KR200347880Y1 - To protect caustic apparatus - Google Patents

Abstract

The present invention relates to a corrosion prevention device using a sacrificial anode method to prevent corrosion occurring at the joints of saddle fountains, flanges, valves, etc., which are installed underground or underwater. By using wires instead of wires, the corrosion of corrosion objects is effectively prevented.

The present invention relates to a corrosion prevention apparatus using a sacrificial anode method used to prevent the underground buried or the electrical corrosion of the underwater structure, the connection between the sacrificial anode and the underground buried or underwater structure using an electric wire Silver is connected to various places of underground buried or underwater structures, while sacrificial anodes are used to prevent corrosion by using a positive electrode containing magnesium, aluminum, and zinc to ensure a good flow of corrosion current.

Description

Anti-corrosion device {To protect caustic apparatus}

The present invention relates to a corrosion prevention device using a sacrificial anode method to prevent corrosion occurring at the joints of saddle fountains, flanges, valves, etc., which are buried underground or installed underwater. By using wires instead of wires, the corrosion of corrosion objects is effectively prevented.

Buried structures such as saddle fountains, flanges, valves, etc., which are buried underground or underwater, are made of metal so that corrosion progresses over time. This is because the electrical resistance of the buried structures is smaller than that of soil or water. This is a phenomenon caused by the current flowing from the, in particular, the corrosion is concentrated in the bolt portion which is the binding medium.

Corrosion is when metals are placed in an electrolyte such as water or soil, due to differences in ambient conditions such as dissolved oxygen, concentration differences, and temperature differences on the surface and due to metal-side causes such as impurities, residual stresses, and surface deposits contained in the metal itself. The potential difference is generated locally on the surface, and as a result, a large number of anode parts and cathode parts are formed. At this time, a current (corrosion current) flows from the anode part to the cathode part. In this process, the metal part of the anode part is eluted gradually. It is the phenomenon of dissolving into electrolyte.

Corrosion prevention methods of underground buried or underwater structures to prevent the corrosion, there is a coating method and an electric method, the coating method forms a coating layer to prevent corrosion, but in reality the complete form of the coating is not an electrical method You will also use the method.

Cathode method is electrically coupled to Fe and Cu to form a corrosion cell, so that the low-potential Fe becomes the anode and the high-potential Cu becomes the cathode, so that the corrosion current flows from the anode to the cathode through the electrolyte (soil or water). Therefore, in Fe, corrosion occurs by an anodic reaction, and in the Cu (Fe → Fe ²⁺ + 2e ⁻ ) cathode, a reduction reaction proceeds.

^{O 2 + 4H + + 4e -} → 2H 2 O

2H ^{+ +} 2e ^- → H ₂

^{M P + + qe - → M} (Pq) -

The corrosion rate of Fe is equal to the amount of corrosion current, and if the cathode is sufficiently catholy applied by applying a voltage larger than the former position between Fe and Cu from the outside, the current flow is changed and the inflow of Fe flows. In this case, the magnitude of the potential to be applied from the outside should be enough to reverse the flow direction of the current, and the cathode method described above is divided into sacrificial anode method and external power method according to the method of applying the method current. Can be.

A sacrificial anode is a method of relatively cathodic object by electrically connecting a metal having a larger ionization tendency than the metal to be acted in the electrolyte to act as an anode, and an external power supply method is a direct current power supply (rectifier). The negative current of) is connected to the anticorrosive object, the positive electrode is connected to the positive electrode, and a voltage is applied to obtain the anticorrosive current.

Apparatus for preventing corrosion of the saddle fountain before being buried underground using the sacrificial anode method is registered by the present applicant as Utility Model Registration No. 0263742, and the pre-registered utility model is fixed for close contact with the cap of the saddle fountain Insert the bracket but the fixing tool is easy to attach and detach, and the fixing tool is fixed to the sacrificial anode to be fixed, but the sacrificial anode is made of a metal having a greater ionization tendency than the saddle fountain, but the sacrificial anode is Because it is directly coupled to the saddle fountain, there is a limit to preventing corrosion. Particularly, the sacrificial anode is attached to one side of the fixing bracket, so that some corrosion occurs because it is disadvantageous to relatively cathodic object.

The present invention relates to a corrosion prevention device using a sacrificial anode method used to prevent the electrical corrosion of underground buried or underwater structures, and to connect between the sacrificial anode and the underground buried structure using a wire, the wire is underground buried or While sacrificial anodes are connected to various locations in aquatic structures, the sacrificial anodes are made of anodes containing magnesium, aluminum and zinc to prevent corrosion by allowing the current to flow well.

The present invention is connected between the underground buried or underwater structure and the sacrificial anode using a plurality of wires, the wire is connected to various places of the underground buried or underwater structure to effectively prevent corrosion.

