KR20200073660A - Apparatus and method for preventing corrosion of metal frame - Google Patents

Abstract

The present invention provides an apparatus and a method for preventing corrosion of an iron frame, capable of effectively protecting an iron frame from corrosion by using a difference in ionization of metals. The apparatus for preventing corrosion of the iron frame according to the present invention is an apparatus for preventing corrosion of the iron frame by being coupled to the iron frame to which a plurality of iron bars are welded to prevent corrosion of the iron frame, which includes: a sacrificial anode material made of a low-potential metal and having a higher ionization tendency than iron constituting the iron frame; and a fixing mechanism coupled to the sacrificial anode material so that the fixing mechanism can be detachably attached to the iron frame.

Description

Anti-corrosion device and method of iron frame{APPARATUS AND METHOD FOR PREVENTING CORROSION OF METAL FRAME}

The present invention relates to an anticorrosion technology for an iron frame, and more particularly, to an anticorrosion device and method for an iron frame that can be used for various equipment to prevent corrosion of an iron frame forming a skeleton of various equipment.

In general, corrosion of metal refers to the destruction of metal and shortening of the useful life of the metal caused by chemical or electrochemical reactions with various substances in the surrounding environment.

Most metals are more stable in ionic form than in the metal itself. Therefore, the metal tends to ionize if the conditions are met, and in this regard, corrosion can be referred to as the ionization tendency of the metal.

All metals will corrode. Corrosion-resistant metals such as platinum, gold, silver, copper, and stainless steel may be considered to be non-corrosive metals, but in fact, they block the progress of corrosion by preventing the coating from being dense and allowing air or water to pass through.

Since the natural form of the metal is a compound, and the nature of the refined metal to return to the ore and the tendency to ionize is the cause of corrosion, the metal material is in the most stable state in the environment even if it is used in an industrially available state. It has the property of going back. For example, it can be said that the result of taking the most stable state in an environment in which iron melted water and air is present.

The principle of metal corrosion is determined by the elution of metal ions, and the degree of ease of metal elution depends on how easy it is to become ions in the environment in which the metal is placed. Metals with a high ionization tendency, such as aluminum, emit many electrons at the same time, so the standard electrode potential is lowered to a negative value based on hydrogen ions (H+), and classified as low. Metals with a low ionization tendency, such as platinum, also have electron emission As it decreases, the standard electrode potential is classified as a precious metal with a high positive value.

In order for corrosion to occur, four elements must be provided: the anode, the cathode, the electrolyte, and the return circuit. The anode is a part where electrons come out, and is a part that is corroded because oxidation reaction occurs chemically. The negative electrode absorbs electrons from the positive electrode and does not corrode because it is a reduction reaction. That is, corrosion occurs where the current leaves the metal of the anode and enters the electrolyte, and since the current leaving the anode flows to the cathode and is consumed, corrosion does not occur in the metal acting as the cathode.

Currently, not only the visual aesthetics due to corrosion of metal materials at various industrial sites, construction sites, and living sites, but also its original function has been lost, and a large amount of money has been put into recovery. Particularly, in the industrial fields such as the semiconductor and display equipment industries, astronomical costs for corrosion prevention are being used.

As a method for preventing corrosion of general metal structures or electronic products, surface treatment methods such as painting or plating are mainly used. However, such a surface treatment method has a disadvantage that it takes a lot of additional cost and the corrosion prevention period is limited.

In addition, in the case of a method of preventing rust by applying antirust oil to the surface of the intermediate molded article of iron, there is a problem that more processes and costs are required according to the removal of antirust oil after manufacture of the finished product. And the method of plating metals such as zinc is less economical.

Meanwhile, when rust occurs in the iron product during the production of the iron product, a sandblast post-treatment process is added to remove the rust. This post-treatment process leads to delays in production periods and increased costs. In addition, due to the strong sand blast used for removing rust, the appearance change of the iron product may occur, and fine particles according to the sand blast may penetrate into the iron product and deteriorate the environment in which the iron product is installed.

Therefore, it can be said that the best way to solve problems such as additional cost due to corrosion is to prevent corrosion of iron products in advance.

Registered Patent Publication No.1279836 (2013. 07. 01.)

The present invention has been devised in view of the above-described points, and an object thereof is to provide an apparatus and method for preventing corrosion of an iron frame that can effectively protect the iron frame from corrosion by using a difference in ionization of metal.

