KR20110097556A - Apparatus for grounding circular concrete ground electrode and construction method therefor - Google Patents

Abstract

A first coupling part for coupling the discharge rod 20 to one side and the other side of the first fixing piece is formed, a second coupling portion for coupling the discharge rod 20 to one side and the other side of the second fixing piece is formed, the second coupling portion A ground core 10 forming a third coupling part for coupling the ground lead terminal 40 to the other side spaced apart from the predetermined distance; A discharge rod 20 coupled to and fixed to the lower end of the first coupling portion and the second coupling portion of the ground core 10; In the state where the discharge rod 20 is coupled to the lower end of the first coupling portion and the second coupling portion of the ground core 10, the conductive concrete to surround the first fixing piece and the second fixing piece except for the third coupling portion ( a conductive molding member 30 formed through concrete or conductive mortar; And a ground lead terminal 40 coupled to the third coupling portion of the ground core 10 and fixing both the lead rod provided on one side of the ground core 10 and the ground wire drawn out from the ground wire outlet of the electric pole 1; It includes.

Description

Grounding device and construction method using circular concrete earth electrode {APPARATUS FOR GROUNDING CIRCULAR CONCRETE GROUND ELECTRODE AND CONSTRUCTION METHOD THEREFOR}

The present invention relates to a grounding device using a circular concrete grounding electrode and a construction method thereof, and more specifically, to construct a grounding construction by utilizing excavation parts for electric pole dry poles when constructing electric poles, and install a grounding pole in the lower pole of a series connection structure. It facilitates the construction, and relates to a technology for improving the adhesion between the ground electrode and the ground by the load of the pole pole by installing the ground pole under the pole.

In other words, when installing a distribution line, excavation area that needs to be excavated in order to establish poles should be constructed. If you want to install a grounding pole in the lower part of the pole with minimal additional excavation, and if necessary, obtain a low ground resistance. The present invention relates to a technique for improving the grounding effect by maximizing the contact density between the ground electrode and the ground by using a grounded electrode connected in series and utilizing pole weight and earth pressure.

In general, in order to supply electric power that has undergone various stages of transformation in a substation to a customer of a home or a building, a overhead distribution line supported by a pole installed at regular intervals on the ground is used. In such a distribution line, a grounding rod is connected to protect the power distribution equipment from abnormal currents (lightning, ground fault, surge, etc.) and to prevent various electrical disasters caused by a short circuit.

At this time, the grounding of the distribution line ensures the operation of the protection relay in the case of high and low voltage mixing and ground fault, and suppresses the abnormal voltage. Plays an important role in prevention

In particular, Korea's distribution line grounding method is a neutral direct grounding method, and the ripple effect of misgrounding is innumerable. Moreover, the rapid development of information and communication is desperately required for high-quality power supply.

As the grounding works of such important distribution lines are operated with the construction methods and materials introduced decades ago, it is a factor of enormous budget waste and subconstruction work, and the recently introduced materials and construction methods also require enormous budgets and construction conditions. It is true that construction is difficult due to the narrowness of the place, excavation of paved roads, interference and damage with underground works.

As shown in FIG. 1, the grounding construction as described in FIG. 1 excavates a pit of a pole of a certain depth for embedding the pole 1 in the ground E and reaches a predetermined interval from the pole 1 pit. Excavating a pit for embedding the grounding rod (2) and the grounding wire (3), and grounding the grounding rod (2) for grounding in the pit with a tool such as a metal hammer, and then connected to the power distribution line, the grounding wire penetrating the electric pole (1) After connecting (3) and the grounding rod (2), the grounding work is completed by filling the excavated soil into the pit.

That is, the grounding rod 2 electrically connecting the ground E and the power distribution line quickly protects the power distribution equipment from abnormal currents and at the same time quickly transmits the abnormal currents to the ground E to prevent human injury from various electrical disasters. It will act to discharge.

On the other hand, the buried ground rod (2) is a problem that often occurs when the ground resistance value required by the type and composition of the soil, geological structure, moisture content and seasonal temperature changes, etc., The above problem is solved by further embedding the other grounding rod 2 at a predetermined interval on one side of the already grounded grounding rod 2.

However, such ground works usually require the installation of the ground rods 2 to a depth of about 75 cm from the ground surface, so that the ground lines 3 are buried in order to bury the ground wires 3 in addition to the pits for embedding the electric poles 1 in the city center where the customers are concentrated. Excavation and recovery costs for damage to paved roads, sidewalk blocks and unidentified underground facilities (water pipes, gas pipes, communication cables, etc.) are excessive, and the construction period can be prolonged and the required ground resistance It was difficult to secure the excavation space to obtain a problem.

In addition, the excavation and recovery costs are excessively required when the paved road or sidewalk block has to be excavated 2 ~ 4m in length in the urban area, and it is installed underground by hitting the ground electrode with hammer at 75cm below the ground surface. Frequently, damage to buried material (water pipes, gas pipes, communication cables, power cables, etc.) occurs.