1 is a perspective view of the existing saddle fountain

Figure 2 is a cross-sectional view of the present invention applied to the saddle fountain

3 is a front view of an existing valve

4 is a cross-sectional view of a state in which the present invention is applied to a valve

5 is a cross-sectional view of a state in which the present invention is applied to a flange

6 is a cross-sectional view of an embodiment of the present invention applied to the flange

7 is a front view of a conventional butterfly valve

8 is a cross-sectional view of the present invention installed in the butterfly valve

9 is a cross-sectional view of the anode of the present invention

[Explanation of symbols on the main parts of the drawings]

10: Saddle Fountain 20: Sacrificial Anode

21: wire 22,23: coupling terminal

30: valve 40: flange

50: butterfly valve 60: anode

The present invention relates to a device for preventing the electrical corrosion of underground buried or underwater structures buried under the saddle fountain 10, valve 30, flange 40, butterfly valve 50, underground buried structure The wire 21 is coupled to the bolt for coupling the other side, the other side of the wire 21 is made by connecting the regenerative anode 20 and then buried at a distance from the underground buried underground or underwater structures You lose.

Here, the wire 21 is used to smoothly flow the current in several places using several, and the sacrificial anode 20 is composed of the anode 60 containing magnesium, aluminum, zinc so that the flow of corrosion current is fast. To prevent corrosion.

The sacrificial anode 20 is made of a metal having a greater ionization tendency than the underground buried structure, and the regenerative anode 20 is composed of a cathode 60 including magnesium, aluminum, and zinc, but including magnesium, aluminum, and zinc. The anode 60 is formed by filling a chemical 61 such as gypsum, bentonite, and sodium sulfate around the sacrificial anode 20.

The wire 21 is fixed to the coupling terminals 22 and 23 on both sides, and then fixing the coupling terminal 23 to the sacrificial anode 20 with a bolt or saddle fountain 10, valve 30, flange (40) and the buried structure such as the butterfly valve (50) to the bolt (11) (31) (41) (51) to be coupled to the bolt (11) after the bolt 11 is screwed in the bolt 11 and tightened Fix using a bolt (25).

In the case of the flange 40, the wire 42 is fixed to the outside of the flange 40, and then the wire 21 connected to the regenerative anode 20 is connected to the wire 42.

The reason why the electric wire 21 connected to the sacrificial anode 20 is connected to the bolts 11, 31, 41 and 51 is that the structures other than the bolts 11, 31, 41 and 51 are covered by the coating. Since the corrosion is prevented, since the corrosion proceeds in the bolts 11, 31, 41 and 51, the corrosion current of the bolts 11, 31, 41 and 51 is eliminated.

The anode 60 including magnesium, aluminum, and zinc has a sacrificial anode 20 embedded therein and is filled with a chemical agent 61 composed of 75% gypsum, bentonite 20%, and sodium sulfate 5%. It has a and can be used even in a high specific resistance environment.

In this invention, a method of coupling the saddle fountain 10 to the water pipe 1, a method of connecting the branch pipes by opening the cap 12 of the saddle fountain 10, and the water pipe 1 using the flange 40 ), A method of installing the valve 30 and the butterfly valve 50 in the water pipe (1) is a known fact, so a description thereof will be omitted.

That is, the underground buried or underwater structures such as the saddle fountain 10, the valve 30, the flange 40, the butterfly valve 50, the structure and installation method are known, so the underground buried or underwater structure The description of the installation method and the like will be omitted and only the corrosion preventing apparatus of the present invention will be described.

Corrosion preventing device of the present invention is made of a sacrificial anode 20 and several wires 21 connected to the sacrificial anode 20, the both ends of the wire 21, the coupling terminal 22 to reduce the contact resistance (23) is installed so that the coupling using the coupling terminals 22 and 23 is made.

First, a case in which the saddle fountain 10 is installed will be described with reference to FIG. 2.

When the sacrificial anodes 20 are connected when the saddle fountain 10 is assembled, the coupling terminals 22 of the electric wires 21 are fitted by fixing the bolts 11 used to connect the saddle fountain 10. After the other side of the wire 21 is coupled to the sacrificial anode 20, the screw hole is formed in the tip end of the bolt 11 when connecting the sacrificial anode 20 after the coupling of the saddle fountain 10 is completed Then, the coupling terminal 22 may be fixed to the screw hole by the tightening bolt 25.

In addition, the valve seat 13 of the saddle fountain 10 is coupled to the wire 21 by using the fastening bolt 25, the connection of the wire 21 can be connected to several places where corrosion is in progress The connection is appropriate, and the other side of the wire 21 is fixed by using a bolt to the sacrificial anode 20, the connection is completed.

Since the saddle fountain 10 is buried underground, the sacrificial anode 20 must be connected before being buried underground, and the sacrificial anode 20 is spaced apart from the saddle fountain 10 by a predetermined distance (about 30 cm). It should be installed only to minimize the effect of corrosion current.

Next, in the case of installing the sacrificial anode 20 in the valve 30, as shown in FIGS. 3 and 4, the sacrificial anode 20 is connected to the sacrificial anode 20 using the bolt 31 used to assemble the valve 30. In this case, the wires 21 are connected to the wires 21, and the wires 21 are connected to the bolts 31 in which corrosion occurs first, thereby preventing corrosion with the regenerative anode 20, and the wires 21. After forming the screw hole in the silver bolt 31, it may be fixed to the screw hole using the fastening bolt 25.

