KR100932007B1 - Monitoring method for track monitoring using wind direction / wind speed sensor module - Google Patents

Abstract

The present invention provides a line monitoring diagnostic method using the wind direction / wind speed sensor module. The wind is introduced into the air induction hole along the plurality of air induction holes provided on the frame and a plurality of air induction holes provided on the outer circumferential surface of the frame, the wind direction / wind sensor connected to the end of the air induction hole in the frame Measuring the wind direction / wind speed of the wind flowing into the air induction hole, and the communication unit connected to the wind direction / wind speed sensor includes transmitting / receiving a measurement value, the air induction hole is inclined to the inside of the frame Towards the altitude is formed to be higher.

Wind direction, wind speed, sensor, module, track, monitoring, diagnostics

Description

Method of monitoring and diagnosing using wind direction / wind velocity sensor modules}

The present invention relates to a line monitoring diagnostic method, and more particularly to a line monitoring diagnostic method using the wind direction / wind speed sensor module.

In the past, power control technology has led the research on how to detect failures quickly and accurately when a power system breaks down, and how to properly recover after failures.

However, people's perceptions have changed since the major blackouts in the United Kingdom and Russia, including the United Kingdom and Russia, and the massive physical and physical damages.

In other words, the field of preventive diagnosis has been studied to prevent the failure in advance by measuring and determining the signs of the failure before the failure occurs. In particular, researches on the field of monitoring and diagnosing the variation of transmission line, which is the most important artery in power system, have been actively conducted.

Meanwhile, the transmission line includes a transmission tower, a insulator, and a transmission line, which are connected in the air while being supported by the transmission tower and the insulator. Therefore, since the transmission tower is exposed to typhoons or other strong winds, when the transmission tower is directly subjected to strong winds, the transmission tower or the transmission line supported thereto suffers physical damage such as sagging or twisting.

Therefore, in order to prevent such an accident, it is necessary to accurately monitor and diagnose the wind direction and the wind speed of the transmission line. Conventionally, for this purpose, a regular visit diagnosis method of a site maintainer and a method of monitoring by a local sensor (wind direction / wind speed and a camera) installed in a transmission tower have been used.

Wind direction / wind speed sensors shall be located inside the track monitoring diagnostic system to measure wind direction and wind speed. For this purpose, a passage through which wind passes through the monitoring diagnostic apparatus must be drilled. Therefore, water from rain or snow or the like penetrates into the track monitoring diagnostic apparatus by the passage, causing malfunction or deterioration of life of the monitoring diagnostic apparatus. Therefore, the monitoring diagnostic apparatus does not adequately monitor the monitoring for changes in the surrounding environment and thus does not detect the failure or abnormality of the transmission line.

The technical problem to be achieved by the present invention is to install a wind direction / wind sensor at the end of the air induction hole formed in a structure that does not flow to the inside of the frame even if the water flowing along the surface of the frame passes through the air induction hole, the wind is transmitted to the transmission line To provide a way to monitor / diagnose impacts.

According to an aspect of the present invention for achieving the above technical problem, the wind is introduced into the air induction hole along the frame fitted in a sphere on the transmission line and a plurality of air induction holes provided on the outer peripheral surface of the frame, The wind direction / wind speed sensor connected to the end of the air induction hole in the frame measures the wind direction / wind speed of the wind flowing into the air induction hole, and the communication unit connected to the wind direction / wind speed sensor transmits / receives the measured value. Including, the air induction hole is inclined is characterized in that the height is formed higher toward the inside of the frame.

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In another embodiment, measuring the wind direction / wind speed of the wind by the wind direction / wind sensor to detect the wind direction / wind speed with a wind direction / wind speed detection unit provided at the inner end of the air induction hole, and the detected wind direction / wind speed It may include a connecting unit for amplifying by the amplification unit connected to the sensing unit, and transmits the amplified value to a micro process provided in the frame.

In another embodiment, the wind direction / wind speed detection unit has an inlet for the wind flows in and the outlet for the wind flows out, it may include a wind direction / wind speed detection chip for detecting the wind direction / wind speed between the inlet and the outlet. have.

