KR101075901B1 - a controlling system for the grounding resistance to grounding conductor - Google Patents

Abstract

The present invention relates to a grounding resistance control system of the grounding rod.

In particular, it is made of a configuration in which one or more flow holes through which conductive fluid passes through are integrally formed in the ground rod embedded to a predetermined depth of the ground, and the fluid chamber is connected to the flow holes to store a predetermined amount of conductive fluid.

Accordingly, the conductive fluid is flowed to the ground rod at regular cycles to obtain a constant ground resistance regardless of oxidation of the ground rod.

Flow hole, ground rod, micro tube, fluid chamber

Description

Grounding resistance control system for grounding rods {a controlling system for the grounding resistance to grounding conductor}

The present invention can obtain a constant ground resistance irrespective of oxidation of the ground rod itself through a configuration that flows a small amount of conductive fluid to the ground rod continuously or continuously, and realizes the maximum ground resistance, due to lightning or abnormal current The ground resistance control system of the ground rod to prevent damage to the equipment.

In general, the ground is installed to connect the ground electrode to the soil to protect the equipment using electricity, and the risk factors include lightning and abnormal current.

In addition, the resistance flowing to the ground is referred to as ground resistance, and the ground resistance refers to the sum of the conductor resistance of the ground lead wire and the ground electrode, the contact resistance between the ground electrode and the soil, and the resistance of the soil around the ground electrode.

Factors that change the ground resistance may include changes in ground resistance and earth resistivity, and the ground resistance decreases exponentially with the number of ground rods or ground plates.

When the grounding resistance is reduced to some extent, a threshold value that is no longer reduced is reached, and no matter how many grounding rods or grounding plates are attached, the grounding resistance is no longer reduced.

The threshold value of the ground resistance is related to the earth resistivity and the coplanar area at grounding, and the ground resistance is related to the area of the ground rod or the ground plate. The curve of earth resistance decreases exponentially.

In addition, the earth resistivity depends on several variables, such as soil moisture content, chemical composition of water content, soil type geological composition, earth temperature, climate and regional characteristics.

Designing the ground to meet these conditions is good protection for the equipment.

In connection with such a technique, a ground plate and a ground rod are disclosed in Korean Patent Application Publication No. 2008-92899, and the construction thereof is a ground rod body 1 or a ground plate body used for increasing the ground resistance, as shown in FIGS. (2) is made of a configuration in which the open-cell foam metal 12 is connected to one side of the copper plate (11).

However, the grounding plate and grounding rods made of the foamed metal 12 as described above are also inconvenient to be replaced at regular intervals due to changes in grounding resistance due to corrosion or the like when used for a long time.

In addition, there is a problem that the process for manufacturing the foamed metal 12 is increased to increase the cost, causing an increase in the cost of replacement and grounding of the grounding facility.

An object of the present invention for improving the conventional problems as described above, by sending a conductive fluid to the ground rod at regular intervals to obtain a constant ground resistance irrespective of oxidation of the ground rod, and can be realized while maximizing the ground resistance In addition, it is possible to prevent the damage of equipment caused by abnormal current, to suppress the expense of replacing the plate dish, and to maintain the grounding ability for a time by one-time grounding, The present invention provides a grounding resistance control system of a grounding rod that can prevent the occurrence of oil.

In order to achieve the above object, the present invention provides a fluid chamber in which one or more flow holes through which conductive fluid passes is integrally formed in a ground rod embedded to a predetermined depth of the ground, and connected to the flow hole to store a predetermined amount of conductive fluid. It provides a grounding resistance control system of grounding rods that are connected.
In addition, at least a portion of the configuration is separated from the grounding rod buried to a predetermined depth of the ground is provided to expose to the outside is provided with a separate fluid chamber provided with a viewing window on one side, the grounding rod and the separate fluid chamber is pipe or It provides a grounding resistance control system of the grounding rod made of a configuration connected by a fluid flow means such as a wick.
In addition, one or more flow holes through which the conductive fluid passes through are integrally formed in the ground rod embedded to a predetermined depth of the ground, and the fluid chamber is connected to the flow holes to store a predetermined amount of the conductive fluid; A plurality of ground plates are connected radially around the ground rod, and the ground plate also provides a ground resistance control system of the ground rod in which a sub-flow hole connected to the flow hole is integrally formed.

Here, the flow hole of the present invention is composed of a micro tube so that the end connected to the ground through the capillary phenomenon, the flow hole or the micro tube has a maximum outflow area at the top of the ground rod and a minimum outflow area at the bottom It is provided to have, the conductive fluid of the present invention to have a constant viscosity to provide a ground resistance control system of the grounding rod is installed to form a conductive film in a certain area.

