KR102576981B1 - Apparatus for fixing distribution lines with lightning protection - Google Patents

Abstract

According to the present invention, a grounding facility for a power distribution pole comprises: a rainwater tank that is seated on the ground inside a power distribution pole to store rainwater flowing into the power distribution pole; and a grounding rod that grounds a grounding wire that passes through the power distribution pole underground. The grounding rod is implemented by a cylindrical conductor having one opened surface connected to a rainwater outlet of the rainwater tank, wherein pores are formed on a circumferential surface of the grounding rod to receive rainwater discharged from the rainwater tank and discharge it to the land through the pores so as to increase humidity around the land where the grounding rod is buried by using rainwater, thereby enabling efficient grounding.

Description

Grounding facilities for distribution poles{APPARATUS FOR FIXING DISTRIBUTION LINES WITH LIGHTNING PROTECTION}

The present invention relates to a grounding facility for distribution poles, and more specifically, to a grounding facility for distribution poles to quickly transfer overvoltage generated by lightning to the ground.

Electric power is transmitted from a power plant to a substation, often along distribution lines with concrete poles as supports, and then to homes through pole transformers on poles. However, distribution lines installed in this way prevent accidents from occurring in power facilities due to abnormal voltages such as ground faults, lightning, and surges, and prevent disasters from occurring due to short circuits. To do this, grounding is done.

At this time, grounding refers to electrically connecting a metal or conductive object to the ground and making its potential the same as the ground or minimizing the potential difference, thereby making the potential of an electric circuit or electrical device the same as the ground, thereby protecting people or people from sudden high voltages caused by lightning, etc. This refers to actions that help protect the building.

For this purpose, at least one grounding rod is usually buried around the electric pole, and the buried grounding rod is connected to a grounding wire drawn from the electric pole, so that the overvoltage generated by lightning is transmitted to the ground.

In relation to this, Korean Patent No. 10-1414271 discloses a bottom made of a non-conductive material and buried in the ground, an inner pipe and an outer pipe erected in the form of concentric circles so that electric pole insertion grooves are formed on the upper surface of the bottom. A support plate body consisting of; A lower cover, which is a plate with a grounding rod penetrating at the bottom and is provided with an anchoring rod that is fixed in the ground, and is coupled to form a space between the bottom of the support plate main body; a connection plate inserted between the bottom of the support plate body and the lower cover; a grounding rod inside the support plate body, one side of which is connected to the connection plate and the other side of which is connected to the ground; It is rotatably mounted on the inner tube of the support plate main body, and when the electric pole is inserted into the electric pole insertion groove of the support plate main body, the electric pole rotates so that the first connection end on one side is connected to the ground wire wired inside the electric pole, while the second connection end on the other side is connected to the ground wire wired inside the electric pole. A ground rod-integrated, floor-embedded support plate for an electric pole is disclosed, which is connected to the connection plate while the connection end is pressed against the electric pole and includes a ground wire connection port for energizing the ground wire, the connection plate, and the ground rod.

In this way, in the past, grounding was performed by burying a grounding rod under an electric pole or in the ground adjacent to an electric pole.

Typically, it is desirable to install such a grounding rod in a place where the soil is uniform and humid, where the water level is shallow, and where there is no risk of corrosion due to gases/acids, etc. This is to improve the durability of the grounding rod and enable grounding quickly.

However, as the installation locations of electric poles vary, it is not easy to find a location that satisfies all of the above conditions each time a grounding rod is installed. In particular, there was a lot of moisture in the ground at the time of installing the grounding rod, but the ground may become dry due to climate change, etc. In this case, problems may occur in which grounding is not performed efficiently.

Korean Patent No. 10-1414271

Therefore, the present invention seeks to provide a grounding facility for distribution poles that enables efficient grounding by using rainwater to increase the humidity around the ground where the grounding rod is buried.

