KR20210095456A - Calculating method for length of phase spacer and calculating apparatus for length of phase spacer - Google Patents

Abstract

The present invention relates to a calculating method for a length of a phase spacer, which is conducted by a processing apparatus for calculating the length of one or more phase spacers to be formed between two or more power lines with different dips by being installed between two transmission steel towers, comprising: a step of respectively receiving an input of the length between a reference steel tower, which is one of the two transmission steel towers, and the installation points of the one or more phase spacers; a step of receiving an input of a horizontal angle between the reference steel tower and the two or more power lines; a step of receiving an input of the coordinate value of the installation points of the one or more phase spacers on the two or more power lines; and a step of calculating the length of the one or more phase spacers by using formula 1: l = d, Ө, (x, y, z). Accordingly, the present invention is able to reduce the cost for variable rod and personnel spent for the installation of the phase spacers, install the phase spacers with a precise length, and improve the reliability of power transmission facilities.

Description

Interphase spacer length calculation method, interphase spacer length calculation device

The present invention relates to a method for calculating the length of an interphase spacer and an apparatus for calculating the length of an interphase spacer, and to a technique for calculating the length of an interphase spacer to be installed for durability of a transmission line of a transmission tower.

In a transmission system including transmission lines of multiple phases between transmission towers, an interphase spacer having a structure connected between transmission lines of different phases is disclosed in order to prevent a short circuit accident between lines due to vibration caused by wind. is becoming

In one example, the length of the interphase spacer is ideally formed to correspond to the distance between the arms of the transmission tower to which the two power lines are connected, when the two power lines disposed on different phases have the same value.

However, the power lines of the power transmission facilities may have different values of the power lines of each phase due to aging of the facilities, climate change, errors during installation, etc. In this case, the length of the interphase spacer is set to a length corresponding to the distance between the arms of the transmission tower. There are limitations in forming and installing.

Accordingly, when the separation between the power lines of each phase is different, the interphase spacer is installed by adding a variable rod to the interphase spacer of the length corresponding to the arm separation distance. In this case, as the power line sags due to the weight of field workers and equipment, a variable load adjustment error may occur, which may lead to problems of tension generation in which the upper line supports the lower line and distortion of the small conductor.

Alternatively, due to the variable rod adjustment error, the interphase spacer is installed longer than the distance between the upper line and the lower line, and the interphase spacer is bent and mechanical force is borne on the clevis rod and the wire clamp.

Therefore, when installing a spacer between phases between power lines with different separation values, different separation values are used to improve the reliability of equipment by improving worker stability, reducing material purchase costs and installation costs such as variable rods, and minimizing errors in the length of phase spacers. There is a need to develop a method or device capable of calculating the length of the interphase spacer to be installed between the power lines with no error.

Korean Patent Laid-Open Publication No. 10-2010-0063236 (Method for measuring the ear canal of a transmission line)

The technical task to be achieved by the present invention is to accurately measure the length of the interphase spacer to be installed between two power lines having different ear poles, thereby reducing the manpower and material costs required for installing the interphase spacer, and to prevent a safety accident that may occur between power lines. .

According to an aspect of an embodiment, the interphase spacer length calculation method is

It is performed in a processing device for calculating the length of at least one interphase spacer to be installed between two transmission towers and to be formed between at least two power lines having different poles,

receiving each input a distance between a reference tower, which is one of the two transmission towers, and an installation point of the at least one interphase spacer;

receiving a horizontal angle between the reference tower and the at least two power lines;

receiving a coordinate value of an installation point of the at least one interphase spacer on the at least two power lines; And,

calculating the length of the at least one interphase spacer using Equation 1 below; It is characterized in that it includes.

[Equation 1]

According to another aspect of an embodiment, the interphase spacer length calculation device is

an input unit for receiving coordinate values of two transmission towers and coordinate values of at least two power lines connected between the two transmission towers; And,

From the coordinate values of the two transmission towers received from the input unit and the coordinate values of at least two power lines connected between the two transmission towers, using Equation 1 below, at least two power lines connected between the two transmission towers. and an interphase spacer length calculation unit for calculating the length of the interphase spacer to be installed.