Corrosion prevention device of the iron frame according to the present invention for solving the above object, a plurality of iron bars are coupled to a welded iron frame to prevent corrosion of the iron frame, the corrosion protection device of the iron frame, the iron A sacrificial positive electrode material made of a low-potential metal having a greater ionization tendency than iron constituting the frame; And a fixing mechanism coupled to the sacrificial cathode material to be detachably attached to the iron frame.

Corrosion preventing device of the iron frame according to the present invention, the conductive portion coupled to the sacrificial cathode material so as to extend outward from the surface of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame ; May be included.

The sacrificial positive electrode material is made of iron to which the first attachment portion is attached to any one iron bar among a plurality of iron bars constituting the iron frame, and the first attachment portion is attached to a plurality of iron bars constituting the iron frame. And a second attachment portion substantially vertically disposed with respect to the first attachment portion so that its end can be attached to another iron bar substantially vertically disposed with the bar, wherein the fixing mechanism includes an end portion of the first attachment portion and the second attachment portion. Each of the magnets are disposed at the ends of the portion, and the conductive portion is made of two irons, each of which is attached to the first attachment portion and the second attachment portion at a portion of the sacrificial anode material where the first attachment portion and the second attachment portion are connected. It extends toward the corner of the iron frame where the bars intersect, and may be elastically deformed in contact with the iron frame.

Corrosion prevention device of the iron frame according to the present invention, to be elastically deformable to the sacrificial cathode material so as to extend outward from one side of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame A first conductive portion to be combined; And a second conductive part elastically deformablely coupled to the sacrificial cathode material so as to extend outward from the other side of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame; , The first conductive portion and the second conductive portion are disposed to face each other, the minimum gap between the first conductive portion and the second conductive portion is smaller than the thickness of the iron bar so that the fixing mechanism is coupled to the iron bar In this case, the first conductive portion and the second conductive portion may be elastically deformed in contact with both sides of the iron bar.

The fixing mechanism is a magnet made of at least a portion of an arcuate shape so that one of the two iron bars connected to each other among a plurality of iron bars constituting the iron frame is in contact with one side and the other can be joined to the other side. Can.

The apparatus for preventing corrosion of an iron frame according to the present invention, wherein two iron bars contacting the arched magnet from the surface of the sacrificial positive electrode material intersect with the iron frame to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame, It may extend toward the edge of the iron frame, the conductive member is elastically deformable in contact with the iron frame; may include.

On the other hand, a method for preventing corrosion of an iron frame according to the present invention for solving the above-mentioned object is a method for preventing corrosion of an iron frame for preventing corrosion of an iron frame in which a plurality of iron bars are welded, (a) the iron Preparing a plurality of anti-corrosion devices comprising a sacrificial positive electrode material made of a low-potential metal having a greater ionization tendency than iron constituting a frame, and a magnet coupled to the sacrificial positive electrode material to be detachably attached to the iron frame step; And (b) attaching the plurality of anti-corrosion devices to a plurality of locations of the iron frame to be adjacent to a weld portion of the iron frame using respective fixing mechanisms.

In step (a), at least one of the plurality of corrosion preventing devices, the sacrificial cathode material so as to extend outwardly from the surface of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame. It includes a conductive portion coupled to, and in the step (b), a corrosion preventing device including the conductive portion may be attached to the iron frame so that the conductive portion contacts the welding portion.

In step (a), at least one of the plurality of corrosion preventing devices, the sacrificial anode so as to extend outward from one side of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame. Elastic to the sacrificial positive electrode material so as to extend outwardly from the other side of the sacrificial positive electrode material to electrically connect the first conductive portion elastically deformable to the ash and the iron frame and the sacrificial cathode material in contact with the iron frame. The first conductive portion and the second conductive portion include the second conductive portion and the second conductive portion, wherein the first conductive portion and the second conductive portion include a corrosion preventing device including the first conductive portion and the second conductive portion in step (b). It can be attached to the iron frame so as to be elastically deformed in contact with each side of the.

