KR102204629B1 - Band type ground electrode for replacing mesh ground cable - Google Patents

Abstract

The present invention relates to a strip-type grounding electrode for replacing a mesh grounding cable, and the strip-type grounding electrode for replacing a mesh grounding cable according to the present invention is composed of a strip-shaped grounding plate that can be wound in a roll shape, and the width of the grounding plate is The central portion of the direction is perforated to form a hollow portion, which is an empty space, and a plurality of the hollow portions are continuously formed at intervals along the direction of winding or unwinding in the form of a roll of the grounding plate.

Description

Band type ground electrode for replacing mesh ground cable {BAND TYPE GROUND ELECTRODE FOR REPLACING MESH GROUND CABLE}

The present invention relates to a ground electrode, and more particularly, to a strip-shaped ground electrode that can replace a mesh ground cable.

In the conventional grounding technology using copper, the grounding body has a rod electrode with a vertical depth structure, a plate electrode with a horizontal contact structure, a ring electrode, and a mesh ground electrode, a buried branch line with a horizontal length structure, and a three-dimensional building structure. There is.

Among them, the rod-shaped electrode has a high construction cost, and the plate-shaped electrode has good grounding resistance in theory, but it is not used well due to pore corrosion problems, the annular electrode is not well used, and the mesh ground electrode is limited to the ground network of a large power plant, and is buried. Branch lines are used for transmission towers, but there is a trend of decreasing due to the large number of excavations in mountainous areas, and building structures are limited to buildings.

The grounding configuration of the mesh wire, which is most widely used among ground electrodes using copper materials, is as shown in FIGS. 1A and 1B.

The mesh ground is widely used for the purpose of securing an equipotential while maintaining low resistance in a wide site such as a power substation, but a high potential may be partially maintained just above the part where the ground wire is buried. In order to solve this problem, the mesh spacing is tighter, and for economical design, a separate auxiliary grounding is implemented with a grounding rod, a carbon grounding rod, or a boring grounding, which increases the cost of grounding construction.

In addition, the ground wire for mesh grounding is a method in which a bare copper wire is twisted and laid under the ground surface, and has a problem that the earth contact area is small, so that the ability to reduce the ground resistance is significantly lower than that of the plate type.

Republic of Korea Patent Publication No. 2009-0037223

The present invention was conceived to solve the problems of the prior art, and the present invention can maximize the grounding effect, thereby reducing construction costs, and utilizing the mesh grounding result of the existing commercial folding program as it is, and in a roll form. It is configured so that it is possible to quickly process the project by shortening the construction time, and the potential rise is flattened to minimize the voltage such as stride voltage and contact voltage to ensure physical safety, and power equipment such as transformers by the flattening of the ground potential rise in case of a ground fault. Its purpose is to provide a strip-shaped grounding electrode for replacement of a mesh grounding cable having an insulation stabilization effect of.

The strip-shaped grounding electrode for replacing the mesh grounding cable according to the present invention for achieving the above object is composed of a strip-shaped grounding plate that can be wound in a roll shape, and the center part of the width direction of the grounding plate is perforated. As a result, a hollow portion, which is an empty space, is formed, and a plurality of the hollow portions are continuously formed at intervals along the winding or unwinding direction in the form of a roll of the grounding plate.

In addition, the area occupied by the hollow portion is preferably 40 to 80% of the total area of the combined area of the ground plate and the area of the hollow portion.

In addition, it is preferable that a discharge protrusion that can be used standing at a right angle to the grounding plate is provided at a portion between the hollow portions adjacent to each other among the grounding plate material.

In addition, it is preferable that a center hole for connecting a grounding rod or connecting a ground line is formed through a portion between the hollow portions adjacent to each other among the grounding plate material.

In addition, it is preferable that the hollow portion has a shape of any one of a triangle, a square, a polygon, and a circle.

In addition, the grounding plate is preferably any one of a copper plate, a stainless steel plate, and a galvanized steel plate.

In addition, it is preferable that both ends of the mesh wire made of a metal ground wire are connected to the grounding plate material surrounding the hollow portion to cross the inside of the hollow portion.

As described above, according to the belt-type ground electrode for replacing a mesh ground cable according to the present invention, the following effects are obtained.

First, the construction cost is reduced by maximizing the grounding effect of the new concept grounding body, so that it is possible to cover even places where it is difficult to satisfy the grounding resistance value with the conventional technology, and the strip-shaped grounding electrode is applied to a buried branch line or other shape grounding electrode. Compared to this, it is suitable for lightning protection or surge countermeasures because it has a large effect of reducing the ground resistance, especially the transient ground impedance. In particular, it has a feature of excellent grounding effect in areas with large earth resistivity.