In addition, the present invention stores rainwater flowing into distribution poles and controls the supply of moisture around the grounding rod when the amount of rainwater stored reaches a certain amount, thereby efficiently managing the humidity around the grounding rod even in areas with low rainfall. The goal is to provide grounding facilities for distribution poles.

In addition, the present invention stores rainwater flowing into a distribution pole and controls the supply of moisture around the grounding rod using the stored rainwater when a lightning strike is expected, thereby efficiently managing the humidity around the grounding rod in preparation for lightning strike. We would like to provide a grounding facility for distribution poles that allows this.

In addition, the present invention is a distribution pole that has a rainwater chamber for collecting rainwater within the pole, and safely guides rainwater from the top of the pole to the rainwater chamber, allowing rainwater to be collected safely without affecting other devices inside the pole. We intend to provide grounding facilities for use.

A grounding facility for a distribution pole according to an embodiment of the present invention for achieving the above-described task includes a rainwater tank that is seated on the ground inside the distribution pole and stores rainwater flowing into the distribution pole; And a grounding rod for grounding a grounding wire coming down through the distribution pole to the ground, wherein the grounding rod is implemented as a cylindrical conductor whose open side is connected to the rainwater outlet of the rainwater tank and a pore is formed on the circumferential surface, It is characterized in that rainwater discharged from the rainwater tank is introduced and discharged to the ground through the pores.

Preferably, the grounding facility for the distribution pole further includes a rainwater guide member that guides rainwater to be delivered to the rainwater tank, wherein the rainwater guide member includes a rainwater guide funnel mounted on the top of the distribution pole to collect rainwater; And it is inserted into the rainwater guide funnel and exposed upward to the distribution pole to catch lightning, and the end of the portion protruding from the lower part of the rainwater guide funnel is formed in a cone shape to guide the rainwater collected in the rainwater guide funnel to the rainwater tank. It may include a rainwater guide lightning rod.

Preferably, the rainwater guide funnel includes a flange portion extending over the top of the distribution pole; a funnel-shaped main body portion whose diameter narrows downward from the flange portion; A main hole formed in the center of the lower surface of the main body into which the rainwater guide lightning rod is inserted; And it may include a plurality of micro holes formed along the outer periphery of the main hole to allow rainwater to flow to the peripheral surface of the rainwater guide lightning rod.

Preferably, the rainwater tank includes a rainwater inlet formed in the shape of a funnel that opens toward the rainwater guide member to introduce rainwater delivered through the rainwater guide member; A rainwater storage tank that stores the inflow of rainwater; a rainwater outlet discharging the stored rainwater to one surface of the grounding rod; And it may include a rainwater discharge control unit that controls the opening/closing of the rainwater outlet based on the amount of rainwater stored in the rainwater storage tank or lightning information received from an external device.

The grounding facility for distribution poles provided by the present invention has the advantage of enabling efficient grounding by using rainwater to increase the humidity around the ground where the grounding rod is buried.

In addition, the present invention stores rainwater flowing into distribution poles and controls the supply of moisture around the grounding rod when the amount of rainwater stored reaches a certain amount, thereby efficiently managing the humidity around the grounding rod even in areas with low rainfall. There is an advantage in allowing it to happen.

In addition, the present invention stores rainwater flowing into a distribution pole and controls the supply of moisture around the grounding rod using the stored rainwater when a lightning strike is expected, thereby efficiently managing the humidity around the grounding rod in preparation for lightning strike. There is an advantage to being able to do this.

In addition, the present invention has the advantage of providing a rainwater chamber for collecting rainwater within the electric pole and safely guiding rainwater from the top of the electric pole to the rainwater chamber, allowing rainwater to be collected safely without affecting other devices inside the electric pole. there is.

Figure 1 is a perspective view of a grounding facility for a distribution pole according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of a grounding facility for a distribution pole according to an embodiment of the present invention.
Figure 3 is a cross-sectional view of a grounding facility for a distribution pole according to an embodiment of the present invention.
Figures 4 to 6 are diagrams for explaining the operating state of the grounding facility for distribution poles according to an embodiment of the present invention.