According to the present invention as described above, the wind direction / wind speed sensor is located at the end of the air induction hole. The air induction hole is formed to have a higher altitude inside than at the frame surface. Therefore, the structure of the air induction hole prevents water generated by snow or rain from penetrating into the inside of the frame even if the water flows through the air induction hole along the surface of the frame. As a result, even if it rains or snow, it is possible to monitor / diagnose the effect of the wind on the transmission line using the wind direction / wind speed sensor installed at the end of the air induction hall.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed contents are thorough and complete, and that the spirit of the present invention to those skilled in the art will fully convey. Portions denoted by like reference numerals denote like elements throughout the specification.

1 is a view showing a state in which the line monitoring diagnostic apparatus according to the present invention is installed on the transmission line, Figure 2a is a cross-sectional view seen from the top of the line monitoring diagnostic apparatus according to the present invention. Figure 2b is a view showing the air inlet hole in the side of the track monitoring diagnostic apparatus according to the present invention, Figure 3 is a block diagram showing the configuration of the wind direction / wind speed sensor according to the present invention, Figure 4 is shown in Figure 2a It is a block diagram which shows the structure of a line monitoring diagnostic apparatus.

Referring to Figure 1, the line monitoring diagnostic apparatus 40 according to the present invention is installed on the transmission line serves to monitor the transmission line side. The transmission line includes a transmission tower 10 connecting the transmission line 20 and an insulator 30 supporting the transmission line 20.

2A and 2B, the line monitoring diagnostic apparatus 40 includes a frame 40, a wind direction / wind sensor module 49, a solar cell 45, and a super capacitor 46. The line monitoring diagnosis device 40 may be formed in a spherical shape, and a transmission line fitting hole 41 may be formed in the center. The transmission line 20 may be inserted through the transmission line fitting hole 41. On the outer circumferential surface of the frame 47 is provided an air induction hole 51 through which wind is guided. The air induction hole 51 may be provided in plural according to a natural environment in which the wind direction changes from time to time, and may prevent water from penetrating into the frame 47 through the air induction hole 51. It may be formed into a structure.

The wind direction / wind speed sensor module 49 is provided at the end of the air induction hole 51 inside the frame 47. The end of the air induction hole 51 is located at an altitude higher than the inlet of the air induction hole 51 located on the outer circumferential surface of the frame 47. That is, the air induction hole 51 is formed to have an inclination, and the altitude is higher toward the inside of the frame 47. As a result, the transmission line monitoring and diagnosing device 40 is configured to allow water to flow through the air induction hole 51 even though water caused by snow or rain flows down the outer circumferential surface of the frame 47. Can be prevented from infiltrating

The frame 47 is formed in a spherical shape, and the aforementioned power line fitting hole 41 is provided at the center of the frame 47.

The wind direction / wind speed sensor module 49 may detect wind direction and wind speed around the transmission line 20 and may be installed in the frame 47. The wind direction / wind speed sensor module 49 includes a wind direction / wind speed sensor 47, a communication unit 44, and a micro process 43. The wind direction / wind speed sensor 42 measures the wind direction / wind speed, and the communication unit 44 collects data measured by the wind direction / wind speed sensor and wirelessly transmits the data to the administrator's server 50. The communication unit 44 may adopt and use ZigBee technology, which is a low-speed, low-power, wireless personal area communication technology. The micro process 43 controls the wind direction / wind speed sensor 42 and the communication unit 44.

A plurality of solar cells 45 may be provided and attached to the outer circumferential surface of the frame 47. The solar cell 45 serves to generate power by using sunlight. The supercapacitor 46 may be installed inside the frame 47 and connected to the solar cell 45 and the wind / wind sensor module 49. The supercapacitor 46 may store charges generated from the solar cell 45 and discharge the charges to supply power to the wind direction / wind speed sensor module 49. As a result, the line monitoring diagnostic apparatus 40 may generate power by itself from the solar cell 45 and the super capacitor 46 and supply the wind direction / wind speed sensor module 49 without connecting an external power source. have.