When the sacrificial anode 20 is installed in the flange 40, the coupling terminal 22 of the electric wire 21 is connected to the bolt 41 to which the flange 40 is coupled as shown in FIGS. 5 and 6. 6 to be connected to the sacrificial anode 20, and the flange 40 is welded to the flange 40 along the outside of the flange 40 so as not to be disturbed by the bolt hole, as shown in FIG. 6. The electric wire 21 of the sacrificial anode 20 may be connected to the electric wire 42.

At this time, the wire 21 fixed to the flange 40 is fixed as close as possible to the bolt hole so that the corrosion current flowing through the bolt 41 flows quickly through the wires 42 and 21 to the sacrificial anode 20 to prevent corrosion. Do not occur.

In addition, when the sacrificial anode 20 is connected to the butterfly valve 50, the coupling terminal 22 of the electric wire 21 may be inserted into and fixed to the bolt 51 as illustrated in FIGS. 7 and 8.

In this case, the wires 21 must be connected to the sacrificial anodes 20 using several to effectively prevent corrosion.

As such, the present invention separates the sacrificial anode 20 from the underground buried or the underwater structure and then embeds the wire between the underground buried structure and the sacrificial anode 20 by several wires 21, but the wire 21 is underground. Corrosion can be effectively prevented by allowing connection to various locations in the buried structure.

That is, when the sacrificial anode 20 is directly connected to the underground buried or underwater structure as in the conventional art, the corrosion current flows quickly toward the sacrificial anode 20 only at the portion where the sacrificial anode 20 is connected, and is far from the sacrificial anode 20. In this case, the flow of the corrosion current is delayed or prevented from flowing to the sacrificial anode 20, so that the corrosion progresses from the far side from the sacrificial anode 20.

And since the underground buried structure is usually prevented by the coating, the corrosion is often progressed in the bolt, but when the sacrificial anode 20 is directly connected to the underground buried structure as in the past, effectively removes the corrosion current flowing through the bolt Since the corrosion proceeds because it is not known, in the present invention is to prevent the corrosion by connecting the sacrificial anode 20 to the wire 21 to concentrate the bolt in the corrosion proceeds.

As such, when the sacrificial anode 20 is separated from the underground buried structure and buried, and the sacrificial anode 20 is connected to the bolt in which corrosion proceeds using the wire 21, the sacrificial anode 20 is buried in the underground buried or underwater structure. It has been confirmed that corrosion is significantly prevented than when directly connected.

Meanwhile, the sacrificial anode 20 of the present invention can be used as the anode 60 containing magnesium, aluminum, and zinc, and the anode 60 containing magnesium, aluminum, and zinc has a sacrificial anode 20 embedded therein. It is made up of a chemical agent 61 composed of 75% gypsum, 20% bentonite, and 5% sodium sulfate, and has a high operating potential and can be effectively used even in a high resistivity environment, which is effective for preventing corrosion.

The sacrificial anode 20 according to the present invention is composed of two types of zinc alloy die castings (ZDC2) or zinc purity of 95% or more, and also includes magnesium and aluminum, as defined in JIS H 5301. Is higher than the sacrificial electrode 20 and lower than bronze brass, the sacrificial anode 20 has a greater tendency to ionize than the underground buried structure, and thus acts as an anode in the soil, so it flows out of the underground buried structure to the soil. Corrosion current is consumed in the sacrificial anode 20, the anticorrosive object is relatively negative to prevent corrosion.

The present invention connects sacrificial anodes with high ionization tendency to underground structures or structures installed in water so that they act as anodes in the soil or water. In preventing the corrosion of underwater structures, install sacrificial anodes at a distance from the underground or underwater structures, but connect the sacrificial anodes and the underground buried or bolts of the underwater structures with wires so that the corrosion current flows quickly. To effectively prevent corrosion.

Claims (3)

In preventing the corrosion by connecting the sacrificial anode 20 to the underground buried structure, such as saddle fountain 10, valve 30, flange 40, butterfly valve 50, The coupling terminal 22 coupled to the distal end of the wire 21 is fixed to several bolts used for coupling the underground buried or underwater structure, and the sacrificial anode 20 is connected to the other end of the wire 21. But the sacrificial anode 20 is a corrosion prevention device, characterized in that buried at a distance from the underground or underground structures. The method according to claim 1, wherein after forming a screw hole in the bolt of the underground buried or underwater structure, the fastening bolt 25 is driven into the screw hole, and the coupling terminal 22 is fixed to the fastening bolt 25. Corrosion prevention device. The positive electrode 60 of claim 1, wherein the sacrificial anode 20 includes magnesium, aluminum, and zinc filled with a chemical agent 61 made of 75% gypsum, bentonite 20%, and sodium sulfate 5%. Corrosion preventing device, characterized in that connected to the wire (21).