Below, embodiments of the present invention will be described with reference to the attached drawings, and will be described in detail so that those skilled in the art can easily practice the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. Meanwhile, in order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification. In addition, descriptions of parts that can be easily understood by those skilled in the art are omitted even if detailed descriptions are omitted.

Throughout the specification and claims, when it is said that a part includes a certain component, this means that other components may be further included rather than excluding other components unless specifically stated to the contrary.

Figure 1 is a perspective view of a grounding facility for a distribution pole according to an embodiment of the present invention, Figure 2 is an exploded perspective view of a grounding facility for a distribution pole according to an embodiment of the present invention, and Figure 3 is an embodiment of the present invention. This is a cross-sectional view of a grounding facility for a distribution pole according to an embodiment.

Referring to Figures 1 to 3, a grounding facility for a distribution pole according to an embodiment of the present invention includes a rainwater guide member 100, a rainwater tank 200, and a ground rod 300.

The rainwater guide member 100 guides rainwater flowing into the distribution pole 100 to be delivered to the rainwater tank 200 and includes a rainwater guide lightning rod 110 and a rainwater guide funnel 120.

The rainwater guide lightning rod (110) is inserted into the rainwater guide funnel (120) and exposed upward to the distribution pole (10) to intercept lightning. The overvoltage generated at this time is transmitted to the ground rod 300 through the ground wire 20 and transmitted to the ground.

Meanwhile, the end 111 of the rainwater guide lightning rod 110 protruding from the lower part of the rainwater guide funnel 120 is formed in a cone shape with a sharp end, as illustrated in the drawing, and collects the rainwater collected in the rainwater guide funnel 120. It is guided so that it does not spread to other places and is delivered to the rainwater tank (200). In other words, the rainwater collected in the rainwater guide funnel 120 flows down along the outer peripheral surface of the rainwater guide lightning rod 110, and is collected at the sharp end 111 and then settled in the lower part of the distribution pole 10. By falling into the tank 200, rainwater is prevented from affecting other areas inside the distribution pole 10. For this purpose, the end 111 of the rainwater guide lightning rod 110 must extend toward the upper part of the rainwater inlet 210 of the rainwater tank 200, which will be described later, and the rainwater guide lightning rod 110 protrudes from the lower part of the rainwater guide funnel 120. ) is preferably determined to be sufficient to guide the rainwater to the rainwater inlet 210 of the rainwater tank 200.

The rainwater guide funnel 120 is mounted on the top of the distribution pole 10 and collects rainwater. For this purpose, the rainwater guide funnel 120 includes a flange portion 121 spanning the top of the distribution pole 10, a funnel-shaped body portion 122 whose diameter narrows downward from the flange portion 121, and a body portion ( 122) A main hole 123 formed in the center of the lower surface into which the rainwater guide lightning rod 110 is inserted, and a plurality of fine holes formed along the outer circumference of the main hole 123 to flow rainwater to the peripheral surface of the rainwater guide lightning rod 110. May include holes 124.

At this time, a rubber seal having a certain elasticity may be attached to the inner periphery of the main hole 123 so that the rainwater guide lightning rod 110 inserted into the main hole 123 does not flow down and maintains its height.

It is preferable that the micro holes 124 are formed densely and have a diameter suitable for rainwater to flow down. Additionally, in order to facilitate the flow of rainwater, the cross section can be formed by cutting it obliquely into a streamlined shape.

Figure 3A is an enlarged view of the rainwater guide member 100, illustrating the combined state of the rainwater guide lightning rod 110 and the rainwater guide funnel 120 in an enlarged manner.