As shown in FIG. 2, the materials and methods of the recently introduced materials and structures can be seen to be somewhat improved, but in order to lower the ground resistance, the ground electrodes are connected in series to be separated from the ground electrode by 2 m or more. Since the grounding poles are installed in parallel, one by one, the work method is different from the past, and the problems related to the safety of the work and the economic loss caused by it are followed.

In detail about the problems of grounding of the distribution line, it is advantageous to connect the grounding rods in series to obtain low grounding resistance.However, the type of grounding rods are not bent or enters frequently. Concrete ground rods must be excavated and purchased in an unsuitable structure, which causes problems in construction.

In addition, in order to construct the grounding rod in parallel, the grounding rod must be separated from the grounding pole by 2 m or more, and thus there is a problem in that an additional excavation of 2.0m × 0.75m × 0.5m (length × depth × width) is performed.

Also, in urban areas, the excavation conditions due to grounding are not satisfactory due to the pavement and complicated traffic relations, and there is a risk of secondary construction, and there is always a risk of damage to other underground works (water pipes, gas pipes, communication cables, power cables, etc.). It is inherent.

On the other hand, if we examine the problems of the grounding materials of the distribution line in detail, the grounding rod is coated with 2mm copper skin on the surface of the iron rod to reduce the cost. In other words, the strength of the bar is weak, so there is a problem in strength, such as bending when hitting.

In addition, since concrete ground rods must be installed by circular excavation separately, it is difficult to install in urban areas due to excessive underground deposits and narrow spaces, and it is difficult to bury them deeply because they must be installed upright. It is difficult to manage.

An object of the present invention, by additional drilling to the depth of 0.25m depth to the bottom of the excavated portion 2m to 2.5m depth for Jeonju dry pole without additional excavation for laying the ground pole during the construction of the Jeonju dry pole excavation construction By installing the grounding pole under the pole, it prevents the problem of digging at a depth of 2m to 2.5m in separate locations for the pole pole and the ground pole embedding, and improves the adhesion between the ground pole and the ground by the pole pole and at the same time Since the space of the pit is utilized, the construction of the series connection structure is facilitated.

In addition, by forming a ground electrode into a conductive mortar with excellent grounding effect and by connecting a rod with a semi-permanent stainless steel plate, it is possible to maintain a constant moisture around the ground electrode with a conductive carbon fiber or mineral moisture absorbent so that the ground resistance value is low. It has a semi-permanent durability of stainless steel to minimize unnecessary ground repair work.

In addition, by reducing the extent of road excavation due to the grounding work to prevent inconvenience and civil complaints, and to prevent damage to other underground buried material by using the Jeonju excavation.

And, unlike the conventional vertically buried ground electrode, by embedding horizontally in the lower end of the pole or horizontally buried single cell electrode on the ground, by placing the ground electrode at the lowest point to improve the moisture content, and transfer to the ground electrode according to the horizontal buried Due to the earth pressure and the load of the poles buried above the ground electrode, the contact density between the ground electrode and the earth is maximized to improve the folding effect.

In the grounding device using the circular concrete ground electrode of the present invention for achieving the technical problem, the first coupling portion for coupling the discharge rod 20 is formed on one side and the other side of the first fixing piece, on one side and the other side of the second fixing piece A ground core 10 having a second coupling portion coupling the discharge rod 20 and forming a third coupling portion coupling the ground lead terminal 40 to the other side spaced apart from the second coupling portion by a predetermined distance; A discharge rod 20 coupled to and fixed to the lower end of the first coupling portion and the second coupling portion of the ground core 10; In the state where the discharge rod 20 is coupled to the lower end of the first coupling portion and the second coupling portion of the ground core 10, the conductive concrete to surround the first fixing piece and the second fixing piece except for the third coupling portion. Or a conductive molding member 30 formed through a conductive mortar; And a ground lead terminal 40 coupled to the third coupling portion of the ground core 10 and fixing both the lead rod provided on one side of the ground core 10 and the ground wire drawn out from the ground wire outlet of the electric pole 1; It includes.

In addition, the grounding device construction method using a circular concrete grounding electrode based on the device of the present invention as described above, the first fixing piece and the second fixing hole formed on the one side and the other side and the first fixing piece. Forming (a) a ground core 10 by overlapping and welding a cross shape with respect to the center of each of the second fixing pieces having a ground hole formed at a position spaced a predetermined distance away from the second fixing hole. ; (B) coupling each of the first fixing holes formed in the first fixing piece and the second fixing holes formed in the second fixing piece by the step formed on the top of the discharge rod 20; In the state in which the discharge rod 20 is coupled to the first fixing hole and the second fixing hole formed on the first fixing piece and the second fixing piece of the ground core 10, the conductive concrete or conductive mortar is formed into a disc shape to form a conductive material. (C) generating the molding member 30; And a cylindrical portion formed at a lower end corresponding to the position where the ground core 10 and the discharge rod 20 are coupled to each other, and fixing the ground lead terminal 40 constituting the lead rod provided at one side of the upper end thereof to the second fixing. (D) inserting into the biasing ground hole and fastening through the first nut and the second nut; It includes.

