KR101324102B1 - Grounding electrode for electrical resistivity survey - Google Patents

Abstract

PURPOSE: A ground electrode for detecting electric non-resistance is provided to be effectively installed in the ground which forms hard layers. CONSTITUTION: A ground electrode (A) for detecting electric non-resistance comprises a first pipe body (10), a second pipe body (20), a screw member (30), and an opened or closed member (40). The first pipe body is formed with metal and includes a protruded piece (11) at both sides of an upper end unit. The second pipe body fills aqueous solution in the first pipe body. The screw member is combined with a lower end of the first pipe body and includes a vertical flow path (31) or a horizontal flow path. The opened or closed member is combined with the upper end of the first pipe body and blocks the first pipe body from being opened.

Description

Grounding electrode for electrical resistivity survey

The present invention relates to a grounding electrode, and more particularly, it can be inserted into the ground by a screw rotation method to facilitate the installation on the ground, as well as to supply the aqueous electrolyte solution continuously to the soil in the installation state The present invention relates to an electrical resistivity probe grounding electrode capable of increasing grounding performance in soils with low water content.

Electrical resistivity surveys are used to detect conductive ores, groundwater or environmental pollution.

At this time, the electrical resistivity sensing method is a method of identifying the internal structure of the ground by sending a direct current or a low frequency alternating current through the ground electrode and measuring the potential difference with another ground electrode to grasp the distribution of the electrical resistivity in the basement.

On the other hand, the electrical resistivity sensing grounding electrode used in the electrical resistivity sensing method is made of a conductive metal such as aluminum or iron, and is formed in a rod shape as shown in FIG.

The electrical resistivity probe grounding electrode was installed on the ground to allow current to flow and to measure the potential difference. However, the conventional resistivity probe ground electrode A 'has a simple bar shape as shown in FIG. If the soil forms a hard layer, the insertion itself into the ground is not easy, there was a problem that is difficult to install on the ground.

In addition, the conventional electrical resistivity probe ground electrode (A ') has a problem that the precision can not be made precisely because the grounding performance is greatly reduced when the water content of the soil, such as sand alluvial layer.

For this reason, the field is attempting to develop an electrical resistivity probe grounding electrode that can be easily installed on the ground regardless of the type of soil, as well as to secure grounding performance in soils with low water content. To date, no satisfactory results have been obtained.

The present invention has been proposed in view of the above situation, and it is easy to insert into the ground, which is difficult to install, and the electrical resistivity probe to solve the problem that the grounding performance is reduced in the soil with low water content The purpose is to provide a ground electrode for use.

Electrical resistivity probe grounding electrode according to the present invention for achieving the above object,

A first tube made of metal and provided with protruding pieces on both sides of the upper end portion;

A second tube body embedded in the first tube body and filled with an aqueous electrolyte solution;

A screw member coupled to a lower end of the first pipe, and made of metal, and having a vertical flow path and a horizontal flow path leading to the vertical flow path;

Coupled to the upper end of the first tube, characterized in that it comprises an opening and closing member to block the internal opening of the first tube.

Here, the first pipe is characterized in that a plurality of long holes with a difference in height is provided.

And the second tube is characterized in that the transparent acrylic.

And the screw member is made of brass, it is characterized in that the tip is pointed downward gradually toward the lower diameter.

And the opening and closing member is characterized in that the opening degree of the first pipe body is adjusted by loosening or tightening the bolt.

The ground resistance electrode for electric resistivity survey according to the present invention is a screw member coupled to the bottom of the first tube, and when the first tube is rotated while the tip of the screw member is brought into contact with the ground, the tip of the screw member penetrates the ground. Therefore, even if the soil forms a solid layer has an effect that can be easily installed.

In addition, the electrical resistivity probe grounding electrode according to the present invention is that the electrolyte is filled in the second tube, the electrolyte solution filled in the second tube is continuous in the soil through the vertical passage and the horizontal passage provided in the screw member Since it can be supplied to the power can be made smoothly with the soil has the effect of increasing the grounding performance.

1 is an exploded perspective view for explaining the structure of the grounding electrode for electrical resistivity survey according to the present invention
Figure 2 is a cross-sectional view of the coupling state for explaining the structure of the electrical resistivity probe ground electrode according to the present invention
Figure 3 is an exemplary view for explaining the installation of the electrical resistivity probe grounding electrode according to the present invention
Figure 4 is an exemplary view for explaining the discharge of the aqueous electrolyte solution from the electrical resistivity probe ground electrode according to the present invention
Figure 5 is an exemplary view for explaining the discharge control of the electrolyte solution in the electrical resistivity probe ground electrode according to the present invention
Figure 6 is an exemplary view for explaining the confirmation of the remaining amount of the electrolyte solution in the electrical resistivity survey ground electrode according to the present invention
Figure 7 is a front view showing the form of the grounding electrode for general electrical resistivity survey

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

As shown in FIGS. 1 and 2, the electrical resistivity probe ground electrode A according to the present invention includes a first tube 10, a second tube 20, a screw member 30, and an opening / closing member ( 40).