[Equation 1]

According to this feature, it is possible to calculate the length of the interphase spacer to be installed between power lines using the interphase spacer length calculation method and apparatus according to an embodiment of the present invention. There is an effect that can effectively reduce the occurrence of worker's labor time and variable load cost.

In addition, according to this, it is possible to accurately calculate and install the interphase spacer length between power lines, thereby preventing problems caused by installing interphase spacers of inappropriate length, thereby improving the stability of the power line.

1 is a view showing two power lines installed between transmission towers to which a method for calculating an interphase spacer length and a calculation device according to an embodiment of the present invention is applied.
2 is a diagram illustrating an example in which a spacer between phases is installed in two power lines installed between transmission towers, which is a target of a method for calculating a length of an interphase spacer and a calculation apparatus according to an embodiment of the present invention.
3 is a flowchart illustrating a flow of a method for calculating an interphase spacer length according to an embodiment of the present invention.
4 is a flowchart illustrating a flow of a method for calculating an interphase spacer length according to an embodiment of the present invention.
5 is a flowchart illustrating a flow of a method for calculating an interphase spacer length according to an embodiment of the present invention.
6 is a block diagram showing a schematic structure of an interphase spacer length calculation apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

1 is a view showing two power lines installed between transmission towers to which a method for calculating the length of an interphase spacer according to an embodiment of the present invention and a calculation device are applied, and FIG. 2 is a method for calculating the length of an interphase spacer according to an embodiment of the present invention. And it is a view showing an example in which an interphase spacer is installed in two power lines installed between transmission towers, which are the subject of application of the calculation device, Figure 3 is a flow chart showing the flow of the interphase spacer length calculation method according to an embodiment of the present invention is a flow chart showing the flow of the interphase spacer length calculation method according to an embodiment of the present invention, Figure 5 is a flow chart showing the flow of the interphase spacer length calculation method according to an embodiment of the present invention, Figure 6 is a flow chart of the present invention It is a block diagram showing a schematic structure of an interphase spacer length calculation apparatus according to an embodiment.

In this embodiment, the interphase spacer length calculation method relates to a technique for calculating the length of the interphase spacer to be installed between two power lines connected between two transmission towers, and is performed in the interphase spacer length calculation apparatus according to an embodiment of the present invention. Let's explain the algorithm as an example. In this case, the interphase spacer length calculating device may be a computer device or a portable terminal device.

Alternatively, in another example, the interphase spacer length calculation method of the present invention may be implemented in a readable recording medium, and the implementation position of the interphase spacer length calculation method according to the present embodiment should not be limited.

First, a method for calculating the length of an interphase spacer according to an embodiment of the present invention will be described with reference to FIGS. 1 to 5. As shown in FIG. Step of receiving the input (S100), the step of receiving the horizontal strength between the reference tower and the wires (S200), the step of receiving the coordinate value of the installation point of the interphase spacer of the power line (S300), and the step of calculating the length of the interphase spacer (S400) is made including

At this time, the structure of the power line and the interphase spacer formed between transmission towers to which the interphase spacer length calculation method of the present invention is applied with reference to FIGS. 3 to 5 will be described with reference to FIGS. 1 to 2 , as shown in FIG. Two power lines c1 and c2 are connected between the two transmission towers 1 and 2, and the first power line c1 is connected to the first arm 11 of the first transmission tower 1 and the second transmission tower 2 is connected between the third arm 21 of the Connected.

In addition, the first and second power lines c1 and c2 are not formed in a straight line between the first transmission tower 1 and the second transmission tower 2 , but are formed to have a drooping state, that is, to have two canals. The two-way d1 of the first power line c1 is the first support point 111 of the first arm 11 of the first transmission tower 1 and the third arm 21 of the second transmission tower 2 3 It is the distance between x1, which is the midpoint of the first imaginary line 110 connecting the support point 211, and the wire crossing point y1, which is the most drooping part of the first power line c1, and the second power line c2 d2) is a fourth point connecting the second support point 121 of the second arm 12 of the first transmission tower 1 and the fourth support point 221 of the fourth arm 22 of the second transmission tower 2 2 This is the distance between x2, which is the midpoint of the virtual line 120, and the wire crossing point y2, which is the most drooping part of the second power line c2.

