KR101029710B1 - electrolytic high dissipation graphite grounding system and installation method thereof - Google Patents

Abstract

The present invention comprises a stainless steel tube filled with photo ions therein, a carbon compression rod formed by compressing carbon in the outer circumference of the stainless steel tube, and a stainless steel needle fixed to the stainless steel tube through the carbon compression rod. It is easy to process due to the simple structure, and it can be installed by connecting the grounding device to improve the grounding force, and it can be installed by laying the grounding device in the longitudinal direction or laying it in the transverse direction so that the depth of drilling or dig required for installation It is easy to install because it lowers, and the grounding area can be grounded to maximize the grounding efficiency and effect, and the grounding efficiency can be remarkably improved. It has an excellent absorption ability due to its action on photo ions. The present invention relates to an electrolyte-filled high-radiation carbon grounding device and a method of installing the same, wherein the grounding device connected to the ground wire is embedded in the ground to ground the transient current, and is made of a cylindrical stainless steel and penetrated therein. A space part, an opening part connected to the space part at one side end thereof to allow entry and exit from the outside, a blocking member configured to open and close by covering the opening part, and integrally extending from the side part to the other end end to seal the space part A stainless steel tube formed with a needle of a pointed shape configured to be formed, one or more conductive water generating spheres formed in a form perforated on an outer surface, and a radial needle fixing fixture configured to be punched so as not to overlap the conductive water generating sphere; A carbon compression rod formed to surround the outer circumferential center portion of the stainless steel tube and compressing carbon particles having excellent moisture adsorption capacity; It is fixed to a stainless steel pipe through the carbon compression rod, the material is a stainless steel needle of the long cone shape made of stainless steel; It comprises a photo ion that is supplied to the carbon compression rods of the water is filled and adsorbed to the space portion of the stainless steel pipe, the ground wire is bonded by welding to the stainless steel pipe.

Discharge, carbon grounding device

Description

Electrolytic-filled high-radiation carbon grounding device and its installation method {electrolytic high dissipation graphite grounding system and installation method

The present invention relates to an electrolyte-filled high-radiation carbon grounding device and a method for installing the same, and more particularly, a stainless steel tube filled with photo ions therein, a carbon compression rod formed by compressing carbon at an outer circumference of the stainless steel tube, and It consists of a stainless steel needle that is fixed to a stainless steel pipe through a carbon compression rod, and has a simple structure as described above, so that it is easy to process and can be installed by connecting a grounding device to improve the grounding force. Can be installed by laying it on the floor or laying it horizontally to reduce the depth of perforation or dig required for installation, and it is easy to install and maximizes the ground area and effect that the grounding device can ground. Has excellent water absorption ability of carbon and increases the moisture content for natural ground reduction effect It can be connected to the ground wire and the grounding device by welding, and the connection structure can be kept more solid. The absorbing power is excellent due to the action of photo ions. It is about a method.

Grounding refers to the electrical connection of electronic devices, electrical machinery, or electrical equipment to the earth. Such grounding is the high voltage static electricity generated by the electrical connection of the equipment and the earth, or the overload acting on the equipment. This is to prevent equipment damage by electric shock accident or overload by sending surge voltage caused by earth.

In addition, when a lightning strike generates a surge voltage of hundreds of billions to billions of volts, it may lead to a fire, resulting in equipment damage and human accident.

In general, a disaster caused by an overload, a lightning strike, or a surge voltage can hardly be predicted by anyone, which causes a fire of a building structure or expensive electrical and electronic communication equipment and a failure of various devices. Therefore, when a surge voltage such as an overload or a lightning strike occurs, the grounding device is used as a means for preventing the overvoltage and overcurrent from being induced and spreading safely to the ground, thereby preventing damage to important equipment due to the overvoltage and overcurrent.

The general structure of the grounding device is buried in the ground and electrically connects high-voltage wire towers, high-rise buildings, communication equipment, electronic measuring equipment, computing equipment, train rails, etc. to the ground to safely spread surge voltage such as overload or lightning. Thus, such equipment is configured to block the phenomenon of damage caused by surge voltage such as overload or lightning.