In addition, the grounding device using a circular concrete ground electrode according to another embodiment of the present invention, by bending to one side and the other side of the first fixing piece to form a first discharge electrode, and bent to one side and the other side of the second fixing piece A ground core 10 which forms a second discharge electrode and forms a third coupling part having a ground hole for coupling the ground lead terminal 40 to the other side of the second fixing piece; Conductive molding member formed through conductive concrete or conductive mortar to surround the first discharge electrode of the first fixing piece and the second discharge electrode of the second fixing piece, except for the third coupling portion of the ground core 10 ( 30); And a ground lead terminal 40 coupled to the third coupling portion of the ground core 10 and fixing both the lead rod provided on one side of the ground core 10 and the ground wire drawn out from the ground wire outlet of the electric pole 1; .

According to the present invention as described above, additional excavation to the depth of 0.25m depth of the bottom of the excavated portion of 2m to 2.5m depth for Jeonju dry pole without additional excavation construction for the earth pole when the excavation construction for Jeonju dry pole construction By installing the grounding pole under the pole, it prevents the problem of digging to the depth of 2m to 2.5m in separate locations for the pole pole and the ground pole embedding, and improves the adhesion between the ground pole and the ground by the pole pole and at the same time Since it utilizes the space of the electric pole pit, there is an effect of facilitating the construction of the series connection structure.

In addition, according to the present invention, by forming and manufacturing the ground electrode with a conductive mortar having excellent grounding effect and by fastening the semi-permanent stainless steel plate and rod, the conductive carbon fiber, mineral moisture absorbent, etc. to maintain a constant moisture at all times around the ground electrode As a result, it has a low ground resistance value and has the effect of minimizing unnecessary ground repair work by semi-permanent durability of stainless steel.

In addition, according to the present invention, by reducing the road excavation range due to the ground construction to prevent residents inconvenience as well as civil complaints, there is an effect of preventing other underground buried damage in advance by utilizing the Jeonju excavation.

And, according to the present invention, unlike the conventional vertically buried ground electrode, by installing a single battery electrode horizontally buried in the lower portion of the pole or horizontally, the ground electrode is located at the lowest point to improve the water content, horizontal embedding Therefore, due to the earth pressure impinged on the ground electrode and the load of the poles embedded in the ground electrode, the contact density between the ground electrode and the ground is maximized, thereby improving the folding effect.

1 is a block diagram showing a grounding apparatus using a conventional circular concrete ground electrode.
Figure 2 is an exemplary view showing the construction of a ground rod or conductive concrete as a ground electrode in the conventional grounding device construction.
Figure 3 is a block diagram showing the installation state of the grounding device using a circular concrete ground electrode according to the present invention.
4 is a block diagram of a grounding apparatus using a circular concrete ground electrode according to the present invention.
Figure 5 is a block diagram showing a conductive molded member of the grounding apparatus using a circular concrete ground electrode according to the present invention.
Figure 6 is an exploded perspective view showing a ground core of the grounding device using a circular concrete grounding electrode according to the present invention.
Figure 7 is a flow chart showing a grounding device construction method using a circular concrete ground electrode according to the present invention.
8 is a flowchart illustrating a process after step S40 of the construction method of the grounding apparatus using the circular concrete ground electrode according to the present invention.
9 is a construction procedure showing the process after step S40 of the grounding device construction method using a circular concrete grounding electrode according to the present invention.
10 is a flowchart illustrating a process after step S80 of the grounding device construction method using a circular concrete ground electrode according to the present invention.
11 is a construction procedure showing a process after step S80 of the grounding device construction method using a circular concrete grounding electrode according to the present invention.
12 is a block diagram of a grounding apparatus using a circular concrete grounding electrode according to another embodiment of the present invention.
Figure 13 is a block diagram showing another configuration of the ground core of the grounding device using a circular concrete grounding electrode according to another embodiment of the present invention.
14 is an exemplary view showing that the lead rod and the ground line of the grounding device using a circular concrete grounding electrode according to another embodiment of the present invention is fixed.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It should be interpreted in terms of meaning and concept. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

3 is a view showing the installation state of the grounding device (A) using a circular concrete ground electrode according to the present invention, Figure 4 is a configuration diagram of a grounding device (A) using a circular concrete ground electrode according to the invention, Figure 5 Figure 6 is a configuration diagram showing a conductive molded member of the grounding device (A) using a circular concrete grounding electrode according to the present invention, Figure 6 is an exploded perspective view showing a ground core material of the grounding device (A) using a circular concrete grounding electrode according to the present invention to be.

