KR20140060926A - Apparatus for measuring an inclined angle of telegraph pole - Google Patents

Abstract

[0001] The present invention relates to an apparatus for calculating an inclination of an electric facility, which comprises a housing mounted in an electric facility and having an internal space, and an upper end supported by the housing and capable of being bent down freely according to a change in inclination of the housing A weight supporting the flexible support bar, the weight supporting the flexible support bar, the flexible support bar being connected to the lower end of the flexible support bar and guiding the flexure of the flexible base bar according to the inclination of the housing due to its own weight, A second optical fiber grating coupled to the other side of the flexible supporting bar along the longitudinal direction thereof and connected in series with the first optical fiber grating; a light source; and a second optical fiber grating that receives light emitted from the light source, To the optical transmission line leading from the first optical fiber grating to the second optical fiber grating, and the first optical fiber grating and the second optical fiber grating And an optical detector for detecting the light output through the second output end of the optical circulator; and a control unit for controlling the inclination change of the housing from the light detected by the optical detecting unit And a slope calculation section for calculating the slope. According to the apparatus for calculating an inclination of such an electric facility, a plurality of electric installations such as a steel tower are connected in series so that the inclination information can be received through a communication network, thereby being able to constantly monitor the safety state of the electric facility at a remote place to provide.

Description

[0001] The present invention relates to an apparatus for measuring an inclined angle of an electric facility,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for calculating an inclination of an electric facility, and more particularly to an apparatus for calculating an inclination of an electric facility using an optical fiber grating.

In general, poles and steel towers are widely used as supports for transmission and distribution cables.

In the case of a steel tower installed in a harsh area where pickling occurs, it may be distorted or torn due to collapse or deformation of the surrounding slope due to the influence of climate and rainfall, resulting in breakage or large safety accidents due to short- There is always a possibility.

Japanese Patent Laid-Open No. 2006-0025489 discloses a steel tower inclination measuring apparatus and a method thereof. However, the tilt measuring apparatus is a method of calculating the tilt by measuring the three-dimensional coordinates of the steel tower in the field, and there is an inconvenience that the operator must directly go to the site to measure the tilt.

It is an object of the present invention to provide an apparatus for calculating an inclination of an electric facility capable of always measuring and providing an inclination of an electric facility by a sensor system installed on the site.

According to an aspect of the present invention, there is provided an apparatus for calculating an inclination of an electric facility, the apparatus comprising: a housing installed in an electric facility and having an internal space; A flexible support bar formed of an elastic material and having an upper end in an inner space of the housing, the upper end of the flexible support being supported by the housing and extending downward, the flexible support bar being freely bendable according to a change in the inclination of the housing; A weight attached to the lower end of the flexible support bar to guide the flexure of the flexible base bar according to a change in the inclination of the housing due to its own weight; A first optical fiber grating coupled to one side of the flexible supporting bar along a longitudinal direction thereof; A second optical fiber grating coupled to the other side of the flexible supporting bar along the longitudinal direction thereof and connected in series with the first optical fiber grating; A light source; And a second optical fiber grating for receiving the light emitted from the light source and transmitting the light from the first optical fiber grating through the first output end to the optical transmission line leading from the first optical fiber grating to the second optical fiber grating, And outputting the output signal through a second output terminal; A photodetector for detecting light output through the second output terminal of the optical circulator; And a tilt calculating section for calculating a tilt change of the housing from the light detected by the light detecting section.

Preferably, the upper surface exposed to the outside of the housing is further provided with a level indicator for visually confirming a horizontal state when the housing is installed in the electric facility.

Here, the electric facilities may be applied to a transmission tower or a pole tower.

Preferably, the flexible support bar has a rectangular cross-sectional shape, and the inclination calculator transmits the calculated inclination information to the address of the management server set through the wireless transmission unit through the communication network.

According to the apparatus for calculating an inclination of an electric facility according to the present invention, a plurality of electric equipments such as a steel tower can be connected in series so that the inclination information can be received through a communication network, so that the safety state of the electric facility can be monitored at a remote place Provides the advantages of.