The conventional grounding device as described above improves the grounding performance by supplying moisture around the grounding device by using an electrolytic material that is easily absorbed by moisture, but in the case of dry earth, the absorption of moisture is insignificant. It is difficult to obtain the effect.

As a result, when the surge voltage invades, the potential of the circumferential surface of the ground rod is sharply increased. At this time, the discharge rate is delayed due to no effective discharge to the ground, and the life of the ground rod itself is shortened or sufficient protection of the surrounding facilities is achieved. There is a problem such as not made.

In addition, in the case of the conventional grounding device as described above, mostly made of alloy materials of iron and copper or copper, when buried for a long time in the soil containing moisture, the part is corroded in the process of easily reacting and its shape is deformed or prepared for the initial stage. There was a problem that the grounding efficiency was significantly lowered. In particular, the grounding resistance reducing agent contained a lot of strong electrolytes, which required a lot of grounding resistance reducing agents due to the large construction area, which shortened the life of the grounding device such as severely corroding the grounding device. As a result, the installation cost is increased and the installation time is long, and the length of the ground rod is increased to increase the ground area, and the depth of drilling is increased by connecting more ground rods to the ground rod. It may be necessary to be very deep, making it difficult to install the grounding device. The.

In recent years, the so-called mesh grounding method has been widely used, which is installed in a very large area due to its structural characteristics, which is made by connecting the copper wire in the form of a network, and is grounded in the form of a net. .

It has excellent grounding effect, so it can get low grounding resistance, and it is easy to get low contact voltage or low stride voltage, so it is a place where safety is a priority and a place where high earth resistivity or a large area such as the bottom of a building can be secured. It is mainly to be constructed.

On the other hand, this is not suitable for most buildings, telecommunication relay stations, base stations, etc., where a very large construction area is required and a grounding facility should be installed in a limited area. Installation is required in the form of a net, and requires a considerable amount of skill to connect each net-shaped connection point by crimp sleeve joining or heating welding, and requires periodic reconstruction because the construction cost is high and maintenance is not possible. There is a problem in that the operating cost is excessive, and the grounding device occupies a small area, but a grounding device having excellent grounding effect is required.

The present invention for solving the conventional problems as described above is made of a simple structure, the productivity is excellent, can be a plurality of grounding device to improve the grounding force, the grounding device in the longitudinal direction or by lying down in the transverse direction By providing a method of installation, it is possible to reduce the depth of drilling or dig required for the installation of the grounding device, which is easy to install, maximizes the ground area and the effect that the grounding device can ground, and significantly improves the grounding efficiency. It has excellent water absorption ability, so it can increase the water content and get natural grounding reduction effect. By connecting the ground wire and the grounding device by welding, the connection structure can be kept more solid, and the light ion can keep sufficient moisture. Electrolyte-filled high-radiation carbon grounding device that can be installed regardless of city factory and its installation method And to provide for that purpose.

The present invention for achieving the above object is made of a cylindrical stainless steel, the space portion formed in the form penetrated therein, the opening portion is connected to the space portion at one side end and configured to be accessible from the outside, A blocking member configured to open and close the opening, a needle having a pointed shape configured to seal the space part by being integrally extended with a side portion at the other end, and at least one conductive water generating sphere having a perforated shape on the outer surface; A stainless steel pipe having a spin settling fixture formed by perforation so as not to overlap with the conductive moisture generating sphere; A carbon compression rod formed around the outer periphery of the stainless steel tube and formed by compressing carbon particles having excellent moisture adsorption capacity; It is fixed to a stainless steel pipe through the carbon compression rod, the material is a stainless steel needle of the long cone shape made of stainless steel; And a photo ion for supplying moisture adsorbed and adsorbed to the space of the stainless steel pipe to a carbon compression rod, and the ground wire is an electrolyte-filled high-radiation carbon grounding device that is welded and bonded to a stainless steel pipe, and the grounding-grounding device To install the perforated or exploded ground, and installed in the perforated or exploded place the electrolyte-filled high-radiation carbon grounding device in the longitudinal direction or laid in the transverse direction, the speech to the opening of the stainless steel pipe facing, An object of the present invention is to provide a method of installing an electrolyte-filled high-radiation carbon grounding device for welding and installing the joints.

