KR101026870B1 - Deep anode install structure for electric prevention of corrosion using cylindrial plumb - Google Patents

Abstract

The present invention relates to an electric core core anode installation structure using a cylindrical cone, the cylindrical tube (10); A casing 20; A vent pipe 30; A support tube 30 'installed in the longitudinal direction in the cylindrical tube 10; A lead wire 40 arranged along the support pipe 30 '; A plurality of anodes 50 disposed below the lead wires 40; A sorter box (60) connected to the cylindrical tube (10) and the lead wire (40) drawn out of the casing (20); A cathode ray 70 which is drawn out of the classifier box 60 and connected to the object to be protected through a rectifier; Graphite filler (80) filled around the anode (50) in the cylindrical tube (10); A cylindrical cone (90) positioned above the graphite filler (80); A rope 93 connected to the cylindrical cone 90; Consists of a lid 90 'which is covered on the ground end of the cylindrical tube 10, it is possible to quantitatively easily check the consumption of the graphite filler from the position of the cylindrical cone installed on the graphite filler quantitatively and to manage it afterwards. The refilling of graphite filler prevents the reduction of the output power of the anode, which not only maintains the efficiency of the anti-corrosion efficiency for a long time with a constant high efficiency, but also reduces the cost and maintenance costs associated with the installation of the anode anode structure. Invention.

Electric method, heart anode, external power method, graphite filler, cylindrical cone.

Description

Deep anode install structure for electric prevention of corrosion using cylindrial plumb}

The present invention relates to an electrical method for mounting a core anode, and more particularly, it is possible to refill graphite while quantitatively confirming the degree of consumption of graphite fillers filled around the anode for corrosion prevention, which is installed underground. The present invention relates to an electromechanical core anode installation structure using a cylindrical cone that can maintain the anticorrosion efficiency by maintaining a high efficiency for a long time with a constant high efficiency.

In general, corrosion means that metal (material) reacts with the surrounding environment and the metal itself is deteriorated or the properties of the metal are deteriorated. Such corrosion is mostly an electrochemical reaction (ie, a chemical reaction involving electron movement). ) Is generated when four elements, an anode, a cathode, a current path (metal path), and an ion path (electrolyte) are satisfied.

The combination consisting of the above four elements is called a corrosion cell, and when a corrosion cell is formed, the more active and lower potential metal of the two metals is anodized to corrode. The current flows along the cathode → current path → anode → ion path of the corroded cell, and according to the flow of this current, an anodic reaction (oxidation reaction) and a cathode reaction (reduction reaction) occur. Corrosion occurs at the anode.

On the other hand, the corrosion of metal structures is caused by the anodic reaction and the cathodic reaction by the corrosion mechanism in the presence of electrolytes such as soil or seawater. Inhibiting the progress of the reaction or separating the positive and negative parts in a third way is the basic method of preventing corrosion.

Since the first and the third methods cannot be the perfect methods in reality, the second method, the method of suppressing the progress of the anode reaction, is the most widely used and is called the cathodic protection method. Corrosion of the metal structure is a phenomenon that occurs when the current flows out of the metal surface through the electrolyte, so the principle of the electrochemical method is on the contrary, a direct current (corrosive current) flows into the metal surface through the electrolyte and the outflow current of the metal surface (corrosion). By dissipating the current) to prevent corrosion.

The electric method is largely divided into two types, the sacrificial anode method and the external power supply method, depending on the method of supplying the method current. Electrically connecting metals with a lower potential than the anticorrosive object (eg, aluminum, zinc, magnesium, etc.) in the electrolyte causes the metal with a lower potential to become an anode and the anticorrosive object becomes a cathode so that the anticorrosive current from the anode It is made to flow to an anode through an electrolyte. In general, the external power method uses a rectifier capable of installing an insoluble anode and outputs a direct current power source, connecting the cathode of the rectifier to the anticorrosive object, and connecting the anode of the rectifier to the insoluble anode. It is a method to prevent corrosion by cathodic object discharged from the anode to the soil and back to the anticorrosive object from the soil.

The most commonly used method of the external power method of the above-described electrical method is a method of outputting the anticorrosive current by using a core positive electrode as shown in FIG. In other words, the asymmetric anode method is a method for drilling a hole having a depth of about 40m to 60m in the soil and installing the anode from about 15m below the depth, which is a casing covering the upper outer periphery of the cylindrical tube 1 as shown in FIG. (2) and the vent tube 3 and the support tube 3 'are installed in the longitudinal direction inside the cylindrical tube 1, and the lead wire 4 is arranged along the support tube 3'. A plurality of anodes 5 are installed at the lower part, and the sorter box 6 is connected to the lead wire 4 drawn out of the cylindrical tube 1, and the drawer box 6 is drawn out through the rectifier. The cathode ray 7 is connected to an object to be subjected to corrosion such as a metal structure, and the graphite filler 8 is filled around the anode 5 inside the cylindrical tube 1, and the gravel layer 9 is placed on the graphite filler 8. The filling is made of a structure in which the ground end of the cylindrical tube 1 is covered with a lid 9 '.

The graphite filler 8 filled around the anode 4 is here used to reduce the ground resistance around the anode 4.