In the step (a), at least one of the plurality of anti-corrosion devices, the fixing mechanism provided therein is an arcuate magnet, and the sacrificial anode to electrically connect the iron frame and the sacrificial cathode material in contact with an iron frame. It includes a conductive portion coupled to the sacrificial anode material so as to extend outwardly from the surface of the ash, and in step (b), the anti-corrosion device having the arcuate magnet is connected to two iron bars that are connected so that the arcuate magnets cross each other. It can be attached to the iron frame so as to make contact with both, and to contact the edge portion to which the two iron bars contacting the arc-shaped magnet are connected.

The corrosion protection device of the iron frame according to the present invention can be easily attached to the iron frame through a fixing mechanism, and a sacrificial anode material made of a metal having a lower potential than iron (Fe) constituting the iron frame comes into contact with the iron frame and the iron frame and The circuit is constructed. Therefore, the electric current is moved by the potential difference between the iron frame and the sacrificial anode material, so that the corrosion current flows in the sacrificial anode material and polarization occurs, and the iron frame, which is the cathode, is depolarized to reduce the corrosion current. Corrosion can be prevented in advance.

In addition, since the corrosion preventing device of the iron frame according to the present invention can be simply coupled to the iron frame through the magnetic force of the magnet, it is easy to attach and detach, and it is easy to adjust the attachment position. In addition, the attachment position on the iron frame can be changed by the user at any time, so that a relatively small number can exhibit corrosion protection for a wider area.

1 is a view showing a corrosion prevention device of an iron frame according to an embodiment of the present invention installed on an iron frame.
Figure 2 shows the corrosion protection device of the iron frame according to an embodiment of the present invention.
Figure 3 shows a state in which the corrosion protection device of the iron frame according to another embodiment of the present invention is installed on the iron frame.
Figure 4 shows the corrosion protection device of the iron frame according to another embodiment of the present invention.
5 and 6 shows a state in which the corrosion protection device of the iron frame shown in FIG. 4 is installed on the iron frame.
7 shows an apparatus for preventing corrosion of an iron frame according to another embodiment of the present invention.
8 and 9 show a state in which the corrosion preventing device of the iron frame shown in FIG. 7 is installed on the iron frame.

Hereinafter, a corrosion prevention apparatus and method of an iron frame according to the present invention will be described in detail with reference to the drawings.

1 shows a corrosion protection device of an iron frame according to an embodiment of the present invention installed on an iron frame, and FIG. 2 shows a corrosion protection device of an iron frame according to an embodiment of the present invention.

As shown in the figure, the corrosion protection device 100 of the iron frame according to an embodiment of the present invention, a plurality of iron bars 12 are coupled to the iron frame 10 welded to the corrosion of the iron frame 10 In order to prevent the sacrificial anode material 110 and a sacrificial cathode material 110, the magnet 120 as a fixing mechanism coupled to the sacrificial cathode material 110 for attaching to the iron frame 10 is included.

The sacrificial anode material 110 is made of a low-potential metal having a greater ionization tendency than iron (Fe) constituting the iron frame 10. For example, the sacrificial anode material 110 may be made of a metal selected from aluminum (Al), zinc (Zn), and magnesium (Mg) having a lower potential than iron (Fe). The sacrificial positive electrode material 110 is flat at least one surface in contact with the iron bar 12 so as to be in close contact with the iron bar 12 of the iron frame 10.

The magnet 120 is coupled to the sacrificial cathode material 110 so that at least a portion is exposed from the surface of the sacrificial cathode material 110 so that it can be detachably attached to the iron frame 10. When attached to the iron frame 10, the magnet 120 does not protrude from the surface of the sacrificial anode material 110 so that the surface of the sacrificial cathode material 110 can stably contact the surface of the iron frame 10. That is, the magnet 120 is embedded in the sacrificial positive electrode material 110 so that its outer surface is disposed substantially on the same plane as the surface of the sacrificial positive electrode material 110, or its outer surface is lower than the surface of the sacrificial positive electrode material 110. Is placed.

The anti-corrosion device 100 can be easily attached to the iron frame 10 through the magnet 120 to prevent the iron frame 10 from being corroded. Specifically, the sacrificial anode material 110 made of a metal having a lower electric potential than iron (Fe) constituting the iron frame 10 contacts the iron frame 10 to form a circuit with the iron frame 10, so that the reactivity is large. The sacrificial anode material 110, which is a metal, reacts before the iron frame 10 made of iron (Fe), which prevents ionization of iron (Fe), that is, an oxidation reaction, so that the iron frame 10 can be protected. do. That is, by making the sacrificial anode material 110, which is a metal having a large ionization tendency, electrically connect to the iron frame 10 to act as an anode, by relatively cathodicizing the object iron frame 10, the iron frame 10 of the iron frame 10 is Corrosion can be prevented.