3 to 6, the grounding device A using the circular concrete ground electrode according to the present invention includes a ground core 10, a discharge rod 20, a conductive molding member 30 and a ground lead terminal 40. It is configured to include).

Specifically, the ground core 10 is composed of a first fixing piece 11 and a second fixing piece 12, one side and the other side of the first fixing piece 11 for receiving the discharge rod 20 The coupling part is provided, and a second coupling part for accommodating the discharge rod 20 is provided at one side of the second fixing piece 12, and the ground lead terminal is positioned at a predetermined distance from the second fixing hole 12b toward the other side. A third engaging portion for accommodating and engaging the 40 is provided.

In this case, first fixing holes 11a and 11b are formed at one side and the other side of the first fixing piece 11 at the first coupling part, and a discharge rod (1) is formed at one side of the second fixing piece 12 at the second coupling part. The second fixing holes 12a and 12b for accommodating 20 are formed, and the third coupling part accommodates and couples the ground lead terminal 40 at a position spaced a predetermined distance away from the second fixing hole 12b to the other side. The ground hole 13 is formed.

At this time, the ground core 10 is placed and welded so that the first fixing piece 11 and the second fixing piece 12 overlap each other in a cross shape with respect to the center, but the other length of the second fixing piece 12 is It is comprised so that it may have the length which protruded the predetermined length rather than the 1st fixing piece 11. That is, the ground hole 13 is formed at a position spaced a predetermined length from the second fixing hole 12b of the second fixing piece 12 protruding the predetermined length to the other side.

Here, it is assumed that the predetermined length protruding length formed on the second fixing piece 12 is 40mm to 50mm, preferably 45mm, but the present invention is not limited thereto, and the second fixing piece 12 is provided by the contractor. The length of can be adjusted.

In addition, the material of the ground core 10 including the first fixing piece 11 and the second fixing piece 12 is made of stainless steel that is durable semi-permanently.

On the other hand, the discharge rod 20 is composed of a plurality of cylinders, each upper end is composed of the same diameter as the first fixing holes (11a, 11b) and the second fixing holes (12a, 12b) first fixing piece (11) For accommodating and engaging the first fixing holes 11a and 11b and the second fixing holes 12a and 12b from the lower end of the first coupling part and the second fixing part 12 toward the upper end, respectively. A step is formed, and the lower end is formed in the shape of an awl blade so as to be inserted and fixed to the ground.

That is, the discharge rod 20 has lower ends of the first fixing holes 11a and 11b and the second fixing holes 12a and 12b except for the ground hole 13 formed in the third coupling portion of the second fixing piece 12. Are inserted and fixed respectively. In addition, the material is made of stainless steel semi-permanent durability.

Meanwhile, the conductive molding member 30 includes first fixing holes 11a and 11b and second fixing holes 12a and 12b formed in the first fixing piece 11 and the second fixing piece 12 of the ground core 10. In the state in which the discharge rod (20) is coupled to) is formed in the shape of a disc through conductive concrete (concrete) or conductive mortar (mortar).

At this time, the conductive molding member 30 is the first coupling of the first fixing piece 11, except for the ground hole 13 formed in the position of the third coupling portion spaced a predetermined length toward the other side from the second fixing hole (12b) The first fixing holes 11a and 11b formed in the portion and the second fixing holes 12a and 12b formed in the second coupling portion of the second fixing piece 12 are enclosed in a disc shape through conductive concrete or conductive mortar. Molded.

At this time, the conductive mortar is characterized in that it is composed by mixing a cement-based inorganic binder, mineral water absorbent, conductive carbon fiber, calcium cellulose aluminate, absorbent polymer dispersant or silica sand, reaction control agent and the like.

In addition, it is assumed that the diameter of the conductive molding member 30 is 410 mm to 430 mm, preferably 420 mm, and the thickness of the conductive molding member 30 is 20 mm to 35 mm preferably 30 mm, but the present invention is limited thereto. The diameter of the conductive molding member 30 may be the same as or larger than the diameter of the lower end of the electric pole 1.

In addition, the ground lead terminal 40 is formed in a cylindrical shape to form a screw portion 41 at the lower end of the third coupling portion of the ground core material 10, the ground wire 43 and the upper end drawn from the ground wire outlet of the electric pole (1) Both lead rods 42 provided on one side are connected and fixed.

In addition, the ground wire 43 constitutes a spiral portion 43b which is surface-contacted to be electrically conductive in one side of the lead rod 42, and is composed of a covering portion 43a which surrounds the spiral portion 43b.

In addition, the ground lead terminal 40 is inserted into the ground hole 13 formed in the third coupling portion of the second fixing piece 12 of the ground core 10, the first provided in the upper side of the ground hole 13 The second nut N2 is provided below the nut N1 and the ground hole 13.