FIG. 1 is a schematic perspective view showing a state in which an apparatus for calculating an inclination of an electric facility according to the present invention is installed on a steel tower,
FIG. 2 is a partially cutaway perspective view showing the inside of the housing of the inclination calculating device of FIG. 1,
3 is a block diagram of a control system of the apparatus for calculating an inclination of an electric facility in Fig. 1,
FIG. 4 is a view showing the expansion and contraction states of the first and second optical fiber gratings when the flexible support bar of FIG. 3 is bent by the inclination change,
FIG. 5 is a graph for explaining fluctuation of a detection wavelength due to a temperature change of the first and second optical fiber gratings of FIG. 3,
FIG. 6 is a graph for explaining fluctuation of the detection wavelength due to the inclination change of the first and second optical fiber gratings of FIG. 3;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an apparatus for calculating an inclination of an electric facility according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view showing a state in which an apparatus for calculating an inclination of an electric facility according to the present invention is installed on a steel tower, FIG. 2 is a partially cutaway perspective view showing the inside of the housing of FIG. 1, Fig. 2 is a block diagram of the control system of the tilt calculating device of Fig.

1 to 3, an apparatus 100 for calculating an inclination of an electric facility according to the present invention includes a sensing unit 110 and a control unit 150.

The sensing unit 110 includes a housing 111, a flexible supporting bar 113, a weight 115, and first and second optical gratings 121 and 122.

The housing 111 is formed in a rectangular housing shape having an inner space 111a mounted on a power tower for power transmission and distribution 10, which is an example of an electric facility.

It is needless to say that, unlike the example shown in FIG. 1, the electric device provided with the housing 111 may be a telephone pole installed on the ground.

The housing 111 is connected to the steel tower 10 by means of a coupling member such as a bolt and a nut 131 through a coupling hole formed in a plate-like coupling rib 112 protruding in the vertical direction on the back surface of the rectangular housing portion. .

The housing 111 is formed with two connection ports 117 through which an optical transmission line 160 made of an optical fiber enters and exits from the inner space 111a. An optical fiber as the optical transmission line 160 is connected to the connection port 117 And can be supported and inserted by a protective tube 162 that stably supports the tube.

A leveling unit 140 is mounted on the upper surface exposed to the outside of the housing 111 so that the housing 111 can be installed while checking the horizontal state when the housing 111 is installed on the steel tower.

The leveling unit 140 may include various structures known in the art such that the inside of the leveling unit 140 is filled with water and the horizontal state can be confirmed through movement of the bubble 142 according to the level.

The flexible supporting bar 121 is formed of an elastic material which is supported by the housing 111 and has an upper end in an inner space 111a of the housing 111 and can be freely bent according to a change in the inclination of the housing 111 have.

The flexible support bar 121 may be made of a material such as a flexible silicon material which can be bent according to a change in the position of the weight 115, which will be described later, according to a change in inclination.

The flexible support bar 113 is preferably formed in a polygonal cross-sectional shape, and is formed in a rectangular shape in the illustrated example.

In the illustrated example, the flexible supporting bar 113 has a structure in which the upper end is coupled to the lower end of the auxiliary supporting member 145 formed in a triangular shape such that the cross-sectional area becomes narrower as the leveling unit 140 of the housing is moved downward The auxiliary supporting member 145 may be omitted and coupled downwardly from the bottom of the ceiling of the leveling unit 140, unlike the illustrated example.

The weight 115 is coupled to the lower end of the flexible support bar 113 and moves in the gravity direction due to its own weight in the inner space 111a of the housing 111 according to the inclination change of the housing 111, Thereby leading to warping of the bar 113.

The weight of the weight 115 may be suitably applied.

The first optical fiber grating 121 is coupled to one side of the flexible supporting bar 113 along the longitudinal direction thereof.

The second optical fiber grating 122 is coupled to the other side opposite to the one side along the longitudinal direction of the flexible support bar 113, and is connected in series with the first optical fiber grating 121.

Here, it is preferable that the first optical fiber grating 121 and the second optical fiber grating 122 have different center wavelengths in a state in which no external force is applied.

It is needless to say that four optical fiber gratings may be provided on four surfaces having a rectangular cross section with respect to the longitudinal direction of the flexible support bar 113, unlike the illustrated example.

A plurality of sensing units 110 may be connected to one another through a mutual optical transmission line 160 in series and connected to the inclination detecting position. In this case, the center wavelength of the optical fiber grating applied to each sensing unit 110 is formed to have different values in a state where no external force is applied.