In the iron frame 10, intensive rust may occur in the welding portion 14 where two iron bars 12 are welded, such as the iron bar 12 and the corner portion 13 to which the iron bars 12 are connected. This is because selective corrosion caused by the influence of heat and galvanic corrosion occur in the welded portion 14 due to changes in microstructure and components.

Therefore, the corrosion preventing device 100 is preferably attached to the iron frame 10 so as to be adjacent to the welding portion 14, as shown in FIG. That is, in order to effectively prevent corrosion of the iron frame 10, the plurality of corrosion preventing devices 100 are first disposed adjacent to the welding portion 14 of the iron frame 10, and the rest are the rest of the iron frame 10 It is recommended that they are spaced apart at appropriate intervals.

As described above, the corrosion protection device 100 of the iron frame according to an embodiment of the present invention can prevent corrosion of the iron frame 10 by simply attaching it to the iron frame 10 through the magnet 120. . That is, the sacrificial anode material 110 made of a metal having a lower potential than iron (Fe) constituting the iron frame 10 contacts the iron frame 10 to form a circuit with the iron frame 10. Therefore, the electric current is moved by the potential difference between the iron frame 10 and the sacrificial anode material 110, and the corrosion occurs in the sacrificial anode material 110, causing polarization, and the iron frame 10, which is the cathode, is a bipolar ( Depolarization) can prevent corrosion of the iron frame 10 of the iron frame 10 in a manner that reduces corrosion current.

Therefore, in the manufacturing process of the iron frame 10, it is possible to prevent a problem of a delay in a production period or an increase in cost caused by performing a post-treatment process such as sand blasting due to corrosion.

In addition, since the corrosion preventing device 100 of the iron frame according to an embodiment of the present invention can be simply coupled to the iron frame 10 through the magnetic force of the magnet 120, it is easy to attach and detach, and the attachment position can be adjusted. It is easy. And the attachment position on the iron frame 10 can be changed at any time by the operator, so that the corrosion prevention effect can be exerted on a wider area with a relatively small number compared to the fixed type.

In preventing corrosion of the iron frame 10 by using the corrosion preventing device 100 of the iron frame according to an embodiment of the present invention, rust may easily occur in the welding portion 14 of the iron frame 10, and thus corrosion It is effective to arrange the prevention device 100 so as to be adjacent to the welding portion 14 of the iron frame 10.

On the other hand, Figures 3 to 9 shows various modifications of the corrosion protection device of the iron frame according to the present invention.

First, the corrosion protection device 200 of the iron frame shown in FIG. 3 includes a sacrificial cathode material 210 and a iron frame 10 made of a low-potential metal having a greater ionization tendency than iron (Fe) constituting the iron frame 10. ) A magnet 120 fixed to the sacrificial cathode material 210 so as to be detachably coupled to it, and a conductive portion 220 coupled to the sacrificial cathode material 210 to extend outward from the surface of the sacrificial cathode material 210. ). Here, the magnet 120 is as described above.

The sacrificial anode material 210 is a first attachment portion 212 that is substantially vertically disposed to be attached to different iron bars 12a and 12b, respectively, among a plurality of iron bars 12 constituting the iron frame 10 ) And the second attachment portion 214. A magnet 120 is disposed in each of the first attachment portion 212 and the second attachment portion 214. The first attachment portion 212 may be attached to an iron bar 12a whose ends are substantially perpendicular to the ground among a plurality of iron bars 12 constituting the iron frame 10. In addition, the second attachment portion 214 may be attached to an iron bar 12b that is substantially parallel to the ground among a plurality of iron bars 12 whose ends constitute the iron frame 10.