The rainwater tank 200 is seated on the ground inside the distribution pole 10 and stores the rainwater. For this purpose, the rainwater tank 200 is formed in the shape of a funnel that opens toward the rainwater guide member 100 (i.e., the end 111 of the rainwater guide lightning rod 110) to introduce rainwater delivered through the rainwater guide member. A rainwater inlet 210, a rainwater storage container 220 for storing the inflow of rainwater, a rainwater outlet 230 for discharging the stored rainwater to an open surface 310 of a ground rod 300, which will be described later, and a rainwater outlet 230. ) may include a cover 240 that opens/closes. In addition, it may include a rainwater discharge control unit (not shown) that controls the opening/closing of the rainwater discharge port 230 by manipulating the cover 240.

The rainwater discharge control unit (not shown) can be implemented in the form of a small chip, and has no structural significance, so it is not separately shown in the drawings.

The rainwater discharge control unit (not shown) may control the opening/closing of the rainwater outlet 230 based on the amount of rainwater stored in the rainwater storage tank 220 or lightning information received from an external device. For this purpose, it further includes a sensor that measures information that can predict the amount of rainwater stored, such as the water level or weight inside the rainwater storage tank 220, and the rainwater discharge control unit (not shown) uses the information received from the sensor to determine the amount of rainwater stored. After predicting, if the rainwater storage amount exceeds the rainwater storage amount preset to determine whether to discharge rainwater, the rainwater outlet 230 can be controlled to open. Alternatively, it further includes a device that provides a communication interface with an external device (e.g., a Korea Meteorological Administration server, etc.) that transmits information from an external agency (e.g., the Korea Meteorological Administration, etc.) predicting whether lightning strikes, and the rainwater discharge control unit (not shown) is the After receiving climate information from an external device, the rainwater outlet 230 can be controlled to open when lightning is predicted.

The grounding rod 300 not only grounds the grounding wire 20 coming down through the distribution pole 10 to the ground, but also draws in rainwater discharged from the rainwater tank 200 and discharges it to the surrounding ground to the grounding rod 300. Increases the humidity of adjacent land. This is to ensure that the overvoltage transmitted by lightning can quickly flow to the ground.

For this purpose, the ground rod 300 is implemented as a cylindrical conductor in which one open surface (i.e., open surface) 310 is connected to the rainwater outlet 230 of the rainwater tank 200 and a pore 320 is formed on the circumferential surface. You can. In addition, a flange 330 for coupling with the rainwater tank 200 may be formed on the upper part of the ground rod 300 on which the open surface 310 is formed, and a flange ( A coupling groove for coupling with 330) may be additionally formed.

B in FIG. 3 is an enlarged view of the rainwater tank 200, and in particular, the structures of the rainwater inlet 210 and the rainwater outlet 230 are enlarged and illustrated. Referring to B of FIG. 3, an inflow control cover 211 may be added to the bottom of the inlet 210. The inflow control cover 211 is opened downward by the water pressure generated by the accumulation of rainwater, thereby allowing rainwater to flow into the rainwater. It can be moved to the storage bin (220). In addition, referring to B of FIG. 3, the connection structure of the cover 240 installed on the top of the rainwater outlet 230 and the coupling structure of the rainwater outlet 230 and the ground rod 300 can be confirmed.

Figures 4 to 6 are diagrams for explaining the operating state of the grounding facility for distribution poles according to an embodiment of the present invention. Figure 4 shows that the rainwater (W) collected in the rainwater guide funnel 120 flows to the outer peripheral surface of the rainwater guide lightning rod 110 through the micro hole 124, and then flows down the outer peripheral surface of the rainwater guide lightning rod 110, Showing an example of rainwater falling through the end 111 of the rainwater guide lightning rod 110, Figure 5 shows the rainwater (W) falling through the end 111 of the rainwater guide lightning rod 110 at the inlet 210 of the rainwater tank 200. ), and the inflow control cover 211 is opened by the water pressure, showing an example in which rainwater (W) is stored in the rainwater storage tank 220, and Figure 6 shows an example in which rainwater (W) is stored in the rainwater discharge control unit (not shown). This shows an example in which the cover 240 is opened and the rainwater (W) stored in the rainwater storage tank 220 flows into the grounding rod and flows to the ground through the pores 320 formed on the circumferential surface of the grounding rod.