The control unit 150 includes a light source 151, an optical circulator 153, a light detecting unit 155, a tilt calculating unit 157, and a wireless transmitting unit 159.

The light source 151 applies a broadband light source that emits light in a wide wavelength range.

The optical circulator 153 receives the light emitted from the light source 151 and transmits the light through the first output end 153a to the optical transmission line 160 extending from the first optical fiber grating 121 to the second optical fiber grating 122 And outputs the light reflected from the first optical fiber grating 121 and the second optical fiber grating 122 through the second output end 153b.

The photodetector 155 detects light output through the second output terminal 153b of the optical circulator 153 and provides the detected light to the slope calculation unit 157. [

The inclination calculating unit 157 detects the shift of the center wavelength of the light detected by the optical detecting unit 155 by the lattice spacing change of the first optical fiber grating 121 and the second optical fiber grating 122, And calculates a slope change.

The wireless transmitting unit 159 controls the inclination calculating unit 157 to transmit the inclination information calculated by the inclination calculating unit 157 to the communication address of the management server 190 set via the communication network 180. [

Here, the communication network 180 may be a wired or wireless Internet.

The inclination calculation apparatus 100 may be installed in an electric facility at a position where a plurality of sensing units 110 are serially connected to one control unit 150 and tilt measurement is required.

4 and 5, when the mounting portion of the sensing unit 110 is tilted to the left, the first optical fiber grating 121 is moved from one side of the flexible supporting bar 113 The center wavelength shifts from the reference center wavelength lambda 1 to the lengthening of the wavelength and the second optical fiber grating 122 moves from the reference side to the reference side The center wavelength shifts in the direction in which the wavelength becomes shorter from the center wavelength? 2.

Therefore, the slope calculating unit 157 checks the movement amount of the central wavelength, and calculates the slope by comparing it with the look-up table in which the center wavelength shift value measured in advance according to the slope is recorded.

On the other hand, when only the temperature is changed, as shown in FIG. 6, in the same direction, that is, the wavelength increases by the same wavelength variation amount at the reference center wavelength? 1 (? 2) of the first and second optical fiber gratings 121 and 122 Direction or in the direction in which the wavelength decreases, it is possible to determine whether the wavelength shift due to the temperature change of the slope calculation section 157 is present.

The inclination calculation apparatus 100 of the electric facility described above is provided with a plurality of sensing units 110 connected in series to an electric facility such as a steel tower 10 to transmit inclination information to the management server 190 ) In real time so that it is possible to monitor the safety state of the electric facilities at a remote place at any time.

110: sensing unit 111: housing
113: Flexible support bar 115: Weight weight
121: first optical fiber grating 122: second optical fiber grating
150: control unit

Claims (5)

A housing mounted on the electric facility and having an internal space;
A flexible support bar formed of an elastic material and having an upper end in an inner space of the housing, the upper end of the flexible support being supported by the housing and extending downward, the flexible support bar being freely bendable according to a change in the inclination of the housing;
A weight attached to the lower end of the flexible support bar to guide the flexure of the flexible base bar according to a change in the inclination of the housing due to its own weight;
A first optical fiber grating coupled to one side of the flexible supporting bar along a longitudinal direction thereof;
A second optical fiber grating coupled to the other side of the flexible supporting bar along the longitudinal direction thereof and connected in series with the first optical fiber grating;
A light source;
And a second optical fiber grating for receiving the light emitted from the light source and transmitting the light from the first optical fiber grating through the first output end to the optical transmission line leading from the first optical fiber grating to the second optical fiber grating, And outputting the output signal through a second output terminal;
A photodetector for detecting light output through the second output terminal of the optical circulator;
And an inclination calculating unit for calculating an inclination change of the housing from the light detected by the light detecting unit. The apparatus according to claim 1, further comprising a leveling unit on the upper surface exposed to the outside of the housing to visually confirm a horizontal state when the housing is installed in the electric facility. [3] The apparatus according to claim 2, wherein the electric facility is a power transmission tower or a pole. The apparatus according to claim 2, wherein the flexible support bar has a rectangular cross-sectional shape. The apparatus according to claim 3, wherein the slope calculating unit is configured to transmit the calculated slope information to an address of a management server set through a wireless transmission unit through a communication network.

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