KR200257071Y1 - Ground for electric pole using the material decreasing the shaped ground resistance - Google Patents

Abstract

The present invention relates to a pole grounding device installed on the ground to support the overhead distribution line,

Forming a grounding resistance reducing material to integrate into the grounding device, and combine the grounding device with the bottom of the pole, so that the grounding device can be buried together with the laying of the pole. Grounding equipment for electric poles using molded earth resistance reducing material, characterized in that to greatly reduce the earth resistance of the device.

Description

Ground for electric pole using the material decreasing the shaped ground resistance}

The present invention relates to a pole grounding device installed on the ground to support the overhead distribution line,

Forming a grounding resistance reducing material to integrate into the grounding device, and combine the grounding device with the bottom of the pole, so that the grounding device can be buried together with the laying of the pole. The present invention relates to a grounding device for electric poles, characterized by greatly reducing the earth resistance of the device.

In general, the power generated by a power plant goes through several stages of transformation to reduce transmission losses and then reaches a secondary substation near the city center.

After reaching the secondary substation, the power is stepped down to the distribution voltage, and then supplied to the general customer through the distribution line.

The distribution line is composed of a distribution line and a pole for supporting the distribution line, such a distribution line is usually installed in the form of overhead lines spaced at a certain height from the ground along the roadside of the city for convenience of installation and management.

The distribution line installed as above is exposed to the air, and thus extends over a long distance, frequently receiving invasion of abnormal voltages such as lightning strikes, and frequently causing obstacles such as high-low pressure mixing and ground faults.

In order to protect various power distribution equipments from abnormal voltage or current invading power distribution lines due to the above accidents, and to prevent damage to human beings, it is necessary to quickly discharge the abnormal voltages in the ground through ground wires and ground rods. There is.

In order to ensure safety from such accidents, the electrical equipment technical standards stipulate certain standards to be followed in grounding distribution lines.

In order to ground the power distribution line according to the above standard, conventionally, as shown in Figure 1a, the ground wire 4 and the ground rod 3 installed on the pole 1 are directly connected and spaced at least a predetermined distance (50 cm) from the pole, and then a predetermined depth. The ground rod was buried directly below (75 cm).

This construction method is to dig a hole for embedding electric pole first, and then dig a hole to bury the ground wire from the hole to a certain point where safety is secured, and then install a ground rod using a fulcrum hammer, connect the ground wire, and then bury it. It was the way.

However, such a grounding method requires digging additional ground to bury ground wires in addition to the holes for laying electric poles in the city center where customers are crowded. Therefore, the existing paved roads and sidewalk blocks have to be dug up. There is a problem that excessively takes a long time and construction period.

In addition, the construction method requires a lot of time to bury the ground rod (3) by hammering the ground rod (3) at a depth of about 75 cm below the surface of the ground, as well as other underground facilities (eg, water pipes, Gas pipes, communication cables, etc. are often damaged.

In addition, since the construction method is carried out in areas where various facilities such as buildings and residential areas in the city center are concentrated, it is difficult to secure a space for obtaining a prescribed grounding resistance according to the local situation, and thus it is often difficult to obtain a predetermined grounding resistance value. .

In order to solve the above problems, as shown in FIG. 1B, the ground rods 3 are vertically connected in series to be installed, or two or more ground rods 3 are spaced apart by a predetermined distance (about 2M) or more in parallel. It also became.

However, this grounding method was able to lower the theoretical grounding resistance, but in practice, it still only solved the problem of securing space in the city, which only added to the construction difficulties, and also increased the construction cost and delayed the construction period. there was.

In order to solve the above problems, the present applicant has devised a utility model registration application (application number 20-1999-29168) by devising a grounding device for electric pole made of insulation as shown in Figure 2a, Figure 2b, Registration has been confirmed after the technical evaluation.

