KR200410069Y1 - Earthing Equipment - Google Patents

Abstract

The present invention relates to a complex grounding facility, and in particular, to a complex grounding facility suitable for various purposes such as various buildings, communication relay stations, base stations,

It can be easily installed without any extra cost for additional design and construction while using the conventional grounding facilities, and it is possible to secure a wider ground area. It is intended to provide a grounding facility with a doubled grounding effect by constructing it where it can secure the area.

Ground, Lightning Rod, Mesh, Mesh, Mesh Ground

Description

Earthing Equipment

1 is an exemplary view showing a conventional grounding facility.

2 is an exemplary view showing a hybrid grounding facility according to the present invention.

Explanation of symbols on the main parts of the drawings

1: drilling hole 2: main ground rod

3: connection part 4: auxiliary earth wire

5: reticular ground 6: junction

The present invention relates to a complex grounding facility, and more particularly, to a complex grounding facility suitable for various applications such as various buildings, communication relay stations, base stations.

As is well known, a lightning rod (안전하게 雷 針) safely induces a shock current caused by a lightning strike to the ground to prevent fire damage and injuries caused by lightning strikes in buildings. To install.

Such a lightning rod consists of three parts: a protrusion, a lightning rod, a grounding conductor, and a ground electrode.

The projections of these protrusions use rods of 12 mm or more in diameter made of copper or hot-dip galvanized iron or steel, and the lightning rods are made of copper with a cross-sectional area of 30 mm2 or more, and aluminum with 50 mm2. Use the above leads.

In addition, the grounding electrode should be grounded with a ground resistance of 10 Ω or less by using a steel plate having a thickness of 1.4 mm, an area of 0.35 m 2 or more, a steel plate of 3 mm or more, a galvanized iron plate of an area of 0.35 m 2 or more, or a bar shape having an earthing effect equivalent thereto. Buried in.

On the other hand, in case of using the ground electrode using the steel sheet or galvanized steel sheet, not only the excavation site of the ground such as road is widened, but also a lot of cost is required to bury it deeply. There is a problem that this is large.

In addition, the ground electrode has a lifespan of only 3 to 5 years due to corrosion, and thus does not maintain a constant reference ground resistance. The ground resistance varies greatly depending on season, temperature, and amount of electrolyte. It can have a devastating effect.

 Therefore, in recent years, it is common to use a rod-shaped ground electrode, and the conventional ground rod 2 forms a drilled hole 1 as shown in FIG. 1, and inserts the grounded rod 2 into the drilled hole 1. The ground rod is connected to a facility or electronic equipment that requires grounding by connecting a lead wire (not shown) to one side of the ground rod.

The grounding rod 2 described above is fitted with a stopper in the form of a cone at the lower end thereof, and a drainage ball 1b is formed in several places, and a tape 1c is covered with the drainage hole 1b.

The above-described ground rod 2 has a gap (not shown) formed at the upper end, and moisture in the air penetrates into the ground rod 2 through the gap, and the metal salt of the metal ion component filled with moisture inside the ground rod. As the liquid is absorbed and accumulated in the form of droplets by contact with the electrolyte moisture generating material, salts), the electrolyte solution is formed and flows into the lower portion of the ground rod 2.

As the accumulation increases, the solution concentrated in the ground rod causes osmotic action as the electrolyte solution diffuses and supplies to the soil continuously through the drain hole 1b of the ground rod at the bottom. As a result, the ground rod is naturally discharged to the surrounding soil where the ground rod is embedded, and gradually the large area of the soil is converted into the electrolyte soil. This electrolyte solution acts as the root of the electrolyte, reducing the electrical resistance between the ground electrode and the soil, thereby obtaining an effective discharge effect.

On the other hand, the surge voltage is often high frequency so that the wave length is only 1㎲, so even though it is widely installed, it does not contribute to the ground impedance as much as the area, but only a part of the injection point where the surge voltage is invaded. It contributes to the ground discharge of the surge voltage.

This range is called the effective radius of the grounding conductor and decreases as the frequency of the surge voltage increases.

Therefore, even if the grounding area of the grounding conductor is increased outside the effective radius, it is difficult to obtain a satisfactory grounding effect.

Accordingly, when the surge voltage invades, the potential of the circumferential surface of the ground rod rises sharply. At this time, since there is no effective means for discharging to the ground, the discharge rate is delayed, which shortens the life of the ground rod itself or provides sufficient protection of the surrounding facilities. There is a problem such as not.

The present invention is to provide a complex grounding facility that can solve the above problems.