The first tube 10 is made of metal, and the protruding pieces 11 are provided on both sides of the upper end portion.

It is preferable that such a 1st tubular body 10 is provided with the some long hole 12 which differs in height.

By providing a plurality of long holes 12 with different heights in the first pipe body 10, the inside of the first pipe body 10 can be visually confirmed through the long holes 12.

Meanwhile, spirals 13 are provided on the upper and lower inner circumferential surfaces of the first pipe body 10.

Since the spirals 13 are provided on the upper and lower inner peripheral surfaces of the first pipe body 10, the screw member 30 may be coupled to the lower pipe through the spiral bit on the lower end of the first pipe body 10, and the upper surface of the first pipe body 10 may be combined. Opening and closing member 40 can be coupled through the helical bite.

The second tubular body 20 is embedded in the first tubular body 10, and the electrolyte solution 21 is filled therein.

It is preferable that such a 2nd tubular body 20 becomes a transparent body especially a transparent acryl.

When the second tubular body 20 is made of transparent body, especially transparent acrylic, and the inside of the first tubular body 10 is confirmed through the long hole 12 of the first tubular body 10, the electrolyte solution filled in the second tubular body 20 is filled. It is possible to grasp the remaining amount of (21), it is possible to minimize the damage of the second tube 20 due to the impact from the outside.

 The screw member 30 is to be coupled to the lower end of the first pipe body 10, made of a metal, the vertical flow path 31 and the horizontal flow path 32 connected to the vertical flow path 31 is provided.

Such a screw member 30 is directed toward the bottom and gradually decreases in diameter so that the tip is pointed.

As the screw member 30 faces downward and gradually decreases in diameter, the tip becomes sharp, so when the tip rotates the screw member 30 in contact with the ground, the sharp member penetrates the ground 100, so the screw member 30 becomes It can be easily inserted into the ground (100).

On the other hand, the screw member 30 may be any metal, but preferably made of brass.

Since the screw member 30 is made of brass, it is possible to minimize the decrease in hardness and strength while increasing the conductivity of the screw member 30.

The opening and closing member 40 is to be coupled to the upper end of the first tube 10, to block the internal opening of the first tube 10.

Such opening and closing member 40 is preferably in the form of bolts.

Since the opening and closing member 40 is in the form of a bolt, the opening degree of the first pipe body 10 is adjusted by loosening or tightening the opening and closing member 40, so that the opening of the first pipe body 10 can be adjusted through the opening and closing member 40. As a result, the air inflow amount into the first pipe body 10 is controlled to control the discharge rate of the electrolyte solution 21 from the second pipe body 20 to the soil.

At this time, the opening and closing member 40 may be toward the bottom and gradually decrease in diameter.

As the opening and closing member 40 toward the lower side and gradually decreases in diameter, when the opening and closing member 40 is gradually released, a gap is gradually generated between the opening and closing member 40 so that the opening degree of the first tube 10 is adjusted. This can be done more smoothly.

The installation of the electrical resistivity probe grounding electrode A according to the present invention as described above is as follows.

The electrical resistivity probe ground electrode A according to the present invention is installed in the ground 100 as the screw member 30 is inserted into the ground 100.

That is, in the present invention, the screw member 30 is coupled to the lower end of the first pipe body 10, and the protruding pieces 11 are provided at both sides of the upper end of the first pipe body 10, as shown in FIG. 3. When the first tube 10 is rotated by holding the protruding pieces 11 on both sides of the upper end of the first tube 10, the screw member 30 is rotated and the screw member 30 is inserted into the ground. The electrical resistivity probe ground electrode A can be installed on the ground 100.

At this time, the screw member 30 is directed toward the bottom and gradually decreases in diameter, so that the tip is sharpened, so that the tip of the screw member 30, which is rotated, easily penetrates the ground, even though the soil forms a hard layer. Installation can be made easily.

The electrical resistivity probe grounding electrode (A) according to the present invention installed through the above process can increase the grounding performance even in soils with low water content.

This will be described in detail as follows.