 The present invention relates to an electrolyte-filled high-radiation carbon grounding device and a method for installing the same. The present invention has a simple structure, which is excellent in productivity, and can speak multiple grounding devices to improve grounding force, and embeds the grounding device in the longitudinal direction. It can be installed in a horizontal or horizontal direction to reduce the depth of drilling or dig required for the installation of the grounding device, and it is easy to install and maximizes the ground area and effect that the grounding device can be grounded to significantly improve the grounding efficiency. In addition, it is a very useful invention that can be installed irrespective of the market place by welding the ground wire and the grounding device to maintain the connection structure more solid state, and to retain sufficient moisture by the action of photo ions.

Hereinafter, the configuration and operation of the electrolyte-filled high-radiation carbon grounding device and its installation method according to the accompanying drawings will be described in detail.

1 is a perspective view of the electrolyte-filled high-radiation carbon grounding device of the present invention, Figures 2a to 2b is a cross-sectional view taken along line A-A 'of Figure 1, Figure 3 is a perspective view of the electrolyte-filled high-radiation carbon grounding device with an auxiliary needle 4 is a cross-sectional view showing a method of installing the electrolyte-filled high-emission carbon grounding device of the present invention, Figure 5 is a cross-sectional view showing another embodiment of the installation method of the electrolyte-filled high-spinning carbon grounding device, Figure 6 7 is a perspective view showing another embodiment of the electrolyte-filled high-spinning carbon grounding device of the present invention.

Electrolytically charged high-radiation carbon grounding device of the present invention is a grounding device connected to the ground wire (1) embedded in the ground to ground the transient current, made of a cylindrical stainless steel, the space portion formed in the form penetrated therein ( 110, an opening 120 connected to the space part 110 at one end and configured to allow entry and exit from the outside, a blocking member 130 configured to cover and open the opening 120, and the other side. Pointed tip portion 140 is configured to seal the space portion 110 and integrally extended to the end portion, and one or more conductive moisture generating sphere 150 formed in a form perforated on the outer surface, and the conductive A stainless steel tube 100 having a spin needle fixing tool 160 formed by perforation so as not to overlap with the moisture generating sphere 150; A carbon compression rod (200) formed to surround an outer circumferential center of the stainless steel pipe (100) and compressing carbon particles having excellent moisture adsorption capacity; It is fixed to the stainless steel pipe 100 through the carbon compression rod 200, the material is a stainless steel needle (300) of a long cone shape made of stainless steel; It comprises a light ion 400 for supplying the water absorbed and adsorbed in the space 110 of the stainless steel pipe 100 to the carbon compression rod 200, the ground wire (1) is a stainless steel pipe (100) It is joined by welding.

The stainless steel pipe 100 is formed of a cylindrical stainless steel, and has a space portion 110 formed therein, and an opening portion connected to the space portion 110 at one side end thereof to allow entry and exit from the outside ( 120, a blocking member 130 configured to cover and open the opening 120, and a needle point 140 having a pointed shape configured to seal the space 110 by being integrally extended to the side at the other end. And, one or more conductive water generating spheres 150 formed in a perforated form on the outer surface, and the spinning needle fixing sphere 160 is formed by punching so as not to overlap the conductive water generating sphere 150.

The space 110 is penetrated inside the stainless steel pipe 100. The space 110 is filled with photo ions 400 to adsorb the surrounding moisture by the action of the filled photo ions 400 to increase the grounding effect.

The opening 120 is configured to serve as a doorway for filling the light ions 400 in the space 110 formed inside the stainless steel pipe 100, and is preferably provided in a shape that is easily opened and closed to the outside. .

The blocking member 130 is provided to seal the opening 120 of the stainless steel pipe 100, and various shapes and methods capable of sealing the opening 120 after filling the opening 120 with photo ions 400. It is preferable to be provided with, in order to prevent the foreign ions from penetrating the inside of the stainless steel tube (100) while preventing the light ion 400 is filled in the interior of the stainless steel tube 100 to the outside. do.