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According to the present invention as described above, by flowing a conductive fluid to the ground rod at regular intervals to obtain a constant ground resistance regardless of the oxidation of the ground rod, and to realize the maximum ground resistance while preventing damage to the equipment by lightning or abnormal current In addition, it is effective in restraining the expenditure caused by the replacement of plate dishes, maintaining the grounding ability on time by one-time ground construction, and preventing accidents caused by non-grounding.

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

Figure 2a, b is a perspective view showing a ground rod according to the present invention, Figure 3 is a cross-sectional view showing a ground rod according to the present invention, Figure 4 is a perspective view showing a ground rod according to another embodiment of the present invention, Figure 5 is a perspective view showing a grounding resistance control system of a grounding rod according to an embodiment of the present invention, Figure 6 is a perspective view showing a grounding rod according to another embodiment of the present invention.

The present invention integrally forms one or more flow balls 110 through which conductive fluid EF passes through a ground rod 100 connected to electrical equipment as a grounding cable 171 while being embedded to a certain depth of the ground E. .

It is made of a configuration in which the fluid chamber 200 is connected to the flow hole 110 is stored a certain amount of the conductive fluid (EF).

In addition, the flow hole 110, the end is connected to the ground (E) is composed of a micro-tube to use the capillary phenomenon.

In addition, the flow hole 110 is installed to have a maximum outflow area at the top of the ground rod 100 and a minimum outflow area at the bottom.

In addition, the conductive fluid (EF) is formed to have a constant viscosity.

On the other hand, as shown in Figure 4, while being installed to move the fluid using a fluid flow means 250, such as a pipe or wick in a configuration that is separated from the ground rod 100, at least part is installed to expose to the outside and one side As a separate fluid chamber 220 having a viewing window 210 may be used.

 In addition, the ground rod 100 is made of a body 150 having a tip 151 and a metal mesh 170 connected to the outside so as to be mounted on the ground through a hammer or the like.

At this time, the body 150 may be made of a porous metal block.

Further, a cover member 175 is further provided to seal the top of the ground rod to cover the top of the fluid chamber 200.

On the other hand, a mounting valve 155a is provided in the mounting hole 155 while the mounting hole 155 is connected to the plurality of ground plates 160 radially around the body 150 to provide the ground plate 160. It is installed to connect to the sub-flow hole (165) of.

At this time, the ground plate 160, the metal mesh 170 may be integrally mounted on the outside of the body or the whole may be made of a porous metal block.

In addition, the ground rod 100, the fluid chamber 200 on the inner diameter side is made of a closed type formed in the space while the tip 151 is fixed to the lower portion through screwing, etc., the cover member for sealing the top ( 175 is provided, it is made of a configuration that the metal mesh 170 is mounted on the outside.

The operation of the present invention having the above configuration will be described.

As shown in FIG. 2 to FIG. 7, the conductive fluid EF flows through the ground E to form the conductive film EM at a predetermined area around the ground rod 100 to maximize the ground resistance. .

At this time, the conductive fluid (EF), the ground rod 100 in a configuration that is supplied by a predetermined amount from the fluid chamber 200 is formed integrally with the ground rod 100 or the separate fluid chamber 220 is installed separately from the ground rod 100 The conductive film EM is integrally formed on the ground located at the periphery.

In addition, the conductive fluid is grounded using the fluid flow means 250 such as a wick using a pipe or capillary phenomenon that flows by gravity when the separate fluid chamber 220 is separated from the ground rod 100. Alternatively, the ground rod 100 may flow from the circumferential position to the ground.

At this time, the separate fluid chamber 220 is separated from the ground rod 100 is at least partially installed to expose the upper portion of the ground through the viewing window 210 is installed to one side of the inside of the separate fluid chamber 220 It is possible to check the state of conductive fluid filling.

In addition, the ground rod 100 is integrally formed with one or more flow holes 110 through which the conductive fluid EF passes, thereby allowing the conductive fluid to flow to the outside of the ground rod 100.

At this time, the flow hole 110, the end connected to the ground (E) is composed of a micro tube to use the capillary phenomenon, even if the fluid chamber 200 is integrally installed on the ground rod 100 has passed a predetermined time While the conductive fluid is released, a constant conductive film EM is always formed.

In addition, the flow hole 110 is installed to have a maximum outflow area at the top of the ground rod 100 to have a minimum outflow area at the bottom to maintain a constant conductive film at all times in a downward configuration as it flows out from the top.

In addition, the conductive fluid (EF) is formed to have a constant viscosity to maintain a constant size of the conductive film at all times to form a constant ground resistance.