Second, since the result of the conventional grounding calculation commercial program can be used as it is, the grounding network design can be systematized and optimized through an economical and efficient configuration. It is possible to calculate the minimum thickness of the general mesh ground wire corresponding to the fault current value, and this calculated value can be used as it is, and the grounding design can be made to have the same cross-sectional area.

Third, it is configured in a roll form, reducing construction time and contributing to the rapid process progress of the project. The copper plate processed in the factory can be punched into the required shape using a press machine, etc., and transported in a roll form and spreading on the excavated site without special equipment such as boring equipment or striking equipment to complete the grounding work. This is possible.

Fourth, since the potential rise is flattened, it is possible to minimize voltages for the safety of the human body, such as step voltage and contact voltage. In the conventional method in which the mesh ground wire is installed in a grid pattern 60cm below the ground substation site, the potential for fault current energization rapidly rises in the ground directly above the ground wire to form a dangerous voltage. Therefore, after precisely calculating with the grounding calculation program, the mesh gap is narrowed to the optimum through recalculation of the dangerous voltage. As shown in FIG. 13, the potential rise is largely measured only in the vicinity of the mesh ground line. In the case of using the present invention, since the peak-to-peak value is lowered and the mesh spacing may be wider, the grounding construction cost is reduced.

Fifth, due to the flattening of the ground potential rise (GPR) in case of a ground fault, there is an effect of stabilizing insulation of power devices such as transformers.

That is, in the present invention, the grounding potential rise of the ground electrode directly above the ground electrode is low and the overall plant grounding resistance is low compared to the conventional mesh wire, so that the grounding design can be economical.

1A is an example of a conventional mesh ground design.
Figure 1b is a configuration diagram showing a conventional mesh ground ground resistance.
2 is a plan view showing a strip-shaped ground electrode for replacing a mesh ground cable according to an embodiment of the present invention.
3 is a front view showing a strip-shaped grounding electrode for replacing a mesh grounding cable according to an embodiment of the present invention.
Figure 4 is a perspective view showing a belt-type ground electrode for replacing a mesh ground cable according to an embodiment of the present invention.
9A and 9B are a combined perspective view and an exploded perspective view showing a state in which a protrusion for discharging a transient voltage is coupled to a ground electrode according to the embodiment shown in FIG. 8.
10 is a graph showing the correlation between the area of the ground electrode and the ground resistance, and the ground resistance is not reduced in proportion to the area of the copper plate, and it is a graph showing that it is more efficient to increase the lengthwise direction by making a band electrode having a hollow rather than an area.
11A to 11D are diagrams showing the results of measuring the grounding resistance by putting the grounding plate into the experimental tank while sequentially removing it from the center at intervals of 10% of the total.
12 is a configuration diagram of a ground resistance of the present invention.
13 is a diagram showing the types and distribution of voltages applied to the human body.

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

The belt-type grounding electrode for replacement of the mesh grounding cable according to the present invention is for a grounding device in a modified form of a buried branch line widely used in power substations, etc., by processing a strip-shaped grounding plate to remove the center of low grounding effect and It is designed to increase the contact area with the ground and to easily discharge potential to the ground by arranging a support with a hole through which a protrusion and a ground rod can be drilled in the direction.

Since the ground electrode according to the present invention is similar in shape or structure to the structure of the plate-shaped grounding electrode, in order to understand the effect of the central part of the plate-shaped grounding plate on the reduction of the grounding resistance, first, the characteristics in the grounding resistance calculation formula and two types of experiments Let's look at the case.

The copper plate grounding is a grounding that uses a square-shaped copper plate as a grounding body, which is also used as a plate-shaped grounding, and consists of a lead wire connected to a square-shaped copper plate, and the grounding resistance calculation formula that has been widely used in the past is as follows.

이며, 여기서 R: 접지판의 접지 저항(Ω), t: 매설 깊이(cm), ρ: 대지 고유 저항(Ω·m),

이다.That is, the ground resistance by the ground plate is

Where R: ground resistance of the ground plate (Ω), t: buried depth (cm), ρ: earth specific resistance (Ω m),

to be.

Analyzing this equation, it is possible to find the correlation between the ground area of the square ground copper plate and the ground resistance as shown in FIG. 10. It can be seen that the relationship is not directly proportional to each other, but decreases in an inverse proportion to the log function. The contribution of the central part to the grounding effect is very low, and thus it can be seen that the optimal copper plate structure can be economically considered through the removal of the central part.

The table below shows the results of measuring the ground resistance by putting the ground copper plate of 30 x 30 cm into the experimental tank while removing it from the center at 10% area intervals of the total as shown in FIGS. 11A to 11D.

Through such an experiment, it can be seen that the central part does not contribute much to the earthing resistance, and thus it can be seen that it is very economical and efficient to use a hollow earthing plate-type structure as a earthing electrode. It is based on the foundation.

2 to 4 are plan, front and perspective views showing a strip-shaped ground electrode for replacing a mesh ground cable according to an embodiment of the present invention.