The present invention is to provide a complex grounding equipment that can be installed in the ground, and to cover the reticulated ground on the upper ground of the grounding rod, connecting the meshed ground and the grounding rod to obtain a good grounding effect and low ground resistance There is this.

Another object of the present invention is to provide a complex grounding facility that is suitable for places where safety is a priority and in areas with high earth resistivity by increasing the ground area by reticulated grounding.

In order to achieve the above object, an embodiment of the present invention, filling the electrolyte solution in the grounding rod, the electrolyte solution is to be discharged through the drain hole, in the grounding facility surrounded by the tape in the drain hole,

At the top of the ground rod, at least one auxiliary ground wire

Provided is a grounding facility connected to the auxiliary grounding wire and including a reticulated ground widely spread on the ground.

Hereinafter, the present invention configured as described above will be described in detail.

2 is an exemplary view showing a composite grounding facility according to the present invention.

Complex grounding equipment according to the present invention is to have a larger ground area, the same reference numerals for the same components as the conventional grounding equipment and the description thereof will be omitted.

As shown in FIG. 2, the one or more auxiliary ground wires 4 are connected to the junctions 3 at the upper side of the ground rod 2, and the mesh ground 5 is installed on the ground, and the mesh ground 5 and the auxiliary ground wires ( 4) is a joint material 6 is formed by connecting the conductor material.

It is preferable that the above-described auxiliary ground wire 4 forms a copper wire with an extremely low current resistance, and the junction part 3 may simply be wound around the auxiliary ground wire 4 and tied together or permanently coupled by welding or the like.

The above-described mesh ground 5 is laid in a large area, and is constructed in such a way as to cover a wide area according to the ground to be grounded regardless of the shape of the appearance.

In addition, the mesh ground 5 and the auxiliary wire ground wire 4 is preferably made of a material having a very low current resistance, and may be permanently coupled by copper wire or by means of welding or the like.

In addition, although not specifically illustrated on the reticulated ground 5, the soil may be covered.

It is easy to obtain low contact resistance and low contact voltage or low stride voltage because of excellent grounding effect.

In addition, the effect is doubled if the construction is mainly in places where safety is a priority, areas with high earth resistivity or where a large area can be secured, such as the bottom of a building.

Hereinafter, the operation and operation of the present invention will be described with reference to the accompanying drawings.

Accordingly, after the construction, the moisture in the ground contacts the electrolyte moisture generating material, which is a metallic salt of metallic ions, which is filled in the ground rod 2, and is absorbed and accumulated in the form of droplets, thereby forming an electrolyte solution. To the bottom of the

As the accumulated amount increases, the electrolyte solution at the bottom continuously diffuses and supplies into the soil around the ground rod 2 through the drain hole 1c of the ground rod 2, so that the concentrated solution inside the ground rod 2 Osmotic action is caused to be released to the soil around the ground rod 2 is buried naturally to gradually change the large area of the soil into the electrolyte soil.

This electrolyte solution acts as the root of the electrolyte, reducing the electrical resistance between the ground electrode and the soil, thereby obtaining an effective discharge function.

The present invention, when the surge voltage is introduced into the lead wire (not shown) due to lightning, etc. are distributed through the mesh ground (5) connected to the ground rod (2) and discharged to the ground through the ground rod (2).

In this process, the ground rod 2 is discharged to the ground through the drain hole 1b, the surge voltage is discharged to the ground, the soil filled in the drilling hole (1), the electrolyte solution acts as the electrolyte root, the ground electrode and soil Reduces the electrical resistance between the two to enable effective discharge.

At this time, in the present design, the remaining current which is not discharged by the ground rod 2 disposed in the effective radius is discharged to the ground by the reticular ground 5.

Therefore, the surge voltage can be efficiently removed, and thus, the surge voltage can be safely protected from the lightning voltage such as a lightning strike. When the surge voltage is drawn, the potential of the reticulated ground (5) or the ground rod (2) is significantly different from that of the earth. Corrosion can be suppressed due to corrosion.

Although the present invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various changes and modifications are possible within the technical scope of the present invention, and such modifications and modifications belong to the appended utility model registration claims. .

The grounding equipment according to the present invention can use the conventional grounding equipment as it is, and can be easily installed without excessive additional costs for additional design and construction, and can secure a wider ground area to prevent damage to the device due to lightning strikes. Can be.

Claims (1)

In the grounding equipment formed in the ground, the grounding rod is inserted into the grounding hole, the electrolyte solution is filled in the grounding rod, and the electrolyte solution is discharged through the drainage hole. An auxiliary ground wire connected to at least one of the ground rods; A grounding facility connected to the auxiliary grounding wire and including a reticulated ground widely spread on the ground.

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