The conductive portion 220 is in contact with the iron frame 10 when the first attachment portion 212 and the second attachment portion 214 are attached to the iron frame 10 so that the iron frame 10 and the sacrificial anode material 210 ) To connect electrically. The conductive portion 220 may be formed of a material such as the sacrificial anode material 210 or various other conductive materials to form a path through which electrons can move. The conductive portion 220 may have a shape that can be elastically deformed by contacting the iron frame 10 such as a wire shape or a flat plate shape. When the conductive portion 220 is elastically deformed in contact with the iron frame 10, the conductive portion 220 may more stably contact the iron frame 10. In addition, the conductive portion 220 extends in an inclined direction with respect to the first attachment portion 212 and the second attachment portion 214 at the connection portion of the first attachment portion 212 and the second attachment portion 214, respectively. By doing so, it is possible to smoothly contact the edge portion 13 of the iron frame 10.

The anticorrosion device 200 of the iron frame according to the present embodiment can be prevented from being corroded by the iron frame 10 simply by being attached to the iron frame 10 through the magnet 120. The principle of preventing corrosion of the iron frame 10 by the sacrificial anode material 210 is the same as described above.

In particular, the corrosion protection device 200 of the iron frame according to the present embodiment may directly contact the welding portion 14 formed on the edge portion 13 of the iron frame 10 through the conductive portion 220. That is, due to the structure of the sacrificial positive electrode material 210, the sacrificial positive electrode material 210 has difficulty in directly contacting the welding portion 14 formed at the edge portion 13 of the iron frame 10, but the iron according to the present embodiment The anti-corrosion device 200 of the frame may directly contact the welding portion 14 formed on the edge portion 13 of the iron frame 10 by using the conductive portion 220. Therefore, it is possible to more effectively prevent the occurrence of corrosion in the welding portion 14. As shown, when there are welding beads protruding from the surface of the iron frame 10 in the welding portion 14, the conductive portion 220 may directly contact the welding bead. Welding beads may be formed in a variety of sizes, the conductive portion 220 is elastically deformed so that the sacrificial anode material 210 is attached to the iron frame 10 can be in smooth contact with the welding beads of various sizes.

In the method of preventing corrosion of the iron frame 10 using the corrosion preventing device 200 of the iron frame according to the present embodiment, the corrosion preventing device 200 of the iron frame is disposed adjacent to the welding part 14 More effective corrosion protection for the iron frame 10 is possible. In particular, by installing the corrosion protection device 200 of the iron frame to the iron frame 10 so that the conductive portion 220 contacts the welding portion 14, corrosion occurrence in the welding portion 14 can be more effectively prevented.

In the drawing, the sacrificial anode material 210 is shown as having an approximately “a” bent shape, but the shape of the sacrificial anode material 210, the number of magnets 120, and the arrangement structure of the magnets 120 are variously changed. Can be. In addition, the shape, number, and connection position of the sacrificial anode material 210 of the conductive portion 220 may also be variously changed.

Corrosion prevention device 300 of the iron frame shown in Figures 4 to 6 is a sacrificial anode material 310 made of a low-potential metal having a greater ionization tendency than iron (Fe) constituting the iron frame 10, and the iron frame ( 10) a first conductive magnet coupled to the sacrificial cathode material 310 to be detachably coupled to the sacrificial cathode material 310 and the sacrificial cathode material 310 to extend outward from the surface of the sacrificial cathode material 310 It includes a portion 320 and a second conductive portion 325. Here, the magnet 120 is as described above.

The first conductive part 320 and the second conductive part 325 contact the iron frame 10 when the sacrificial anode material 310 is attached to the iron frame 10, thereby making the iron frame 10 and the sacrificial cathode material ( 310) to electrically connect. The first conductive portion 320 and the second conductive portion 325 may be formed of a material such as the sacrificial anode material 310 or various other conductive materials to form a path through which electrons can move.

The first conductive part 320 is elastically deformablely coupled to the sacrificial cathode material 310 so as to extend outward from one side of the sacrificial cathode material 310. The first conductive portion 320 may have a shape that can be elastically deformed in contact with the iron frame 10 such as a wire shape or a flat plate shape.

The second conductive portion 325 is elastically deformablely coupled to the sacrificial cathode material 310 so as to extend outward from the other side of the sacrificial cathode material 310. The second conductive portion 325 may have a shape that can be elastically deformed in contact with the iron frame 10 such as a wire shape or a flat plate shape, like the first conductive portion 320.