The invention described in FIGS. 2A and 2B incorporates a plurality of metal fixing pieces 6 on the bottom surface to inject and mold the insulation cover 5, and to the nut 7 provided at the lower end of the insulation cover 5. The grounding device (3) is screwed, and the grounding device is configured in such a way that the ground wire (4) is connected to the center of the fixing piece (6) of the insulating cover (5) by the bolt (8). By connecting the device to the bottom of the pole to be embedded together to solve the various problems in the above-described construction, while being able to bury the ground rod deeper than before, it was possible to secure a lower ground resistance than conventional.

However, the grounding method can significantly reduce the discomfort in the construction, but there is a problem that the overall grounding resistance can not be significantly lowered because the contact resistance between the ground electrode and the earth, which is the most important factor for determining the grounding resistance, cannot be improved. .

In general, the important factors that determine the ground resistance in installing the ground electrode are the characteristics of the ground electrode itself, the characteristics of the surrounding soil, and the contact resistance between the ground electrode and the soil, where the surrounding soil is already determined according to the landfill situation of the state. Since the grounding electrode is a product that is already commercialized, the main variable for determining the grounding resistance is the contact resistance between the grounding electrode and the earth, and thus efforts are being made to improve it.

In order to reduce the contact resistance between the earth electrode and the earth, when the pole was buried, the ground resistance reducing agent was mixed with water between the lower end of the pole and the earth.

However, this construction method has the effect of remarkably improving the grounding resistance.However, when the grounding rod is embedded, dig a hole for embedding the pole and mix the grounding resistance reducing agent with water in the form of dough and fill it up again. As the work process became very complicated, such as setting up a pole, the construction time was long, and various construction inconveniences were required, such as the necessity of overlapping additional work during the work.

The present application has been made to solve the two problems of the prior art as described above (complexity of construction method and high ground resistance) at a glance,

The main purpose of the present invention is to reduce the grounding resistance by molding the grounding resistance reducing material into an integrated state by combining the grounding resistance reducing material with the conventional grounding device. At the same time, the laying of the grounding device is also carried out, and the construction method of the grounding work is remarkably improved.

Figure 1a is a installation diagram of a ground rod installed in series in a conventional direct buried method

Figure 1b is a view of the installation of ground rods in parallel in the conventional direct buried method

Figure 2a is an exploded perspective view of the grounding device using a conventional insulating cover

Figure 2b is a state diagram of the installation of the grounding apparatus using a conventional insulating cover

Figure 3a is an exploded perspective view of the grounding device for electric pole of the present application

Figure 3b is a side cross-sectional view of the electric pole grounding apparatus

Figure 3c is a plan view of the electric pole grounding apparatus

4 is an installation state diagram of the electric pole grounding apparatus of the present application

<Explanation of symbols on main parts of the drawings>

1: pole 2: lead wire 3: ground rod

4 grounding wire 5 insulation cover 6 fixing piece

7: nut 8: bolt 10: insulated

11: electric pole insertion hole 12: groove 13: reinforcement part

14: fixing part 15: fixing groove 16: reinforcement shaft

20: ground portion 21: ground rod 22: fixed piece

23: connector 24: connection groove 25: grounding pipe

30: Insulation resistance reducing material molding

40 coupling part 41 coupling shaft 42 screw part

43: nut 50: ground wire 51: sheath

52: spiral 60: wedge

The configuration and coupling relationship of the present application for achieving the above object will be described with reference to FIG. 3.

First, look at the composition of the draft

Insulation box 10 injection-molded to place the pole insertion hole 11 into which the lower end of the pole 1 can be inserted, and the fixing part 14 for coupling the grounding part 20 to the bottom. and; A coupling part 40 for fixing and coupling the ground part 20 to the lower end of the insulator box 10; A grounding part 20 screwed to the insulator box 10 using the coupling part 40 as a connecting shaft; An insulation resistance reducing material molding 30 formed in a cylindrical shape to surround the ground portion 20 by a predetermined thickness; A ground line 50 coupled to the side of the ground portion 20 to electrically connect the ground portion 20 to the outside; A wedge (60) to prevent the insulator (40) from being separated from the pole when the insulator (10) is coupled with the pole (1); Characterized in that made.