When the two-way d1 of the first power line c1 and the two-way d2 of the second power line c2 have different values, the length of the interphase spacer to be installed between the first and second power lines c1 and c2 is Since the error range is large to substitute the length between the arms of the transmission tower, the length of the interphase spacer to be installed between power lines can be accurately calculated using the method for calculating the length of the interphase spacer according to an embodiment of the present invention.

In one example, the interphase spacer to be installed between two power lines having different degrees of separation is to be installed in plurality, such as the first interphase spacer 31, the second interphase spacer 32, and the third interphase spacer 33, as shown in FIG. can At this time, even if a plurality of interphase spacers are installed, it is preferable to necessarily include at least one interphase spacer for connecting the two conductor points of the power lines c1 and c2.

As described above, the method of calculating the length of the interphase spacer to be installed between two power lines having different elevations will be described with reference to FIG. 3 again. First, the step (S100) of receiving the distance between the reference pylon and the interphase spacer installation point is the reference pylon A step of receiving the horizontal distance between the and the interphase spacer installation target point, in an example where the reference pylon is the first transmission tower 1 and the interphase spacer installation target point is the position of the first interphase spacer 31, the first transmission tower A horizontal distance between (1) and the first interphase spacer 31 is input.

At this time, the horizontal distance between the first transmission tower 1 and the first interphase spacer 31 is the first and second support points 111 of the first or second arms 11 and 12 of the first transmission tower 1 , 121) and the third and fourth support points 211 and 221 of the third or fourth arms 21 and 22 of the second transmission tower 2 are derived from the distance.

And at this time, the first and second supporting points 111 and 121 of the first transmission tower 1 are supporting points formed on the first and second arms 11 and 12 having the same horizontal length, and the second transmission tower 2 Since the third and fourth support points 211 and 221 of ) are support points formed on the third and fourth arms 21 and 22 having the same horizontal length, the first and second points of the first and second transmission towers 1 and 2 are The horizontal distance between the support point 111 and the third support point 211 is equal to the horizontal distance between the second support point 121 and the fourth support point 221 of the first and second transmission towers 1 and 2 .

The horizontal distance between the support points of two transmission towers can be calculated from the measured values of the distances or sizes disclosed in the design drawings of transmission facilities, etc. , even if the calculation process of the horizontal distance is omitted in the present specification, the features of the present invention should not be limited.

In this way, in an example of deriving the horizontal distance between the reference tower and the interphase spacer installation points from the horizontal distance between the supporting points of the transmission tower (hereinafter referred to as 'the actual horizontal distance between the transmission towers'), in an example, between the reference tower and the first phase The horizontal distance between the spacers 31 is derived by multiplying the actual horizontal distance between the transmission towers by 1/3.

In another example, the horizontal distance between the reference tower and the second interphase spacer 32 is derived by multiplying the actual horizontal distance between the transmission towers by 1/2, and the horizontal distance between the reference tower and the third interphase spacer 33 is the transmission tower It is derived by multiplying the actual horizontal distance between the two by 2/3.

Therefore, in the first step (S100), the distance between the reference tower and the interphase spacer installation point calculated as above is input.

And, in this step (S100), it is possible to receive an input of the interphase spacer installation points according to the number and number of interphase spacers to be installed between power lines in advance. In one example, in an embodiment of the present invention with reference to the drawings, it relates to an embodiment of installing three interphase spacers between power lines, and the distance between the reference pylon and the interphase spacer installation point is input for each of the three interphase spacers. However, in another embodiment, in the case of a structure in which two interphase spacers are installed between power lines or four interphase spacers are installed, the distance between the reference tower and the interphase spacer is received in the form of receiving two or four inputs. A corresponding step ( S100 ) may be performed.

In this step (S100) is performed so that the distance between the reference tower and the interphase spacer is input by a set number, the number of installed interphase spacers to be installed between the power lines may be a preset value, may be changed, and is not limited thereto.

In addition, it should be clearly understood that the preset number of interphase spacers installed in this step (S100) should be equally applied to the following steps (S200, S300, S400).