Needle part 140 has a pointed shape, and is integrally extended to one end of the stainless steel tube 100 to the outer surface to seal the space 110. The needle part 140 serves to discharge the transient current introduced into the stainless steel tube 100, and the tip portion is formed in a shape such as a sharp cone or various pyramids and needles so that the introduced transient current can be quickly and accurately escaped. It is preferable, in addition to that it can be configured in a variety of forms the end is sharply processed.

Conductive water generating sphere 150 is formed in the form perforated on the outer surface of the stainless steel pipe 100, the number can be provided with one or more, so that the circulation of air in the stainless steel pipe 100 can be made smoothly At the same time, it serves to supply moisture by discharging the water inside the stainless steel pipe 100 generated by the action of the photo ion 400 to the compressed carbon rods.

The spinning needle fixture 160 is constructed by perforating the outer surface of the stainless steel pipe 100 so as not to overlap with the conductive moisture generating sphere 150. The radiation needle fixture 160 is to be fixed to the stainless steel needle 300 is inserted, the connection method is to be fixed to the stainless steel tube 100 is stainless steel needle 300, such as welding and bolt (2) assembly It can be made in a variety of ways, the ground is made through a stainless steel spinning needle (300).

The carbon compression rod 200 is formed to surround the central portion of the outer periphery of the stainless steel pipe 100, and is configured by pressing the carbon particles excellent in the adsorption capacity of moisture in the material properties.

The carbon particles are excellent in water absorption, and serve to supply moisture to the electrolyte-filled high-radiation carbon grounding device together with the photo ions 400 filled in the stainless steel pipe 100 so that the grounding can be made more accurately and effectively. The chemical reaction with the stainless steel is very inadequate and there is no concern of corrosion.

The connection structure of the stainless steel pipe 100, the carbon compression rod 200, and the stainless steel needle 300 as described above will be described. First, the carbon compression rod 200 is formed by compressing the carbon particles. The shape of 200 may be provided in the shape of various prisms, including the shape of the circumference.

Since the carbon compression rod 200 is a length member, the user can cut and use the desired length according to the use or place, as well as the carbon compression rod 200 provided as described above is punched in the axial direction to stainless steel. Insert the tube (100).

In addition, the carbon compression rod 200 is inserted into the stainless steel tube 100 is punched in the outer surface to insert the stainless steel needle 300 by fixing so that the stainless steel needle 300 and the stainless steel tube 100 can be connected. do.

In addition, the stainless steel needle 300 and the stainless steel tube 100 may be fixed in a variety of ways, the internal thread of the spinning needle fixture 160 formed in the stainless steel tube 100 to form a female thread (10) On the outer circumference of the stainless steel needle 300, a male screw thread 20 corresponding to the female screw thread 10 may be formed and screwed thereto.

In addition, the inner periphery of the stainless steel pipe 100 is welded to the bolt (2), so that the hole of the bolt (2) coincides with the spinning needle 160, the outer periphery of the stainless steel needle (300) A male screw thread 20 corresponding to the female screw thread 10 of the bolt 2 can be formed and screwed together.

In this case, by inserting the spinning needle on the carbon compression rod 200 and the female screw thread 10 and the male screw thread 20 to be fastened, the replacement and installation of the spinning needle is made simple, in particular, of the stainless steel pipe 100 When welding the bolt (2) on the inner circumference, there is an effect that can be omitted a very difficult operation to form the female thread 10 in the spinning needle fixture (160).

In addition, the outer surface of the stainless steel needle 300 is made of a material attached to the auxiliary needle 500 of the conical shape made of stainless steel.

The auxiliary needle 500 is generally configured in the form of a cone, and is provided by attaching at least one to the outer surface of the stainless steel needle 300, and serves to discharge the transient current and the surge voltage introduced into the stainless steel pipe 100. Do it. Therefore, it is preferable that the end portion has a shape such as a sharp cone or various pyramids and needles so that the transient current and surge voltage flowing in can be quickly and accurately. In addition, various types of auxiliary needles 500 having sharply processed ends are provided. Of course it can be formed. In addition, the auxiliary needle 500 may be attached to the needle 140 provided at the lower end of the stainless steel pipe 100, as well as the outer periphery of the stainless steel needle 300, of course, generally conical auxiliary needle It is configured by attaching another conical auxiliary needle 500 on the surface of 500, the method of attachment can be made in a variety of ways, in particular can be attached by welding.