The insulation box includes a pole insertion hole (11) for inserting the pole (1) again; A fixing part 14 for fixing and supporting the connecting shaft 41 of the coupling part 40; A fixing groove 15 for inserting and fixing the connecting shaft 41; A reinforcing portion 13 and a reinforcing shaft 16 for supporting the insulation resistance reducing material molded product 30; Characterized by

The coupling part 40 further includes a connecting shaft 41 for connecting the insulator box 10 and the ground part 20 coaxially; A screw part 42 formed at an end of the connecting shaft 41 and coupled to the nut 43; A nut 43 screwed to the screw portion 42 to fix and couple the ground portion 20; Characterized by

The ground portion 20 is a cylindrical connector 23 having a connection groove 24 of the inner diameter slightly larger than the outer diameter of the connecting shaft 41; A fixing piece 22 radially welded to the connector 23 at a predetermined height; A grounding rod (21) welded perpendicular to the end of the fixing piece (22); A ground pipe (25) welded to be positioned at a lower end of the fixing piece (22) and to a side end of the connector (23); Characterized by configured,

The ground wire 50 is the cover portion 51 is exposed to the outside again; A spiral portion 52 which is surface-contacted to be electrically conductive in the ground pipe 25; Characterized in that made.

Looking at the coupling relationship of the above configuration,

First, the end of the ground wire 50 is peeled off by a predetermined length to make the spiral portion 52, and then the spiral portion 52 is inserted into the ground tube 25, and the ground tube 25 is crimped to form the ground tube 25. ) Tighten so that it does not fall out. At this time, the foreign material enters between the ground pipe 25 and the spiral portion 52 of the ground wire 50 to increase the contact resistance so as not to disturb the flow of electricity, and the ground pipe 25 and the ground wire 50 In consideration of the contact resistance between the spiral portion (52) of the coupling to combine as wide as possible. The inner diameter of the ground pipe 25 should be designed in consideration of the outer diameter of the ground wire 50 so that the spiral portion 52 of the ground wire 50 can be easily inserted, the outer diameter of the ground wire 50 is defined in the electrical equipment technical standards Follow the standards.

Next, after mixing the grounding resistance reducing material with water, using a separate molding equipment (not shown) around the fixed piece 22 of the grounding portion 20 in a cylindrical shape by a certain thickness (h) of the grounding resistance reducing material molding ( 30). Here, the method of molding the ground resistance reducing material molded article 30 does not require a special method, and generally, it is sufficient to form a special shape by pouring the kneaded concrete with the steel in the middle. However, the diameter of the ground resistance reducing material molding 30 should be molded to be equal to the diameter of the insulator box, and the lower height of the ground resistance reducing material molding 30 should not exceed the height t of the connecting shaft.

The grounding resistance reducing material used here can be used as long as it is a commercially available reducing material. However, due to the nature of the present application, in order to maintain the constant resistance by adsorbing and discharging water, the earth-based change of the earth resistance is reduced. Is recommended.

Subsequently, one end of the connecting shaft 41 is inserted into and fixed to the fixing groove 15 formed at the lower end of the insulator box 10, and the connecting shaft 41 is inserted into the connector 23 of the ground portion 20. Then, by assembling the nut 43 to the screw portion 42 formed at the end of the connecting shaft 41 to fix the grounding portion 20, the assembly of the grounding device is completed.

The wedge 60 is always provided near the grounding device so that it can be used at any time during the pole laying work.

In addition, the metal material used for the grounding portion 20, the coupling portion 40, and the like may be made of a material such as stainless so as not to corrode even if it is embedded in the basement for a long time.

Here, as an embodiment of the grounding apparatus of the present application, the number of the grounding rods 21 formed in the grounding portion 20 is expressed as four, but this is not a fixed number and may reduce the grounding resistance according to the situation where the electric pole is buried. If necessary, the number can be increased or decreased as needed. At this time, as the number of ground rods 21 increases, the number of fixing pieces 22 naturally increases along with it.

In addition, if necessary, the ground resistance can be reduced by increasing the length of the ground rod by a simple design change without increasing the number of ground rods as described above.