On the other hand, the grounding rod 100, the body 150 has a tip 151 so that it can be mounted on the ground through a hammer, etc. and a metal mesh 170 connected to the outside is a state in which the metal mesh is mounted on the body It can be easily mounted on the ground by hitting through a hammer or the like.

At this time, the body 150, it is not necessary to form a separate flow hole when made of a porous metal block.

On the other hand, a mounting valve 155a is provided in the mounting hole 155 while the mounting hole 155 is connected to the plurality of ground plates 160 radially around the body 150 to provide the ground plate 160. It is installed to be connected to the sub-flow hole 165 of the) to have a maximum ground area as the conductive fluid flows.

In addition, the ground rod 100, the fluid chamber 200 on the inner diameter side is made of a sealed type formed in the space while the loss of the coupling portion in the configuration that is fixed to the tip 151 through the screw coupling, etc. in the lower portion. It is to be able to transmit overvoltage to the ground in a minimized state.

1A and 1B are perspective views illustrating a conventional ground rod and a ground plate, respectively.

2A and 2B are perspective views each showing a ground rod according to the present invention.

Figure 3 is a cross-sectional view showing a ground rod according to the present invention.

Figure 4 is a perspective view showing a ground rod according to another embodiment of the present invention.

5 is a perspective view showing a grounding resistance control system of a grounding rod according to another embodiment of the present invention.

Figure 6 is a perspective view showing a ground rod according to another embodiment of the present invention.

Figure 7 is a cross-sectional view showing a ground rod according to another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

100 Grounding rod 110 Flowing hole

151 high-tech 155 mounting holes

160 ... earth 170 ... metal mesh

200 fluid chamber 210 sight glass

Claims (10)

Integrally forming one or more flow holes 110 through which the conductive fluid EF passes through the ground rod 100 that is embedded to a predetermined depth of the ground E; The flow hole 110 is connected to the fluid chamber 200 in which a certain amount of the conductive fluid (EF) is stored is installed so that the conductive fluid can penetrate the ground located around the ground rod through the ground rod; The flow hole 110, the ground resistance control system of the ground rod, characterized in that the end is composed of a micro tube. The grounding resistance control system of claim 1, wherein the fluid chamber (200) is integrally formed inside the grounding rod and the cover member (175) is detachably coupled to the upper sealing member. Integrally forming one or more flow holes 110 through which the conductive fluid EF passes through the ground rod 100 that is embedded to a predetermined depth of the ground E; The flow hole 110 is a configuration in which a certain amount of the conductive fluid (EF) is stored and connected to a separate fluid chamber 220 separated from the ground rod 100, and the conductive fluid is grounded around the ground rod through the ground rod. Installed to penetrate; The flow hole 110, the end is composed of a microtubule; The separate fluid chamber 220 is connected to the ground rod 100 by a fluid flow means 250 such as a pipe or a wick, at least a part of which is installed to be exposed to the upper portion of the ground, and a viewing window 210 is provided on one side thereof. Grounding resistance control system of a grounding rod, characterized in that provided. delete According to claim 1, The flow hole 110, characterized in that the diameter is installed so as to reduce the diameter from the top toward the bottom so as to have a maximum outflow area in the upper portion of the ground rod 100 to the minimum outflow area at the bottom. Grounding resistance control system of ground rod. The grounding resistance control system of claim 1, wherein the conductive fluid (EF) is formed to have a constant viscosity. According to claim 1, The ground rod 100, characterized in that made of a metal mesh 170 connected to the body 150 and the outside having a tip 151 to be mounted on the ground through the hammer Grounding resistance control system of ground rod. The grounding resistance control system of claim 1, wherein the grounding rod (100) is made of a porous metal block. Integrally forming one or more flow holes 110 through which the conductive fluid EF passes through the ground rod 100 that is embedded to a predetermined depth of the ground E; The flow hole 110 is connected to the fluid chamber 200 in which a certain amount of the conductive fluid (EF) is stored is installed so that the conductive fluid can penetrate the ground located around the ground rod through the ground rod; The flow hole 110, the end is composed of a microtubule; The ground rod 100 is provided with a mounting hole 155 to which the plurality of ground plates 160 are connected radially around the body 150, and is provided with a flow valve 155a in the mounting hole 155. Grounding resistance control system of the grounding rod, characterized in that installed to be connected to the sub-flow hole 165 of the plate (160). 10. The grounding resistance control system of claim 9, wherein the ground plate (160) is integrally mounted with the metal mesh (170) on the outer side of the body or is made of a porous metal block.

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