Here, the material of the ground lead terminal 40 is made of durable semi-permanent stainless steel, the diameter is 15mm to 17mm preferably 16mm, the length is 0.07m to 2.1m preferably 2m length It is formed to have.

On the other hand, with reference to Figures 7 to 11 with respect to the construction method of the grounding device using a circular concrete ground electrode according to the present invention.

First, referring to FIG. 7, a method of constructing a grounding apparatus using a circular concrete ground electrode according to the present invention will be described. The first fixing piece 11 and one side and the other side having the first fixing holes 11a and 11b formed on one side and the other side thereof will be described. A center of each of the second fixing pieces 12 having the second fixing holes 12a and 12b formed therein and the ground hole 13 formed at a position spaced a predetermined distance away from the second fixing hole 12b. To overlap and weld in a cross shape to form a ground core 10 (S10).

Subsequently, the first fixing holes 11a and 11b formed in the first fixing piece 11 and the second fixing holes 12a and 12b formed in the second fixing piece 12 are formed by the step formed at the upper end of the discharge rod 20. ) To combine each (S20). At this time, the coupling of the discharge rod 20 is coupled toward the upper end from the lower end of the first fixing holes (11a, 11b) and the second fixing holes (12a, 12b).

Subsequently, the discharge rod 20 is formed in the first fixing holes 11a and 11b and the second fixing holes 12a and 12b formed in the first fixing piece 11 and the second fixing piece 12 of the ground core 10. In the combined state is molded in the form of a disc through the conductive concrete or conductive mortar to form a conductive molding member 30 (S30). In this case, the conductive molding member 30 is generated except for the ground hole 13 formed in the second fixing piece 12.

In addition, a ground lead formed in a cylindrical shape and having a threaded portion 41 at a lower end corresponding to a position at which the ground core 10 and the discharge rod 20 are fastened, and having a lead rod 42 provided at one side of the upper end thereof The terminal 40 is inserted into the ground hole 13 of the second fixing piece 12 and fastened through the first nut N1 and the second nut N2 (S40).

Meanwhile, referring to FIGS. 8 and 9, the process after the step S40 is as follows.

After the step S40, the excavation is performed to a depth of 2m to 2.5m from the ground (E) at the position to embed the electric pole (1), 0.25 from the ground excavated to bury the conductive molding member 30 Further drilling is carried out to a depth of m (S50).

That is, the grounding device construction method using the circular concrete grounding electrode according to the present invention, the conventional construction that must be carried out excavation of 2m to 2.5m to bury the ground electrode separately from the excavation of 2m to 2.5m for embedding electric pole The method has been greatly improved. As a result of the excavation construction of 2m to 2.5m + 0.25m at the location of the electric pole embedding, the grounding pole and the electric pole are buried, and thus the electric pole and the grounding pole are simultaneously buried in a single excavation construction.

Subsequently, by using the ground wire 43 connected to the ground lead terminal 40 and a temporary temporary rope, the conductive molded member to which the ground core 10, the discharge rod 20, and the ground lead terminal 40 are fastened ( 30) is placed at the bottom of the ground excavated (S60).

Subsequently, the ground core 10, the discharge rod 20, and the ground lead terminal 40 are removed so that the rope is pulled out and removed, and the depth between the ground E and the ground excavated has a depth of 2 m to 2.5 m. Embedded conductive molded member 30 is buried in the earth (S70).

Subsequently, the electric pole 1 into which the ground wire 43 is inserted is dried on the embedded conductive molding member 30 (S80).

Then, both the lead rod 42 provided on the upper side of the ground lead terminal 40 and the ground wire 43 drawn out from the pole 1 are connected and fixed, and the pole pole 1 on which the ground ground is excavated is placed. Landfill to fill (S90).

As described above, unlike the conventional vertically buried ground electrode, the conductive molding member 30 is horizontally buried in the lower end of the pole 1, or by installing a single conductive molding member 30 horizontally buried in the ground, The molding member 30 is located at the lowest point to improve the moisture content, and is conductive due to the earth pressure applied to the conductive molding member 30 according to the horizontal embedding and the load of the electric pole 1 embedded above the conductive molding member 30. The contact effect is improved by maximizing the contact density between the molding member 30 and the ground.

Meanwhile, referring to FIGS. 10 and 11, the process after the step S80 is as follows.

After the step S80, another conductive molding member 30 is excavated to a depth of 2.75m from the ground (E) at another position to embed (S100).

Subsequently, the procedure of steps S10 to S40 is performed (S110).

Subsequently, the ground core 10, the discharge rod 20, and the ground are implemented so that the procedure of the step S60 is performed and the depth between the ground E and the ground excavated at another position has a depth of 2 m to 2.5 m. The conductive molding member 30 to which the lead terminal 40 is fastened is embedded with earth and sand (S120).