Next, in the step (S200) of receiving the input of the horizontal angle between the reference tower and the wires, the horizontal angle between the first transmission tower (1) and the first power line (c1), which are the reference towers, and the first transmission tower (1) and the second power line The horizontal angle between (c2) is input.

Here, the horizontal angle is an angle value displayed on the instrument panel, and is input from a tab indicating a horizontal angle value for rotating and fixing the instrument in the reference tower.

And then, in the step (S300) of receiving the coordinate value of the installation point of the interphase spacer of the power line, the first to third interphase spacers 31, 32, 33 to be installed on the first and second power lines c1 and c2 are installed Input the point coordinates.

In this step ( S300 ), coordinate values of any one of the first to third interphase spacers 31 , 32 , and 33 are received based on the first transmission tower 1 , which is the reference tower, respectively. At this time, the coordinate value of each interphase spacer receives the coordinate value of the point where the interphase spacer is connected to the first power line c1 and the coordinate value of the point where the interphase spacer is connected to the second power line c2, respectively. As such, the coordinate values of the installation point on the power line of the interphase spacer installed in the power lines are the coordinate values measured by the measuring instrument collimating each power line (c1, c2), and the values for the x-axis, y-axis and z-axis are each have

And finally, the step of calculating the interphase spacer length (S400) is the distance between the reference tower and the interphase spacer installation point input from the above steps (S100, S200, S300), the horizontal angle between the reference tower and the wires, and the phase between the power lines Calculate the length of the interphase spacer from the coordinates of the spacer installation point.

This step (S400) can be performed from Equation 1 below.

[Equation 1]

(Like the format of Equation 1 above, the interphase spacer length (l) is derived from at least one of a distance (d), an angle (θ), and a coordinate value (x, y, z).

이고, 전력선 C2의 상간스페이서 설치 점을

일 경우 상간스페이서 길이(l)는 다음 식 2에 의거 도출된다.For example, the interphase spacer installation point of power line C1 is

and the interphase spacer installation point of power line C2 is

In this case, the interphase spacer length (l) is derived according to Equation 2 below.

[Equation 2]

The length of the interphase spacer to be installed between the power lines between the two transmission towers is calculated through the flow of FIG. 3, so that the interphase spacer of the correct length can be installed between the power lines requiring the installation of the phase spacer, so only the distance between the arms of the transmission tower is used Thus, manpower consumption of the interphase spacer installation worker and cost consumption due to the variable load occurring in the conventional method of roughly inferring the length of the interphase spacer. In addition, it is possible to prevent problems leading to damage to the power line due to mis-installation of the interphase spacer, so that it is possible to expect an economic effect and an effect of improving the reliability of the power transmission facility.

And, as an example, the interphase spacer length calculation method according to this embodiment performed as in the flowchart of FIG. 3 may be performed after performing any one of the processes shown in FIGS. 4 and 5 . As a detailed example, after the step of receiving the first pylon coordinate value of FIG. 4 ( S510 ) and the receiving of the second pylon coordinate value ( S520 ) are performed, the first step of FIG. 3 , the reference pylon and the interphase spacer A step (S100) of receiving an input of the distance between installation points may be performed.

At this time, in the step of receiving the coordinate values of the first pylon of FIG. 4 ( S510 ), the coordinate values (x, y, z) of the first transmission tower 1 are received. In this case, the coordinate value of the first transmission tower 1 may be an actual value included in a design generated during a transmission facility installation process, etc., or a coordinate value newly measured in the implementation process of the present invention, but is not limited thereto.

In the step of receiving the second pylon coordinate value (S520), the coordinate values (x, y, z) of the second transmission pylon 2 are received, and similarly to the above step (S510), an actual value is received or a newly measured value is received. It may be performed to receive coordinate values.

In another example, as shown in FIG. 5 , after the step ( S600 ) of calling the stored first pylon coordinate values and the second pylon coordinate values is performed, the first step of FIG. 3 , the reference pylon and the distance between the installation points of the interphase spacer A step (S100) of receiving an input may be performed.

This step (S600) may be performed to retrieve coordinate values from a non-volatile storage device that stores design related data, and the storage device is a processing device for performing the interphase spacer length calculation method according to an embodiment of the present invention or It may have a structure electrically connected to a computer-readable storage medium recording the method according to the present embodiment.

