber, and prevents the sliding between the mounting plate 331 and the case 110 so that the case 110 can be stably mounted on the mounting plate 331.

Spring 334 is when the mounting plate 331 is coupled to the lower portion of the case 110, the mounting plate 331 is lowered as it contracts by pressing the case 110 in the downward direction and coupled to the lower portion of the case 110 As possible.

In addition, the spring 334 may press the mounting plate 331 upward from the support plate 310 so that the mounting plate 331 is in close contact with the case 110.

The mounting bar 332 is formed with a screw thread on the outer circumferential surface, and the adjusting member 333 is screwed to the outside of the mounting bar 332 with a screw thread formed on the inner circumferential surface.

The adjustment member 333 prevents the mounting bar 332 from being detached from the support plate 310 by the pressure of the springs 324 and 334.

The adjusting member 333 allows the mounting bar 332 to rise and fall according to rotation, so that the mounting plate 332 is in close contact with the case 110 or is spaced apart.

Mounting means 230 may further include a pressing member 336 to adjust the elastic force of the spring 334 according to the rotation of the adjusting member 333.

The pressing member 336 includes a pressing ring 338 positioned in the lower portion of the spring 334 and a pressing pipe 338 contacting the adjusting member 333 while extending downward from the inner circumferential surface of the pressing ring 337 .

The pressing member 336 can be adjusted up and down together when the adjusting member 333 rotates, thereby properly adjusting the elastic force of the spring 334.

For this reason, when the inspection unit 300 separates the tie band 116 from the first and second cases 112 and 114 for inspection or maintenance work on the inside of the case 110, the first and second cases 112 and 114 A can be prevented from falling while being separated from the distribution line (1), as well as the case 110 is stably supported on the distribution line (1) to check or repair the inside of the case 110 to be made can do.

What has been described above is only an embodiment for implementing a safety system during maintenance work of a distribution line according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the following claims Anyone who has ordinary knowledge in the field to which the present invention belongs, without departing from the gist of the invention, will have the technical spirit of the present invention to the extent that various changes can be made.

1: Distribution line 10: Support structure
20: Support 30: Agile
100: safety system 200: central control room
300: inspection part 310: support plate
320: support means 321: support bar
322: support ring 323: support member
324: spring 330: mounting means
331: mounting plate 332: mounting bar
333: adjusting member 334: spring
335: contact member 336: pressing member

Claims (1)

A through hole 110a through which the distribution line 1 penetrates is formed, and is divided into first and second cases 112 and 114, and the case 110 fixed to the distribution line 1 by a tie band 116;
An iron core 120 provided in the case 110 and surrounding the distribution line 1 passing through the through hole 110a;
An induction coil 130 wound around the iron core 120 to generate an induction current by electromagnetic induction when the distribution line 1 is energized;
A current sensing unit 140 measuring a current induced in the induction coil 130;
A control unit 160 that generates fault information when the current measured through the current sensing unit 140 is an overcurrent; And
Safety at the time of repair work of the distribution line including the signal transmission unit 170 that transmits the failure information generated by the control unit 160 to the central control room 200 or the intermediate information collector 220 connected to the central control room 200 In the system,
When the case 110 is stably supported on the power distribution line 1, when the tie band 116 is separated by checking or repairing the inside of the case 110, the first and second parts are separated. Case 112, 114 further includes a check unit 300 to prevent falling while being separated from the distribution line (1),
The check unit 300,
A support plate 310 disposed under the case 110;
Support means (320) for supporting the support plate (310) from the distribution line (1);
It includes a mounting means 330 for supporting the case 110 from the support plate 310,
The support means 320,
Hooks (321a) are formed on the upper portion is coupled to the distribution line (1) so as to be adjacent to both ends of the case 110, the lower support bar 321 through the support plate 310;
A support ring 322 provided below the support bar 321;
A support member 323 supporting the support ring 322 while being screwed to the support bar 321; And
It includes a spring 324 coupled to the outside of the support bar 321 to be located between the support plate 310 and the support ring 322,
The spring 324,
The hook 321a is contracted by pulling upward, so that the hook 321a is coupled to the distribution line 1 or is detachable from the distribution line 1, and the hook 321a is connected to the distribution line After being combined with (1), the support ring 322 is pressed downward so that the hook 321a is in close contact with the distribution line 1,
The support member 323,
The hook 321a is brought into close contact with the distribution line 1 as it moves up and down according to rotation, or is disengaged from contact.
The mounting means 330,
A mounting plate 331 disposed under the case 110;
A mounting bar 332 having an upper portion fixed to the mounting plate 331 and a lower portion passing through the supporting plate 310;
Adjusting member 333 that is screwed to the lower outer side of the mounting bar 332 to connect the mounting bar 332 to the support plate 310 so as to be elevated and lowered; And
The mounting plate 331 is coupled to the outside of the mounting bar 332 so as to be positioned between the mounting plate 331 and the supporting plate 310, thereby pressing the mounting plate 331 upward from the supporting plate 310 so that the mounting plate 331 A spring 334 to be in close contact with the case 110; And
It includes a pressing member 336 to adjust the elastic force of the spring 334 according to the rotation of the adjusting member 333,
The spring 334,
The mounting plate 331 is pressed upward from the support plate 310 so that the mounting plate 331 is in close contact with the case 110,
The pressing member 336,
A pressure ring 337 located at the lower portion of the spring 334; And
The pressure ring 337 extends downward from the inner circumferential surface of the pressure ring 337 and includes a pressure pipe 338 that comes into contact with the adjustment member 333. When the adjustment member 333 rotates, the spring 334 is raised and lowered together. Safety system when repairing the distribution line, characterized by adjusting the elastic force of).

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