Subsequently, a ground wire 43 is formed between the lead rod 42 provided on one side of the ground lead terminal 40 and the ground lead terminal 40 coupled to the molding member 30 embedded in the step S120. Connect through (S130).

Then, the ground is excavated for embedding another conductive molded member 30 (S140).

Grounding device construction method using a circular concrete ground electrode according to the present invention, by continuously performing the procedure of step S100 to step S140, a single pole (1), the ground core (10), discharge rod 20 and The ground lead terminal 40 can be constructed by connecting a plurality of conductive molding members 30 fastened in series.

On the other hand, with reference to Figure 12 is a look at the grounding device (A) using a circular concrete grounding electrode according to another embodiment of the present invention as follows.

As shown in FIG. 12, the grounding device A using the circular concrete ground electrode according to another embodiment of the present invention includes a ground core 10, a conductive molding member 30, and a ground lead terminal 40. do.

Specifically, the ground core 10 is bent at one side and the other side of the first fixing piece 11 to form the first discharge electrode 11c, and is bent at one side and the other side of the second fixing piece 12 to form a second. The discharge electrode 12c is formed, and a third coupling part having a ground hole 13 for coupling the ground lead terminal 40 to the other side of the second fixing piece 12 is formed.

At this time, the third coupling part is connected to and fixed to the other end of the second discharge electrode 12c, and has a ground hole 13 having the same size as the diameter of the ground lead terminal 40 so as to accommodate and overlap the ground lead terminal 40. This is made up.

In addition, the ground core 10 is arranged so that the first fixing piece 11 and the second fixing piece 12 overlap each other in a cross shape with respect to the center, and are welded and fixed.

In addition, as shown in FIG. 13, the second fixing piece 12 of the ground core 10 also protrudes a predetermined length toward the other side such that the second discharge electrode 12c is not folded, and the second fixing piece 12 is not folded. It can be configured to be welded to the bottom of the).

Meanwhile, the conductive molding member 30 includes the first discharge electrode of the first fixing piece and the second discharge electrode of the second fixing piece except for the ground hole 13 formed in the third coupling portion of the second fixing piece of the ground core 10. It is molded through conductive concrete or conductive mortar.

At this time, the conductive molding member 30 is formed in the form of a disc through conductive concrete or conductive mortar, the conductive mortar, cement-based inorganic binder, mineral-based water absorbent, conductive carbon fiber, calcium cellulose aluminate, absorbent polymer dispersant or silica sand and It is characterized by comprising a reaction regulator and the like.

In addition, it is assumed that the diameter of the conductive molding member 30 is 410 mm to 430 mm, preferably 420 mm, and the thickness of the conductive molding member 30 is 20 mm to 35 mm preferably 30 mm, but the present invention is limited thereto. The diameter of the conductive molding member 30 may be the same as or larger than the diameter of the lower end of the electric pole 1.

In addition, the ground lead terminal 40 is formed in a cylindrical shape to form a screw portion 41 at the lower end corresponding to the position where the third coupling portion and the discharge rod 20 of the ground core 10 is fastened, and the electric pole (1) Both of the ground wire 43 drawn from the ground wire lead-out of the wire) and the lead rod 42 provided on one side of the upper end are connected.

In addition, the first nut N1 is inserted into the ground hole 13 formed in the second fixing piece 12 of the ground core 10 of the ground lead terminal 40 and is provided on the upper side of the ground hole 13. It is fastened by the second nut N2 provided on the lower side of the ground hole 13, the ground wire 43 constitutes a spiral portion 43b which is surface-contacted to be electrically conductive in one side of the lead rod 42, And the covering part 43a which surrounds the spiral part 43b.

Here, the material of the ground lead terminal 40 is made of durable semi-permanent stainless steel, the diameter is 15mm to 17mm preferably 16mm, the length is 0.07m to 2.1m preferably 2m length It is formed to have.

In addition, the ground lead terminal 40, as shown in Fig. 14, after receiving and compressing and fixing the ground wire 43 drawn out from the electric pole 1 in the groove inside the upper end of the lead rod 42, the heat shrink tube 44 ) Is positioned at a portion where the lead rod 42 and the ground wire 43 are in contact with each other, and then contracts by applying heat to prevent foreign matter from entering between the lead rod 42 and the ground wire 43.

Looking at the construction method of the grounding device using a circular concrete grounding electrode according to another embodiment of the present invention as described above are as follows.

First, the first discharge electrode is formed by bending on one side and the other side of the first fixing piece, and the second discharge electrode is formed by bending on one side and the other side of the second fixing piece, and on the other side of the first fixing piece or the second fixing piece. A ground core 10 including a third coupling part for coupling the ground lead terminal 40 is formed.

Subsequently, except for the third coupling portion of the ground core 10, the conductive molding member is formed through a doped concrete or conductive mortar to surround the first discharge electrode of the first fixing piece and the second discharge electrode of the second fixing piece. 30 is molded.