In another embodiment, the above step ( S600 ) may be performed to call coordinate values from a database storing design related data or a server including the same, and the database or server is an interphase spacer according to an embodiment of the present invention. It may have a structure communicatively connected to a processing device for performing the length calculation method or a computer-readable storage medium recording the method according to the present embodiment, and the embodiment of the above step (S600) is not limited.

As such, the method for calculating the length of the interphase spacer according to an embodiment of the present invention is performed after performing any one of the steps shown in FIG. 4 or FIG. 5, and thus the coordinate value of the pre-stored pylon or the newly measured coordinate value of the pylon can be used to calculate the interphase spacer length, and according to the interphase spacer length calculation method according to an embodiment of the present invention described with reference to FIGS. 3 to 5, the interphase spacer length is obtained accurately, It is possible to install a phase-to-phase spacer between two power lines with low cost and high accuracy.

Next, the interphase spacer length calculation device 200 according to an embodiment of the present invention will be described with reference to FIG. 6 , the interphase spacer length calculation device is the interphase spacer length calculation method described with reference to FIGS. 3 to 5 . As a performing apparatus, it may be configured to include an input unit 210 , an output unit 220 , an interphase spacer length calculation unit 230 , and a storage unit 240 .

In one example, the interphase spacer length calculation device 200 may be connected to the transmission tower measuring device 100 through wired communication or wireless communication, and when connected to the transmission tower measuring device 100 through wireless communication, in the drawing Although not shown, the interphase spacer length calculation device 200 and the transmission tower measuring device 100 may each include a communication module performing the same communication protocol.

At this time, the transmission tower measuring device 100 is a device for measuring the coordinate values of the first and second transmission towers 1 and 2 or the coordinate values of the power lines c1 and c2, and has already been used in the field to which the present invention is applied. It may be a portable type measuring device such as a measuring instrument, but is not limited thereto.

The input unit 210 of the interphase spacer length calculation device 200 is a configuration including at least one of a device for receiving text, voice information, or image information, such as a mouse, a touch input display, a keyboard, a microphone, a camera, and the like, The coordinate values of the second transmission towers 1 and 2 or the coordinate values of the power lines c1 and c2 are input. In an example in which the input unit 210 receives audio information or image information, the input unit 210 may further perform a process of extracting actual data such as coordinate values from the audio information or image information, and the corresponding processing It may include, but is not limited to, a processing device that performs the process or is connected to the processing device to extract actual data.

In another example, the input unit 210 may receive a value measured by the transmission tower measuring device 100 .

The output unit 220 may include a display device such as a monitor that outputs a value input from the input unit 210 or a calculation result of the interphase spacer length calculation unit 230, and a speaker that outputs sound, A GUI (Graphic User Interface) for receiving input can be output.

In one example, when the output unit 220 includes a speaker for outputting sound, the output unit 220 determines whether data is input by the input unit 210 , whether the input data is authentic, or the interphase spacer length calculation unit 230 . ), a specific alarm sound or a preset alarm sound according to each event may be output according to the occurrence of an event such as whether the calculation is terminated.

In addition, the interphase spacer length calculation unit 230 uses input information such as the coordinate values of the first and second transmission towers 1 and 2 or the coordinate values of the power lines c1 and c2 received by the input unit 210 . As a part of calculating the length of the interphase spacer to be installed between the power lines between the transmission towers, the input unit 210 or the communication unit (not shown) receives the values transmitted from the transmission tower measuring device 100 between the phases through Equation 1 above. Calculate the spacer length.

The storage unit 240 stores the coordinate values of the first and second transmission towers 1 and 2 and the power lines c1 and c2 received from the transmission tower measuring device 100 or input from the input unit 210, After storing the actual design value included in the design diagram of the power transmission facility, it may be provided to the interphase spacer length calculation unit 230 . At this time, in an example in which the storage unit 240 stores the actual design value included in the design and provides it to the interphase spacer length calculation unit 230 , the actual design value is stored in the interphase spacer length calculation unit 230 in the storage unit ( 240) may be provided in the form of referencing and extracting the actual design value stored in, but should not be limited thereto.