In the present invention, the second pipe body 20 filled with the electrolyte solution 21 is embedded in the first pipe body 10, and the vertical channel 31 is disposed in the screw member 30 under the second pipe body 20. And a horizontal flow passage 32 extending from the vertical flow passage 31, the electrolyte solution 21 filled in the second tube 20 in the state where the screw member 30 is located in the ground, as shown in FIG. Likewise, it extends to the soil through the vertical passage 31 and the horizontal passage 32 provided in the screw member 30.

At this time, the screw member 30 is coupled to the first pipe body 10, the current applied to the first pipe body 10 by the wiring (not shown in the drawing) can be transmitted to the screw member (30). Since the screw member 30 is made of brass and has excellent conductivity, the electric current transmitted to the screw member 30 can be smoothly transmitted to the soil containing the electrolyte aqueous solution 21, thereby improving grounding performance even in soils with low water content. It can be increased.

In the above process, the electrical resistivity probe ground electrode A according to the present invention may control the discharge of the electrolyte aqueous solution 21.

That is, in the present invention, the opening and closing member 40 in the form of a bolt is provided at the upper end of the first pipe 10, and as shown in FIG. 5, the first opening 10 is gradually loosened. Since the opening degree of the gas is increased and the air inflow into the second pipe body 20 is increased, the discharge amount of the electrolyte solution 21 supplied from the second pipe body 20 to the soil is gradually increased, and the opening and closing member 40 is gradually increased. When tightened, the opening degree of the first pipe body 10 decreases and the air inflow into the second pipe body 20 decreases, so that the discharge amount of the electrolyte solution 21 supplied from the second pipe body 20 to the soil gradually decreases. Therefore, the discharge of the electrolyte aqueous solution 21 can be controlled through the opening and closing member 40.

On the other hand, the aqueous electrolyte solution 21 supplied from the second tube 20 to the soil eventually reaches exhaustion and thus requires supplementation.

At this time, the electrical resistivity probe ground electrode (A) according to the present invention can be made in a timely replenishment of the aqueous electrolyte solution 21.

That is, the first pipe body 10 of the present invention is provided with a long hole 12 with a difference in height, the second pipe body 20 is made of transparent acrylic, as shown in FIG. When the inside of the first pipe body 10 is checked through, the remaining amount of the electrolyte solution 21 filled in the second pipe body 20 can be easily grasped, so when the electrolyte solution 21 is exhausted or has been exhausted, the first When the electrolyte solution 21 is injected into the second tube 20 after separating the opening / closing member 40 coupled to the upper end of the tube body 10, the electrolyte solution 21 can be replenished in a timely manner. By performing the replenishment of the aqueous electrolyte solution 21 in the supply of the aqueous electrolyte solution 21 to the soil can be made continuously.

As described above, the electrical resistivity probe ground electrode A according to the present invention is a screw member 30 coupled to a lower end of the first tube 10, and the tip of the screw member 30 contacts the ground 100. When the first tube 10 is rotated in the state, the screw member 30 penetrates the ground 100 so that the installation can be easily performed even if the soil forms a hard layer, and the inside of the second tube 20 is formed. The electrolyte solution 21 is filled in the bar, the electrolyte solution 21 filled in the second tube 20 is provided in the soil through the vertical passage 31 and the horizontal passage 32 provided in the screw member 30. Since it is continuously supplied, the electricity can be smoothly supplied with the soil, thereby increasing the grounding performance.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

10: first tube 11: protrusion
12: Longbow 13: Spiral
20: second tube 21: electrolyte solution
30 screw member 31 vertical flow path
32: horizontal flow path 40: opening and closing member
100: ground A, A ': ground electrode

Claims (5)

A first tube made of metal and provided with protruding pieces on both sides of the upper end portion;
A second tube body embedded in the first tube body and filled with an aqueous electrolyte solution;
A screw member coupled to a lower end of the first pipe, and made of metal, and having a vertical flow path and a horizontal flow path leading to the vertical flow path;
And an opening and closing member coupled to an upper end of the first tube and blocking an internal opening of the first tube. The method of claim 1,
The first specific body is provided with a plurality of long holes with a difference in height is provided for the electrical resistivity probe grounding electrode. The method of claim 1,
The second tube is an electrical resistivity probe grounding electrode, characterized in that the transparent acrylic. The method of claim 1,
The screw member is made of brass, the lower portion of the electric resistance resistive exploration ground electrode characterized in that the tip is gradually reduced in diameter. The method of claim 1,
The opening and closing member is a bolt-shaped electrical resistivity probe grounding electrode characterized in that the opening degree of the first tube is adjusted by loosening or tightening.

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