In addition, the auxiliary needle 500 is formed sharply because when the lightning or surge flows into the electrolyte-filled high-spinning carbon grounding device has a property that the surface area is concentrated to a narrow portion and discharged, a plurality of auxiliary needles ( 500) to provide as many discharge paths as possible and to allow the incoming surge voltage to flow out quickly.

The stainless steel pipe 100 and the ground wire 1 of the electrolyte-filled high-radiation carbon grounding device as described above are connected by welding, and the welding method is that the ground wire 1 and the stainless steel pipe 100 are easily separated from inflow of overcurrent and overvoltage. It should be clear that it can be implemented in a variety of ways, as long as it can remain firmly attached.

The reason for welding the ground wire 1 and the stainless steel pipe 100 as described above is that when the ground wire 1 and the stainless steel pipe 100 are combined by a mechanical coupling method, a contact resistance is generated, and a large amount of lightning strikes from the outside. Alternatively, when a surge voltage occurs, the connection between the ground wire 1 and the stainless steel pipe 100 may be damaged due to overheating, and foreign matter may penetrate into the damaged area. The ground wire 1 and the stainless steel pipe 100 are integrated, so that the joint is firm and prevents damage due to overheating in advance, and the conductivity is excellent and the contact resistance can be minimized to maximize the grounding performance.

The present invention provides a method of installing an electrolyte-filled high-radiation carbon grounding device in which a grounding device is connected to a ground wire (1) and installs a grounding device for grounding a transient current, wherein the grounding device is provided with a grounding device receiving hole. The first step to do; Opening device 120 is made of a cylindrical stainless steel in the grounding device receiving opening, the space portion 110 is formed through the inside, and the opening portion 120 is connected to the space portion 110 at one side end to allow the entrance and exit from the outside ), And one or more conductive water generating spheres 150 formed of a pointed needle part 140 configured to seal the space part 110 by being integrally formed with the side part at the other end and perforated on the outer surface. ) And a stainless steel pipe (100) having a spinning needle fixing (160) formed by perforation so as not to overlap with the conductive moisture generating sphere (150); A carbon compression rod (200) formed to surround an outer circumferential center of the stainless steel pipe (100) and compressing carbon particles having excellent moisture adsorption capacity; It is fixed to the stainless steel pipe 100 through the carbon compression rod 200, the material is a stainless steel needle (300) of a long cone shape made of stainless steel; The stainless steel tube 100 is placed in the electrolyte-filled high-radiation carbon grounding device comprising a light ion 400 for supplying the adsorbed moisture to the carbon compression rod 200 filled in the space 110, stainless steel tube A second step of placing 100 in parallel with the earth; A third step of welding the stainless steel pipe 100 and the ground wire 1; And a fourth step of embedding the electrolyte-filled high-radiation carbon grounding device and the ground wire (1).

The first step of installing the electrolyte-filled high-radiation carbon grounding device of the present invention comprises a grounding device receiving hole by drilling a space for embedding the grounding device in the ground to be grounded, but larger than the volume of the electrolyte-filled high-radiation carbon grounding device It is preferable to puncture.

After the grounding device receiving device is provided, the grounding device is mounted on the grounding device receiving device, and the grounding device is made of cylindrical stainless steel in the electrolyte-filled high-radiation carbon grounding device. A space portion 110 configured to penetrate through the inside, an opening 120 connected to the space portion 110 at one side end thereof and capable of entering and exiting from the outside, and integrally connected to the side portion at the other end portion thereof. Pointed needle 140 is formed to extend and seal the space 110, one or more conductive water generating sphere 150 formed in the form of perforated on the outer surface, and the conductive water generating sphere 150 A stainless steel pipe 100 having a radial needled fixture 160 formed therein so as not to overlap with it; A carbon compression rod (200) formed to surround an outer circumferential center of the stainless steel pipe (100) and compressing carbon particles having excellent moisture adsorption capacity; It is fixed to the stainless steel pipe 100 through the carbon compression rod 200, the material is a stainless steel needle (300) of a long cone shape made of stainless steel; It refers to an electrolyte-filled high-radiation carbon grounding device comprising a light ion 400 for supplying the water adsorbed and adsorbed to the space portion 110 of the stainless steel pipe 100 to the carbon compression rod 200.