However, in the conventional cardiac anode method, when the current generated from the anode flows into the soil for the electric method, the graphite filler 8 is gradually lost, and when the graphite filler 8 is lost, the grounding resistance is increased. There arises a problem that the amount of output current output from (5) becomes small.

As a result, an additional graphite filler 8 needs to be added. Since the gravel layer 9 is filled on the graphite filler 8, the gravel layer 9 cannot be removed, and thus, the additional graphite filler 8 cannot be added. There was a flaw.

In addition, when the gravel layer 9 is lowered to the anode area as the graphite filler 8 gradually disappears, the periphery of the anode 5 is filled with the gravel layer 9 to increase the output resistance of the anode 5, thereby reducing the anticorrosive efficiency or There was a problem that can not be done.

In addition, in the normal case, the weight of the gravel layer 9 filled in the upper 15m is about 300kg to 600kg, and this weight acts on the anode 5 so that the anode 5 is separated from the lead wire 4 so that it does not function. There was also concern.

The present invention has been made to solve various defects and problems caused by the conventional electrocardioid anode structure in view of the above situation, the object of which is the consumption of graphite fillers filled around the anode in the cylindrical casing It is to provide an electric heart-shaped anode installation structure using a cylindrical cone that can be easily confirmed after the management.

Another object of the present invention is to refill the graphite consumed in the electrocardiographic anode structure to prevent the reduction of the output current amount of the anode, so using a cylindrical cone that can maintain the anticorrosive efficiency at a constant high efficiency for a long time stable It is to provide an electric cored anode installation structure.

Another object of the present invention is to refill the graphite consumed in the electrolytic core anode structure can reduce the cost of reconstruction of the core anode structure, it is possible to quantitatively determine the degree of consumption of the graphite filler maintenance It is to provide an electric heart-shaped anode installation structure using a cylindrical cone with excellent economic efficiency by simplifying and simplifying the maintenance and reducing maintenance costs.

The electric core core anode installation structure using the cylindrical cylinder of the present invention for achieving the above object is a pipe-type cylindrical tube buried underground; A casing covering an upper outer circumference of the cylindrical tube; A vent pipe installed in the longitudinal direction in the cylindrical pipe and having an upper end drawn out of the cylindrical pipe on the ground; A support tube installed in the longitudinal direction in the cylindrical tube; A lead wire arranged along the support tube; A plurality of anodes provided below the lead wires; A sorter box connected to the cylindrical tube and a lead wire drawn out of the casing; A cathode ray which is drawn out of the classifier box and connected to the object to be subjected through the rectifier; Graphite fillers filled around the anode inside the cylindrical tube; A cylindrical cone positioned on the graphite filler; A rope 93 connected to the cylindrical cone 90; It is characterized by consisting of a lid which is covered on the ground end of the cylindrical tube.

The present invention does not fill the top of the graphite filler filled around the anode in the cylindrical casing, but instead installs a cylindrical cone instead of the graphite filler with the consumption of the graphite filler, thereby lowering the cylinder in the casing, thereby reducing the graphite from the position of the cone. It is possible to easily check the degree of consumption of the filler and to manage it afterwards, and it is possible to refill the consumed graphite to prevent the decrease of the output current amount of the anode. It is possible to reduce the cost of re-installation, it is possible to quantitatively determine the degree of consumption of the graphite filler has a special advantage of excellent economic efficiency by reducing the maintenance cost while simplifying and easy maintenance.

Hereinafter, the present invention will be described in detail with the core-type positive electrode installation structure for the electric method using the present invention cylindrical cone as an embodiment.

Figure 2 is a view showing an electric core core anode installation structure using a cylindrical cone of the present invention, Figure 3a is a view showing the locking structure of the handle according to an embodiment of the present invention, Figure 3b is an embodiment of the present invention Figure 3c is a view showing the locking structure of the handle, Figure 3c is a view showing the locking structure of the handle according to an embodiment of the present invention, the electric core core installation structure for the electric method using the present invention is a pipe-type buried underground A cylindrical tube 10; A casing 20 covering an upper outer circumference of the cylindrical tube 10; Vent pipe 30 is installed in the longitudinal direction inside the cylindrical tube 10 and the upper end is drawn out of the cylindrical tube 10 on the ground; A support tube 30 'installed in the longitudinal direction in the cylindrical tube 10; A lead wire 40 arranged along the support pipe 30 '; A plurality of anodes 50 disposed below the lead wires 40; A sorter box (60) connected to the cylindrical tube (10) and the lead wire (40) drawn out of the casing (20); A cathode ray 70 which is drawn out of the classifier box 60 and connected to the object to be protected through a rectifier; Graphite filler (80) filled around the anode (50) in the cylindrical tube (10); A cylindrical cone (90) positioned above the graphite filler (80); The lid 90 'is covered with the ground end of the cylindrical tube 10. As shown in FIG.