Referring to the process of embedding the grounding device configured as described above in combination with the electric pole as follows.

First, drill holes for embedding poles in proportion to the length of poles, and then drill additionally to the required depth to make it easier to bury ground rods, but do not dig out the excavated soil. The additional excavation of the holes here is to facilitate the laying of ground rods.

Next, considering the outer diameter of the lower pole of the pole, select the grounding device whose inner diameter is the same as or slightly larger than the outer pole of the pole. Then, align the pole of the pole with the grounding device at the bottom of the pole, and then lower the pole of the pole. Tighten them until they are tight. Subsequently, insert a pole for fixing the pole between the pole and the grounding device so that the grounding device is not easily separated from the pole.

Then, lift the ground wire carefully and erect the pole using the pole laying equipment (not shown) to prevent the ground wire from being damaged while the pole is buried.When the pole is buried, additional excavation will be made to drill the soft soil and the ground rod will weigh the pole. Buried together by. After filling the soil and fixing the pole, the ground wire is connected to the lead wire and insulated, and the laying of the grounding device together with the laying of the pole is completed.

As described above, when the electric pole is embedded using the present invention, the ground rod is buried together with the electric pole laying without the need for a separate process for placing the ground rod or an additional process for molding the earth resistance reducing material at the place of the electric pole. Since it is also made to simplify the work process will have the effect of significantly reducing the construction cost and construction time.

In addition, the contact resistance is greatly reduced by using a grounding resistance reducing material, and the grounding rod is embedded deeper in the basement than the conventional direct embedding method because it is connected to the bottom of the pole to bury the grounding device. Can be reduced.

In addition, since the ground rod is buried vertically below the embedding position of the pole, there is no fear of damaging other underground facilities among the facilities of the ground rod.

In addition, since the ground rods can be buried in a radial manner, the fault current can be quickly distributed, minimizing the secular variation of the ground resistance, and semipermanently reflecting the life of the grounding device.

Claims (4)

Insulation box 10 injection-molded to place the pole insertion hole 11 into which the lower end of the pole 1 can be inserted, and the fixing part 14 for coupling the grounding part 20 to the bottom. and; A coupling part 40 for fixing and coupling the ground part 20 to the bottom of the insulator; A ground part 20 screwed to the insulator box 10 using the coupling part as a connecting shaft; An insulation resistance reducing material molded article 30 formed in a cylindrical shape to surround the ground portion by a predetermined thickness; A ground line 50 coupled to the side of the ground portion to electrically connect the ground portion to the outside; A wedge (60) for preventing the insulator from being separated from the pole when the insulator (10) is coupled with the pole (1); Electric pole grounding device using molded earth resistance reducing material characterized in that The method of claim 1, The insulation box includes a pole insertion hole (11) for inserting the pole (1) again; A fixing part 14 for fixing and supporting the connecting shaft 41 of the coupling part 40; A fixing groove 15 for inserting and fixing the connecting shaft; A reinforcing portion 13 and a reinforcing shaft 16 for supporting the insulation resistance reducing material molded product 30; Electric pole grounding device using molded earth resistance reducing material characterized in that The method of claim 1, The coupling part 40 further includes a connecting shaft 41 for connecting the insulator box 10 and the ground part 20 coaxially; A screw portion 42 formed at an end of the connecting shaft and coupled to the nut 43; A nut 43 screwed to the screw portion 42 to fix and couple the ground portion; Electric pole grounding device using molded earth resistance reducing material characterized in that The method of claim 1, The ground portion 20 is a cylindrical connector 23 having a connection groove 24 of the inner diameter slightly larger than the outer diameter of the connecting shaft 41; A fixed piece 22 radially welded to the connector at a predetermined height; A grounding rod (21) welded perpendicular to the end of the fixing piece (22); A ground pipe (25) welded to be positioned at a lower end of the fixing piece (22) and to a side end of the connector (23); Electric pole grounding device using molded earth resistance reducing material characterized in that the configuration