Subsequently, a lead rod provided on one side of the upper end thereof is coupled, and the ground lead terminal 40 to which the ground wire drawn out from the ground wire outlet of the pole 1 is connected and fixed is coupled to the third coupling part of the ground core 10. .

Subsequently, the excavation is performed at a depth of 2 m to 2.5 m from the ground at the position where the electric pole is to be embedded, and an additional excavation is performed at a depth of 0.25 m from the excavated ground to embed the conductive molding member 30. .

Subsequently, by using a ground wire temporarily connected to the ground lead terminal 40 and a temporary temporary rope, the conductive molding member 30 to which the ground core 10 and the ground lead terminal 40 are fastened is excavated at the bottom of the ground. Settle down.

Subsequently, while the rope is removed, the conductive molding member 30 to which the ground core 10 and the ground lead terminal 40 are fastened so that the depth between the ground and the ground ground excavated has a depth of 2 m to 2.5 m. Landfill

Subsequently, the electric pole 1 into which the ground wire is inserted is dried over the embedded conductive molding member 30.

Then, the lead rod provided on one side of the ground lead terminal 40 and the battery wire drawn out from the pole 1 are connected to each other, and the excavated ground is embedded to cover the dried pole 1. do.

As described above and described with reference to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as described above, it is a deviation from the scope of the technical idea It will be understood by those skilled in the art that many modifications and variations can be made to the invention without departing from the scope of the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

A: Grounding device using circular concrete ground electrode
E: Ground N1: First Nut
N2: 2nd nut 1: pole
2: conventional ground rod 10: ground core
11: 1st fixing piece 11a, 11b: 1st fixing hole
11c: first discharge electrode 12: second fixing piece
12a and 12b: second fixing hole 12c: second discharge electrode
13: ground hole 20: discharge rod
30: conductive molded member 40: ground lead terminal
41: screw portion 42: lead rod
43: ground wire 43a: sheath
43b: spiral 44: heat shrink tube

Claims (10)