The first conductive portion 320 and the second conductive portion 325 are disposed to face each other so that the iron bars 12 of the iron frame 10 can be positioned between them. The minimum gap between the first conductive portion 220 and the second conductive portion 220 is smaller than the thickness of the iron bar 12 of the iron frame 10. Therefore, the first conductive portion 320 and the second conductive portion 325 may be elastically deformed while being in contact with the iron bar 12, when the iron bar 12 is positioned between them. As illustrated, the first conductive portion 320 and the second conductive portion 325 may have a curved shape in a curved shape to stably contact the surface of the iron bar 12.

The anti-corrosion device 300 of the iron frame according to this embodiment can be prevented from being corroded by the iron frame 10 by simply attaching it to the iron frame 10 through the magnet 120. The principle of preventing corrosion of the iron frame 10 by the sacrificial cathode material 310 is the same as described above.

In particular, the corrosion preventing device 300 of the iron frame according to the present embodiment more stably contacts the iron bar 12 of the iron frame 10 through the first conductive portion 320 and the second conductive portion 325. And can be combined. That is, as shown in Figure 5, when the magnet 120 is attached to the iron bar 12, the first conductive portion 320 is elastically deformed while being pressed on one surface of the iron bar 12, the second conductive portion As the 325 is elastically deformed, it is compressed on the other surface of the iron bar 12. Therefore, the corrosion prevention device 300 can be stably attached to the iron bar 12 by the magnetic force of the magnet 120 and the elastic force of the first conductive portion 320 and the second conductive portion 325. In addition, since the first conductive portion 320 and the second conductive portion 325 contact the iron bar 12, the connection area between the sacrificial anode material 310 and the iron bar 12 is increased, thereby preventing corrosion efficiency. It can be further increased.

In the method of preventing corrosion of the iron frame 10 using the corrosion preventing device 300 of the iron frame according to the present embodiment, the corrosion preventing device 300 of the iron frame is disposed adjacent to the welding part 14 More effective corrosion protection for the iron frame 10 is possible. In addition, by using the first conductive portion 320 and the second conductive portion 325, the corrosion preventing device 300 of the iron frame can be stably attached to the iron bars having various cross-sectional shapes to increase corrosion prevention efficiency.

For example, as shown in FIG. 6, the user can use the first conductive portion 320 and the second conductive portion 325 to make the iron frame 20 of the iron frame 20 having a circular cross-section. ). The sacrificial anode material 310 is difficult to stably attach to the iron bar 20 having a circular cross-section shape by only the magnetic force of the magnet 120, but the corrosion preventing device 300 of the iron frame according to the present embodiment is the first conductive part As the 320 is elastically deformed and is in close contact with one side of the iron bar 20, and the second conductive portion 325 is elastically deformed and is in close contact with the other side of the iron bar 20, the iron bar 20 having a circular cross-sectional shape ) Can be stably attached.

In addition, by using the first conductive portion 320 and the second conductive portion 325, the user stably attaches the corrosion prevention device 300 to various iron bars having various other shapes other than square and circular cross-sections. Can be used.

In this embodiment, the shape of the sacrificial cathode material 310 or the number of magnets 120, the arrangement structure of the magnet 120, the shape or number of the conductive parts 320 and 325, the number, on the sacrificial cathode material 310 The connection location is not limited to that shown, and may be variously changed.

The anti-corrosion device 400 of the iron frame shown in FIGS. 7 to 9 includes a sacrificial anode material 410 made of a low-potential metal having a higher ionization tendency than iron (Fe) constituting the iron frame 10, and an iron frame ( 10) a magnet 420 fixed to the sacrificial anode material 410 so as to be detachably coupled to it, and a conductive portion coupled to the sacrificial cathode material 410 so as to extend outward from the surface of the sacrificial cathode material 410 ( 430).

The sacrificial positive electrode material 410 is formed in a cylindrical shape so as to be in contact with both steel bars arranged to cross each other. As shown in FIG. 8, when the sacrificial anode material 410 is disposed close to the edge portion 13 of the iron frame 10, the sacrificial cathode material 410 is two iron bars 12a that are substantially vertically disposed. (12b).

The magnet 420 is coupled to the sacrificial cathode material 410 so that at least a portion is exposed on the surface of the sacrificial cathode material 410 so that it can be detachably attached to the iron frame 10. The magnet 420 is formed in an arcuate shape so that it can be attached to both of the two iron bars 12a and 12b that the sacrificial anode material 410 contacts. When attached to the iron frame 10, the magnet 420 does not protrude from the surface of the sacrificial anode material 410 so that the surface of the sacrificial cathode material 410 can stably contact the surface of the iron frame 10.