Referring to FIG. 3, the wind direction / wind speed sensor 42 may include a case 429, a wind direction / wind speed detection unit 425, an amplifier 426, a controller 427, a connection unit 428, and an interface unit 430. Include. The detector 425 is installed at one end of the case 429 and includes an air inlet 423, an air outlet 424, and a sensor chip 421. The wind guided into the frame 47 through the air induction hole 51 passes through the air inlet 423 and the air outlet 424 of the wind direction / wind speed sensor 42. In this case, the sensing chip 421 is interposed between the inlet 423 and the outlet 424 to detect the direction and speed of the guided wind. The sensing chip 321 may be a wind / wind meter using three-way MEMS (micro electric mechanical systems) technology in which the wind speed measurement range / precision is 0 to 60 m / sec / ㅁ 5%.

The sensed wind direction / wind speed value is amplified by the amplifier 426 and controlled by the controller 427. The connection part 428 is provided to send the amplified value to the micro process 43. The interface unit 430 is interposed between the controller 427 and the connection unit 428, and electrically connects the two parts for signal communication between the controller 427 and the microprocessor 43.

Next, the wind direction / wind speed monitoring diagnosis method of the transmission line according to the present invention will be described with reference to FIGS. 2A to 4.

2A to 4, wind is guided into the frame 47 through the air induction hole 51. The air induction hole 51 is formed in a structure that can prevent water from penetrating inside through the air induction hole 51 even if water flows on the surface of the frame 47. That is, the end of the air induction hole 51 inside the frame 47 is located at an altitude higher than the inlet of the air induction hole 51 located on the outer circumferential surface of the frame 47. As a result, the transmission line monitoring and diagnostic apparatus 40 detects that the water penetrates into the frame 47 through the air induction hole 51 even if water caused by snow or rain flows down the frame 47. You can prevent it.

The air flows into the air inlet 423 of the wind direction / wind sensor 42 located inside the frame 47 of the air induction hole 51 and flows out of the air outlet 424. It is sensed by the sensing chip 421 between 423 and the air outlet 424. The sensed wind direction / wind speed value is amplified by the amplifier 426 and controlled by the controller 427. The controlled value is sent to the microprocessor 43 connected to the connector 428 by an interfacer 430 that electrically connects the controller 427 and the microprocessor 43. The measured value is transmitted from the micro process 43 to the communication unit 44 and sent from the communication unit 44 to the manager server 50. As a result, the server administrator can remotely check whether there is an abnormality in the transmission line due to the influence of the wind.

1 is a diagram illustrating a state in which a line monitoring diagnostic apparatus according to the present invention is installed on a transmission line.

Figure 2a is a cross-sectional view seen from the top of the track monitoring diagnostic apparatus according to the present invention.

Figure 2b is a view showing the air inlet hole in the side of the track monitoring diagnostic apparatus according to the present invention.

3 is a block diagram showing the configuration of the wind direction / wind speed sensor according to the present invention.

FIG. 4 is a block diagram showing the configuration of the line monitoring diagnostic apparatus shown in FIG. 2A.

Claims (4)

A frame fitted in a rectangular shape to a power transmission line, and wind flows into the air induction hole along a plurality of air induction holes provided on the outer circumferential surface of the frame, and a wind direction / wind sensor connected to the air induction hole end in the frame. Measuring the wind direction / wind speed of the wind flowing into the air induction hall, and the communication unit connected to the wind direction / wind speed sensor includes transmitting / receiving a measurement value, The air induction hole is inclined so that the altitude becomes higher toward the inside of the frame, the transmission line monitoring diagnostic method. delete The method of claim 1, Measuring the wind direction / wind speed of the wind with the wind direction / wind sensor The wind direction / wind speed detection unit provided at the inner end of the air induction hole detects the wind direction / wind speed, Amplifying the detected wind direction / wind speed by an amplifier connected to the sensing unit; And a connection unit for transmitting the amplified value to a micro process provided in the frame. The method of claim 3, wherein The wind direction / wind speed detection unit includes a wind inlet and an outlet through which the wind flows, but includes a wind direction / wind speed sensing chip detecting a wind direction / wind speed between the inlet and the outlet. Diagnostic method.

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