In this case, the electrolyte-filled high-radiation carbon grounding device is preferably seated in the transverse direction so that the stainless steel pipe 100 is parallel to the ground, this is to significantly reduce the depth of the perforated ground to facilitate the installation work, the Electrolyte-filled high-radiation carbon earthing device is made by flexibly manufacturing the size of electrolyte-filled high-radiation carbon earthing device according to the application considering the ground area to be grounded or the size of building to be grounded, working condition, communication equipment, etc. It is desirable to.

When the seating of the electrolyte-filled high-radiation carbon grounding device is completed as described above, the stainless steel tube 100 and the ground wire 1 are connected and welded in the third step, and the welding method is the ground wire 1 and the stainless steel tube 100. It is clear that it can be carried out in various ways within the range that it can be maintained firmly in the attached state without being easily separated from the inflow of overcurrent and overvoltage, and the welded ground wire (1) and the electrolyte-filled high spinning The carbon grounding device is completed in the fourth step of filling up the installation of the electrolyte-filled high-spinning carbon grounding device.

As described above, when a transient current flows from the outside while the electrolyte-filled high-radiation carbon grounding device is buried in the ground, it is discharged into the soil through the needle 140 of the stainless steel pipe 100 through the ground wire 1. In this case, the transient current is concentrated by the stainless steel needle and the discharge is rapidly performed.

In addition, the two-stage electrolyte-filled high-radiation carbon grounding device is provided with a pair of seating so that the opening 120 of the stainless steel pipe 100 to face, welded the joint. As described above, when a pair of electrolyte-filled high-radiation carbon grounding devices are connected and installed, the grounding performance of the general grounding device can be expected to be twice or more than the grounding efficiency of the general grounding device without making the size of the grounding device large. As the speech is reduced, the depth of the ground to be drilled can be significantly reduced, so that the installation work can be easily proceeded. The opening 120 of the stainless steel pipe 100 faces each other and the joints are welded so that the electrolyte-filled high-radiation carbon grounding device is mutually connected. It is firmly combined to give the effect of being grounded by a single grounding device. At this time, the blocking member 130 is configured to cover the opening 120 to open and close, it is preferable to remove the speech.

In addition, the electrolyte-filled high-radiation carbon grounding device of the second step is provided with a pair to seat the opening 120 of the stainless steel pipe 100 to face each other, each of the joint member 600 provided to surround the joint portion It is the structure comprised by welding to the stainless steel pipe 100.

The joint member 600 is intended to be more firmly fixed than when the stainless steel pipe 100 is facing and the joint is welded, the joint member 600 is a hollow pipe shape, the stainless steel pipe 100 is mutually Make sure that it fits into the opposite seam. In the case of the stainless steel pipe 100 to which the joint member 600 is fitted, both ends of the joint member 600 are positioned in separate stainless steel tubes 100, and the joints of the stainless steel tube 100 and the joint member 600 are positioned. By welding, the electrolyte-filled high-radiation carbon grounding devices are firmly coupled to each other to have an effect as if the ground is formed by a single grounding device, and at this time, the blocking member 130 configured to cover and open the opening 120. ), It is preferable to remove the speech.

In addition, the stainless steel pipe 100 is generally the same size and can face each other so that one side end to match, but the diameter of the stainless steel pipe 100 is provided differently to have a large diameter The stainless steel pipe 100 having a small diameter can be fitted to the inner diameter of the stainless steel pipe 100 having the welded joints, and the electrolyte-filled high-radiation carbon grounding devices are firmly coupled to each other, so that the grounding is performed with one grounding device. In this case, it is preferable that the blocking member 130 configured to cover the opening 120 to be opened and closed is removed and addressed.