As described above, the grounding facility for distribution poles of the present invention has the feature of enabling efficient grounding by using rainwater to increase the humidity around the ground where the grounding rod is buried.

In addition, the present invention stores rainwater flowing into distribution poles and controls the supply of moisture around the grounding rod when the amount of rainwater stored reaches a certain amount, thereby efficiently managing the humidity around the grounding rod even in areas with low rainfall. There is a feature that allows it.

In addition, the present invention stores rainwater flowing into a distribution pole and controls the supply of moisture around the grounding rod using the stored rainwater when a lightning strike is expected, thereby efficiently managing the humidity around the grounding rod in preparation for lightning strike. There are features that allow you to do this.

In addition, the present invention has a rainwater chamber for collecting rainwater within the electric pole, and safely guides rainwater from the top of the electric pole to the rainwater chamber, allowing rainwater to be collected safely without affecting other devices inside the electric pole. there is.

Although the embodiments of the present invention have been described above, the scope of the rights of the present invention is not limited thereto, and the present invention can be easily modified from the embodiments by those skilled in the art in the technical field to which the present invention belongs and is recognized as equivalent. Includes all changes and modifications to the extent permitted.

10: Distribution pole 20: Ground wire
100: Rainwater guide member 110: Rainwater guide lightning rod
120: Rainwater guide funnel 121: Flange part
122: main body 123: main hole
124: Micro hole 200: Rainwater tank
210: Rainwater inlet 220: Rainwater storage tank
230: Rainwater outlet 240: Cover
300: ground rod 310: open side
320: porous

Claims (4)

In the grounding facility for distribution poles,
A rainwater tank that is seated on the ground inside a distribution pole and stores rainwater flowing into the distribution pole;
A grounding rod that connects the grounding wire passing through the distribution pole to the ground; and
It includes a rainwater guide member that guides rainwater to be delivered to the rainwater tank,
The ground rod is
It is implemented as a cylindrical conductor whose open side is connected to the rainwater outlet of the rainwater tank and pores formed on the circumferential surface, so that rainwater discharged from the rainwater tank flows in and is discharged to the ground through the pores,
The rainwater guide member is
A rainwater guide funnel mounted on the top of the distribution pole to collect rainwater; and
It is inserted into the rainwater guide funnel and exposed upward to the distribution pole to catch lightning, and the end of the portion protruding from the lower part of the rainwater guide funnel is formed in a cone shape to guide the rainwater collected in the rainwater guide funnel to the rainwater tank. A grounding facility for distribution poles, characterized in that it includes a rainwater guide lightning rod. delete The method of claim 1, wherein the rainwater guide funnel is
A flange portion spanning the top of the distribution pole;
a funnel-shaped main body portion whose diameter narrows downward from the flange portion;
A main hole formed in the center of the lower surface of the main body into which the rainwater guide lightning rod is inserted; and
A grounding facility for a distribution pole, characterized in that it includes a plurality of fine holes formed along the outer periphery of the main hole to allow rainwater to flow to the circumferential surface of the rainwater guide lightning rod. The method of claim 1, wherein the rainwater tank is
A rainwater inlet formed in the shape of a funnel that opens toward the rainwater guide member to introduce rainwater transmitted through the rainwater guide member;
A rainwater storage tank that stores the inflow of rainwater;
a rainwater outlet discharging the stored rainwater to one surface of the grounding rod; and
A grounding facility for distribution poles, comprising a rainwater discharge control unit that controls opening/closing of the rainwater discharge outlet based on the amount of rainwater stored in the rainwater storage tank or lightning information received from an external device.

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