The belt-shaped grounding electrode for replacing a mesh grounding cable according to the present invention includes a grounding plate 10, discharging protrusions 20 and 40, and a central hole 30.

The grounding plate 10 is a copper plate having a thickness of 0.1 to 2t having a strip shape, and is rolled in a roll shape and used. A rectangular hollow part 11 is formed in the center of the ground plate 10 in the width direction to be filled with soil. Due to the presence of the hollow part 11, the grounding plate 10 covers a large area and has the same cross-sectional area as the mesh wire. The hollow part 11 is continuously formed at regular intervals along the length direction of the strip-shaped grounding plate 10.

The grounding plate 10 is based on a copper plate, but is included in the material of the grounding plate 10 including stainless steel or galvanized steel to apply to places where corrosion is a concern. This includes the method of vertical construction.

From the above experimental results, the ratio of only the hollow part 11 of the combined area of the grounding plate 10 and the hollow part 11 should be 40% or more to be effective. Of course it can be done otherwise. In this embodiment, when the width of the grounding plate 10 is 100 to 1000 mm, the length in the width direction of the hollow part 11 is 60 to 600 mm, and the length in the length direction of the hollow part 11 is 100 to 5000 mm. The ratio occupied by the hollow part 11 is approximately 60 to 70%.

Discharge protrusions (20, 40) are provided in two portions between the two adjacent hollow portions (11) of the grounding plate (10), and are intended to suppress the rise of the transient impulse potential. It is used in a state in which the dedicated protrusions (20, 40) are bent to form a right angle with the grounding plate (10) so that they protrude sharply.

Discharge protrusions 20 and 40 are sharp isosceles triangle-shaped discharge protrusions 20 and 40 in the center between the hollow part 11 and the outer edge of the grounding plate 10 as shown in FIGS. 5 to 7. ), and as shown in FIG. 8, a gap is provided at each of the outer edge of the grounding plate 10 and the inner edge of the hollow 11 of the grounding plate 10 It may be configured by cutting a portion of the discharge protrusions 20 and 40 in the form of a plurality of pointed right-angled triangles.

The circular central hole 30 is formed in the middle of the portion between the discharging protrusions 20 and 40, and the central hole 30 is for the purpose of connecting the ground wire or for fixing the roll to the wall of the rectangular cube excavated during vertical construction. Or, it is formed for the purpose of using by hitting the location of a grounded copper rod or a deep rod when necessary.

9A shows a state in which a surge discharge protrusion 60 is coupled to the central hole 30 so as to protrude in the horizontal direction, and FIG. 9B shows a surge discharge protrusion in the central hole 30. It shows the appearance before combining 60) to protrude in the vertical direction.

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As shown in Fig. 12, in the case of the present invention, since the electric circuit is configured in a plurality of parallel structures, the resistance value is reduced.

As in the above description, the present invention has been described only for preferred specific examples, but the present invention is not limited to these examples and can be changed by anyone of ordinary skill without departing from the basic principles and gist of the present invention. Including, and contributing to the advancement of the ground resistance reduction technology in the field of power grounding technology through faithful implementation of the principle will be said to be the technical spirit of the present invention.

The use of the belt-type grounding electrode for replacement of the mesh grounding cable according to the present invention is the grounding network of power plants and substations, power outlets, common outlets, duct banks, train tunnels, vehicle tunnels, railroad tracks, transmission tower buried branch lines replacement, the lower part of the steel tower foundation, and Power plant foundation and surrounding land, various manholes, etc.

10: ground plate 11: hollow part
20, 40: discharge protrusion 30: central hole
60: Over-voltage discharge needle

Claims (7)

It is composed of a strip-shaped grounding plate that can be wound in a roll form,
A hollow portion is formed by removing and perforating the central portion of the grounding plate positioned between both edge portions in the width direction of the grounding plate from the grounding plate having a predetermined length,
A plurality of the hollow portions are continuously formed at intervals along the winding or unwinding direction in the form of a roll of the grounding plate,
Consisting of both edge portions in the width direction of the grounding plate and a portion between the hollow portions adjacent to each other among the grounding plates, and the circumferential portion surrounding the hollow portion in all directions is made of a plate made of a metal material,
The area occupied by the hollow part is a belt-type ground electrode for replacing a mesh ground cable, characterized in that 0.7 to 4 times the area of the circumferential part. delete The method of claim 1,
A strip-type grounding electrode for replacing a mesh grounding cable, characterized in that a discharge protrusion that can be used standing at a right angle to the grounding plate is provided at a portion between the hollow portions adjacent to each other among the grounding plate material. The method of claim 1,
A belt-type ground electrode for replacing a mesh grounding cable, characterized in that a center hole for connecting a grounding rod or a ground line is formed through a portion between the adjacent hollow portions of the grounding plate material. delete delete delete

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