Electrolyte-filled high-radiation carbon grounding device of the present invention installed by the method as described above can improve the grounding force by spreading a plurality of grounding device, and provides a method of installing the grounding device in the longitudinal direction or laid horizontally lying down It is easy to install by lowering the depth of drilling or dig required for the installation of the grounding device, and it maximizes the ground area and effect that the grounding device can ground. Welded to have the effect of maintaining the connection structure more solid state.

As described above, the electrolyte-filled high-emissive carbon grounding device and its installation method have been described, but those skilled in the art will have the present invention within the scope of the present invention as set forth in the claims below. It can be carried out by various modifications or variations.

1 is a perspective view of an electrolyte-filled high-radiation carbon grounding device of the present invention,

2A to 2B are cross-sectional views taken along line AA ′ of FIG. 1;

3 is a perspective view of an electrolyte-filled high-radiation carbon grounding device with an auxiliary needle attached,

4 is a perspective view of a stainless steel pipe,

5 is a perspective view of a stainless steel needle,

6 is a cross-sectional view showing a method for installing the electrolyte-filled high-radiation carbon grounding device of the present invention;

7 is a cross-sectional view showing another embodiment of the method of installing the electrolyte-filled high-radiation carbon grounding device of the present invention;

8 to 9 is a perspective view showing another embodiment of the electrolyte-charging high-radiation carbon grounding device of the present invention.

<Description of the symbols for the main parts of the drawings>

1: ground wire

2: bolt

10: female thread

20: male thread

100: stainless steel pipe

110: space part

120: opening

130: blocking member

140: needle

150: conductive moisture generating sphere

160: spinning needle fixture

200: carbon compression rod

300: stainless steel needle

400: Photoion

500: auxiliary hand

600: joint member

Claims (8)

delete delete delete delete delete A first step of drilling a ground and having a grounding device receiving port; Opening device 120 is made of a cylindrical stainless steel in the grounding device receiving opening, the space portion 110 is formed through the inside, and the opening portion 120 is connected to the space portion 110 at one side end to allow the entrance and exit from the outside ), And one or more conductive water generating spheres 150 having a pointed needle part 140 configured to seal the space part 110 by being integrally formed with the side part at the other end and perforated on the outer side surface. And, the stainless steel pipe 100 is formed with a spinning needle fixing device 160 is formed by perforation so as not to overlap with the conductive moisture generating sphere 150; A carbon compression rod (200) formed to surround an outer circumferential center of the stainless steel pipe (100) and compressing carbon particles having excellent moisture adsorption capacity; It is fixed to the stainless steel pipe 100 through the carbon compression rod 200, the material is a stainless steel needle (300) of a long cone shape made of stainless steel; The stainless steel tube 100 is placed in the electrolyte-filled high-radiation carbon grounding device comprising a light ion 400 for supplying the adsorbed moisture to the carbon compression rod 200 filled in the space 110, stainless steel tube A second step of transversal positioning so that 100 is parallel to the earth; A third step of welding the stainless steel pipe 100 and the ground wire 1; In the method of installing an electrolyte-filled high-carbon spinning device comprising a fourth step of embedding the electrolyte-filled high-radiation carbon grounding device and the ground wire (1), The electrolyte-filled high-radiation carbon grounding device of the second step is provided with a pair of seating so that the opening 120 of the stainless steel pipe 100 to face, welded joints, characterized in that the electrolyte-filled high-radiation carbon grounding device How to install. The method of claim 6, wherein the electrolyte-filled high-spinning carbon grounding device of the second step is provided with a pair to be seated so that the opening 120 of the stainless steel pipe (100) to face, and to surround the joint portion 600 ) Is a method of installing an electrolyte-filled high-spinning carbon grounding device, characterized in that made by welding to each stainless steel pipe (100). According to claim 7, wherein the diameter of the stainless steel pipe 100 is provided differently to have a large diameter The method of installing an electrolyte-filled high-spinning carbon grounding device, characterized in that the stainless steel pipe (100) having a small diameter can be fitted to the inner diameter of the stainless steel pipe (100) having.

Images