In the grounding apparatus using a circular concrete ground electrode,
A first coupling part for coupling the discharge rod 20 to the first fixing piece is formed, and a second coupling portion for coupling the discharge rod 20 to the second fixing piece is formed, and spaced apart from the second coupling portion by a predetermined distance. A ground core (10) forming a third coupling portion for coupling the ground lead terminal (40) to the other side thereof;
A discharge rod 20 coupled to and fixed to a lower end of the first coupling part and the second coupling part of the ground core 10;
In the state where the discharge rod 20 is coupled to the lower end of the first coupling portion and the second coupling portion of the ground core 10, so as to surround the first fixing piece and the second fixing piece except for the third coupling portion. Conductive molding member 30 to be molded; And
A ground lead terminal 40 coupled to the third coupling portion of the ground core 10 and including a lead rod provided on one side of the ground core 10 and connected to and fixed by a ground wire drawn from the ground wire outlet of the pole; Grounding device using a circular concrete ground electrode, characterized in that it comprises a. The method of claim 1,
The first coupling portion forms a first fixing hole for coupling the discharge rod 20, the second coupling portion forms a second fixing hole for coupling the discharge rod 20, and the third coupling portion Grounding device using a circular concrete ground electrode, characterized in that to form a ground hole for coupling the ground lead terminal (40). In the grounding device construction method using a circular concrete ground electrode,
(a) a first fixing piece having a first fixing hole formed at one side and the other side, and a second fixing hole formed at one side and the other side, and a ground hole formed at a position spaced a predetermined distance from the second fixing hole toward the other side; Forming a ground core by overlapping and welding the cross-section with respect to the center of each of the two fixing pieces;
(b) coupling each of the first fixing hole formed in the first fixing piece and the second fixing hole formed in the second fixing piece by a step formed at an upper end of the discharge rod;
(c) a conductive molding member formed by forming a disc through conductive concrete or conductive mortar in a state in which the discharge rod is coupled to the first fixing hole and the second fixing hole formed in the first fixing piece and the second fixing piece of the ground core; Generating a; And
(d) is formed in a cylindrical shape to form a screw portion at the lower end corresponding to the position where the ground core material and the discharge rod is fastened, and inserts a ground lead terminal including a lead rod provided at one side of the ground rod into the ground hole of the second fixing piece. Fastening through the first nut and the second nut; Grounding device construction method using a circular concrete ground electrode, characterized in that it comprises a. The method of claim 3, wherein
After the step (d)
(e) Excavation is performed at a depth of 2m to 2.5m from the ground at the position where the pole is to be buried, and additional excavation is performed at a depth of 0.25m from the excavated ground to embed the conductive wire forming member. Making;
(f) using the ground wire connected to the ground lead terminal and a temporarily temporary rope, mounting the conductive molded member to which the ground core, the discharge rod, and the ground lead terminal are fastened to the lowermost ground of the excavated ground;
(g) The rope is pulled out and removed, and the conductive molding member to which the ground core, the discharge rod, and the ground lead terminal are fastened is embedded with earth and sand to have a depth of 2 m to 2.5 m between the ground and the excavated ground. Making;
(h) drying the electric pole with the ground wire inserted above the embedded conductive molded member;
(i) connecting and fixing both the lead rods provided on one side of the ground lead terminal and the ground wires drawn from the poles, and embedding the excavated ground so as to cover the dried poles; Grounding device construction method using a circular concrete ground electrode, characterized in that it comprises a. The method of claim 3, wherein
After step (h),
(j) performing an excavation construction at a depth of 2.75 m from the ground at another position where another conductive molded member is to be embedded;
(k) implementing the procedure of steps (a) to (d);
(l) conducting the procedure of step (f), and forming the conductive core to which the ground core, discharge rod and ground lead terminal are fastened so that the depth between the ground and the ground excavated at another position has a depth of 2 m to 2.5 m. Embedding the member with earth and sand;
(m) connecting a lead rod provided on one side of the ground lead terminal and a discharge rod coupled to the molded member buried in the step (l) through a ground wire; And
(n) embedding the excavated ground for embedding another conductive molded member; Grounding device construction method using a circular concrete ground electrode, characterized in that it comprises a. In the grounding apparatus using a circular concrete ground electrode,
The first discharge electrode is formed by bending on one side and the other side of the first fixing piece, and the second discharge electrode is formed by bending on one side and the other side of the second fixing piece, but the ground lead terminal 40 is formed on the other side of the second fixing piece. A ground core 10 forming a third coupling part for coupling;
Conductive molding member formed through conductive concrete or conductive mortar so as to surround the first discharge electrode of the first fixing piece and the second discharge electrode of the second fixing piece, except for the third coupling portion of the ground core 10. 30; And
A ground lead terminal 40 coupled to the third coupling part of the ground core 10 and having both a lead rod provided on one side of the ground core 10 and a ground wire drawn from the ground wire outlet of the pole 1; Grounding device using a circular concrete ground electrode, characterized in that it comprises a. The method according to claim 6,
The conductive mortar,
A grounding device using a circular concrete ground electrode, characterized in that the mixture is composed of a cement-based inorganic binder, mineral water absorbent, conductive carbon fiber, calcium cellulose aluminate, absorbent polymer dispersant or silica sand and reaction control agent. The method according to claim 6,
The conductive molding member 30,
A grounding device using a circular concrete ground electrode, characterized in that the diameter is 410mm to 430mm, the thickness is formed from 20mm to 35mm. The method according to claim 6,
The ground lead terminal 40,
A ground using a circular concrete ground electrode, characterized in that the ground wire is received and compressed in the groove inside the upper end of the lead rod, and then fixed to the lead rod and the ground wire by applying heat to a heat contraction tube located at a portion where the lead rod and the ground wire meet. Device. In the grounding device construction method using a circular concrete ground electrode,
(a) bending the one side and the other side of the first fixing piece to form a first discharge electrode, bending the one side and the other side of the second fixing piece to form a second discharge electrode, and the other of the first fixing piece or the second fixing piece Forming a ground core 10 having a third coupling part for coupling the ground lead terminal 40 to a side surface thereof;
(b) Conductive through conductive or conductive mortar to surround the first discharge electrode of the first fixing piece and the second discharge electrode of the second fixing piece, except for the third coupling portion of the ground core 10. Molding the molding member 30;
(c) constituting a lead rod provided on one side of the upper end, and coupled to the third coupling portion of the ground core 10, the ground lead terminal 40 to which the ground wire drawn out from the ground wire outlet of the pole 1 is connected and fixed. Making a step;
(d) Excavation is performed at a depth of 2m to 2.5m from the ground at the position where the electric pole is to be embedded, and additional excavation is performed at a depth of 0.25m from the excavated ground to embed the conductive molding member 30. Performing;
(e) The excavation construction of the conductive molding member 30 to which the ground core 10 and the ground lead terminal 40 are fastened by using a ground wire temporarily connected to the ground lead terminal 40 and a temporary temporary rope. Seating at the bottom of the ground;
(f) The conductive molding member 30 to which the ground core 10 and the ground lead terminal 40 are fastened so that the rope is removed, and the depth between the ground and the ground excavated has a depth of 2 m to 2.5 m. Landfill);
(g) drying the electric pole 1 into which the ground wire is inserted above the embedded conductive molding member 30; And
(h) connecting and fixing the lead rod provided on one side of the ground lead terminal 40 and the battery wire drawn from the pole 1, and embedding the excavated ground so as to surround the dried pole 1 ; Grounding device construction method using a circular concrete ground electrode, characterized in that it comprises a.

Images