In an embodiment with reference to FIG. 6 , the storage unit 240 is illustrated as being included in the interphase spacer length calculation device 200, but in another embodiment, the storage unit 240 includes the interphase spacer length calculation device ( 200) It may be configured as a separate device externally, and may be implemented as a remote database or server through wired or wireless communication of a communication unit (not shown).

In this way, since the interphase spacer length calculation device 200 according to an embodiment of the present invention calculates the length of the interphase spacer to be installed between power lines between the transmission towers from the input value of the power transmission facility, the interphase spacer between the power lines for stability of the power transmission system In installing the spacer, it is possible to reduce the variable load cost and manpower cost required for installing the interphase spacer, and the effect of improving the reliability of the power transmission facility can be expected through the installation of the interphase spacer of the correct length.

In addition, in one example, the interphase spacer length calculation method and the interphase spacer length calculation device 200 according to an embodiment of the present invention, the interphase spacer length calculation system including the transmission tower measuring device 100 of FIG. ) to calculate the length of the interphase spacer.

And in one embodiment with reference to the drawings, two power lines are formed between transmission towers and described with reference to an example in which three interphase spacers are installed, but when three or more power lines are formed, or installation of interphase spacers The number is formed of at least one or more and can be applied even when four or more are installed. As such, even if the number of power lines and interphase spacers is different from the embodiment in this specification, it can be applied by changing the design of this embodiment Since there is a range, it will be extended in the context of the embodiments of the present invention.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improved forms of the present invention are also provided by those skilled in the art using the basic concept of the present invention as defined in the following claims. is within the scope of the right.

S: Interphase spacer length calculation system c1: First power line
c2: second power line d1: second power line
d2: 2nd power line 2nd road 1: 1st transmission tower
2: second transmission tower 11: first arm
12: second arm 21: third arm
22: fourth arm 31: first interphase spacer
32: second interphase spacer 33: third interphase spacer
100: transmission tower measuring device 111: first support point
121: second support point
200: interphase spacer length calculator 210: input unit
211: third support point 220: output unit
221: fourth support point 230: interphase spacer length calculation unit
240: storage

Claims (6)

It is performed in a processing device for calculating the length of at least one interphase spacer to be formed between at least two power lines installed between two transmission towers and having different poles,
receiving each input a distance between a reference tower, which is one of the two transmission towers, and an installation point of the at least one interphase spacer;
receiving a horizontal angle between the reference tower and the at least two power lines;
receiving a coordinate value of an installation point of the at least one interphase spacer on the at least two power lines; And,
calculating the length of the at least one interphase spacer using Equation 1 below;
Interphase spacer length calculation method performed including.
[Equation 1]

According to claim 1,
The step of receiving each input of the distance between the reference tower, which is one of the two transmission towers, and the installation point of the at least one interphase spacer,
receiving a coordinate value of the reference pylon; And,
Interphase spacer length calculation method, characterized in that after performing; receiving the coordinate values of the remaining transmission towers excluding the reference tower among the two transmission towers. According to claim 1,
The step of receiving each input of the distance between the reference tower, which is one of the two transmission towers, and the installation point of the at least one interphase spacer,
A method for calculating the length of an interphase spacer, characterized in that after performing; retrieving the coordinate values of the reference pylon stored in a separate storage device and the coordinate values of the remaining transmission pylons excluding the reference pylon among the two transmission pylons. an input unit for receiving coordinate values of two transmission towers and coordinate values of at least two power lines connected between the two transmission towers; And,
From the coordinate values of the two transmission towers received from the input unit and the coordinate values of at least two power lines connected between the two transmission towers, using Equation 1 below, at least two power lines connected between the two transmission towers. Interphase spacer length calculator comprising a; interphase spacer length calculation unit for calculating the length of the interphase spacer to be installed.
[Equation 1]

5. The method of claim 4,
The interphase spacer length calculation device further comprising; an output unit for outputting the interphase spacer length calculation result of the interphase spacer length calculation unit. 5. The method of claim 4,
The interphase spacer length calculating device further comprising a; storing the coordinate values of the two transmission towers as actual measured values of the design, and providing the stored measured values to the input unit.

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