As shown in FIG. 3A, the cylindrical tube 10 has a top end cut downward, and a handle locking groove 11 is formed. The cylindrical cone 90 has a vent tube 30 and a support tube 30 at a central portion thereof. ') And a lead having a through hole through which the lead wire 40 passes. A ring 91 is provided in front, back, left, and right of an upper surface, and a rope 93 is attached to a wire 92 connected to the ring 91. One end of the) is connected, the handle 94 is fixed to the other end of the rope (93).

Here, instead of the handle locking groove 11, the handle 94 can be caught in various configurations. For example, as shown in FIG. 3B, the bar intersects the inner surface of the upper end side of the cylindrical tube 10 and the center of intersection of the bars. The rope 93 may be formed to form a hole in the hole so that the rope 93 passes through the hole, and as shown in FIG. 94).

In addition, the tip of the wire 92 may be inserted into the cylindrical cone 90 to be integrally molded by insert injection molding when the cylindrical cone 90 is formed without the ring 91.

Next will be described in detail the operation of the electrostatic core anode installation structure using the present invention configured as a cylindrical cone as described above.

In the present invention, the cylindrical cone 90 is mounted on the graphite filler 80 filled around the anode 50 in the cylindrical tube 10, and the handle 94 is attached to the handle locking groove 11 of the cylindrical tube 10. Hanged up. Then, as the graphite filler 80 is consumed, the cylindrical cone 90 is lowered.

The lowering of the cylindrical cone 90 is lowered to the required depth according to the length of the rope 93 set by the manager, when the manager pulls the handle 94 to make the rope 93 taut. By comparing the handle position at the beginning of construction and the current handle position, the lowering position of the cylindrical cone 90 can be confirmed, and the degree of consumption of the graphite filler 80 can be accurately and quantitatively confirmed.

Accordingly, when the consumption of the graphite filler 80 is enough to be refilled (when the cylinder 90 is lowered), the graphite filler 80 is refilled, and the cylinder 90 is again placed on the graphite filler 80. It is located.

This refilling of the graphite filler 80 can easily prevent the reduction of the output current of the positive electrode 50 due to the increase in the ground resistance caused by the consumption of the graphite filler 80.

While the present invention has been described as a preferred embodiment, the present invention is not limited thereto, and various modifications can be made without departing from the gist of the invention.

1 is a view showing a conventional structure for installing a seam anode for a conventional electric method,

Figure 2 is a view showing an electric core core anode installation structure using a cylindrical cone of the present invention,

Figure 3a is a view showing a locking structure of the handle according to an embodiment of the present invention,

Figure 3b is a view showing the locking structure of the handle according to an embodiment of the present invention,

Figure 3c is a view showing the locking structure of the handle according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

10: cylinder tube 11: handle locking groove

20 casing 30 vent tube

30 ': support tube 40: lead wire

50: Anode 60: Sorter Box

70 cathode ray 80 graphite filler

90: cylindrical cone 90 ': lid

91: ring 92: wire

93: rope 94: the handle

Claims (6)

A pipe-type cylindrical tube 10 buried underground; A casing 20 covering an upper outer circumference of the cylindrical tube 10; Vent pipe 30 is installed in the longitudinal direction inside the cylindrical tube 10 and the upper end is drawn out of the cylindrical tube 10 on the ground; A support tube 30 'installed in the longitudinal direction in the cylindrical tube 10; A lead wire 40 arranged along the support pipe 30 '; A plurality of anodes 50 disposed below the lead wires 40; A sorter box (60) connected to the cylindrical tube (10) and the lead wire (40) drawn out of the casing (20); A cathode ray 70 which is drawn out of the classifier box 60 and connected to the object to be protected through a rectifier; Graphite filler (80) filled around the anode (50) in the cylindrical tube (10); A cylindrical cone (90) positioned above the graphite filler (80); A rope 93 connected to the cylindrical cone 90; Electrocardial core anode installation structure using a cylindrical cone, characterized in that consisting of a lid (90 ') is covered on the ground end of the cylindrical tube (10). The method of claim 1, wherein the cylindrical tube 10, the upper end is inclined downwardly to form a handle locking groove (11) for the electric method for installing a core positive anode using a cylindrical cone. The method of claim 2, characterized in that the bar is placed on the inner surface of the upper end side instead of the handle engaging groove 11, and a hole is formed in the center of the intersection of the bars so that the rope 93 passes through the hole. Electro-core core anode installation structure using cylindrical cone. 3. The cylindrical cone according to claim 2, wherein the rope (93) passes through the lid (90 ') so that the handle (94) is caught by the lid (90') instead of the handle catching groove (11). Electro-core core anode installation structure used. According to claim 1, wherein the cylindrical weight 90 is a cylindrical weight having a through-hole through which the vent pipe 30, the support pipe 30 'and the lead wire 40 penetrates in the center, the front and rear of the upper surface Ring 91 is installed on the left and right, one end of the rope 93 is connected to the wire 92 connected to the ring 91, the other end of the rope 93, the handle 94 is connected and fixed An electrocardiographic anode installation structure using a cylindrical cone, characterized in that there is. 6. The cylindrical cone according to claim 5, wherein the tip of the wire (92) is inserted into the cylindrical cone (90) and integrally molded by insert injection molding when the cylindrical cone (90) is formed without the ring (91). Electrocardial core anode installation structure using.

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