The conductive portion 430 serves to electrically connect the iron frame 10 and the sacrificial anode material 410 by contacting the iron frame 10 when the sacrificial anode material 410 is attached to the iron frame 10. . The conductive portion 430 may have a shape that can be elastically deformed by contacting the iron frame 10 such as a wire shape or a flat plate shape.

The anti-corrosion device 400 of the iron frame according to the present embodiment can be prevented from being corroded by the iron frame 10 by simply being attached to the iron frame 10 through a magnet 420. The principle of preventing corrosion of the iron frame 10 by the sacrificial anode material 410 is the same as described above.

In particular, the corrosion preventing device 400 of the iron frame according to the present embodiment is easy to be disposed adjacent to the edge portion 13 of the iron frame 10. That is, as shown in Figure 8, the corrosion protection device 400 is a sacrificial positive electrode material 410 is made of a cylindrical shape, the magnet 420 is made of an arcuate shape, substantially two iron bars arranged vertically ( It may be attached to the iron frame 10 in the form of being sandwiched between the corners 13 between 12a) and 12b. And the conductive portion 430 can stably contact the welding portion 14 formed in the edge portion 13. Since the conductive portion 430 is elastically deformable, the sacrificial anode material 410 can smoothly contact the welding beads of various sizes while being attached to the iron frame 10.

In addition, since the conductive portion 430 is elastically deformable in the corrosion preventing device 400 of the iron frame according to the present embodiment, the sacrificial anode material 410 is attached to the iron frame 10 in the state where the sacrificial cathode material ( Even though the distance between the 410 and the welding portion 14 is different, the conductive portion 430 can stably contact the welding portion 14.

In the method of preventing corrosion by using the corrosion preventing device 400 of the iron frame according to the present embodiment, the corrosion preventing device 400 of the iron frame is disposed adjacent to the welding part 14 to the iron frame 10 For more effective corrosion protection is possible. In particular, by installing the corrosion protection device 400 of the iron frame to the iron frame 10 so that the conductive portion 430 contacts the welding portion 14, corrosion occurrence in the welding portion 14 can be more effectively prevented.

In addition, the user uses the anti-corrosion device 400 of the iron frame according to this embodiment to prevent corrosion of the iron frame, and the anti-corrosion device 400 is disposed at the corners between the iron bars connected at various angles. can do. For example, as shown in FIG. 9, two iron bars 12a and 12c are connected to be inclined, and a welding portion 14 is provided at the edge portion 13 between these two iron bars 12a and 12c. When formed, the user has one iron bar 12a contacting one side of the sacrificial positive electrode material 410 and one side of the magnet 420, and the other iron bar 12c other side of the sacrificial positive electrode material 410 And the corrosion preventing device 400 to be placed between the two iron bars 12a and 12c so as to contact the other side of the magnet 420 to be attached to the iron frame. And by making the conductive portion 430 contact the welding portion 14, it is possible to increase the connection area between the sacrificial anode material 410 and the iron frame 10 and further improve corrosion prevention efficiency.

In this embodiment, the shape of the sacrificial anode material 410, the shape or number of magnets 420, the arrangement structure, the shape or number of the conductive parts 430, the connection location on the sacrificial cathode material 410 is illustrated. It is not limited and can be changed in various ways. For example, the sacrificial anode material may have various other shapes other than a cylindrical shape, and the magnet may not be entirely arcuate, but attached to two iron bars which are at least partially arcuate or disposed to cross each other. So that a plurality of can be coupled to the sacrificial anode material.

The present invention has been described as a preferred example, but the scope of the present invention is not limited to the form described and illustrated above.

For example, in the drawings, a magnet is used as a fixing mechanism coupled to the sacrificial anode material to attach the sacrificial cathode material to the iron frame, but the fixing mechanism is detachable from the iron frame such as bolts, velcro, etc. in addition to the magnet. It can be combined and changed into various other structures that can fix the sacrificial anode while attached to the iron frame.

Above, the present invention has been shown and described in connection with a preferred embodiment for illustrating the principles of the present invention, but the present invention is not limited to the configuration and operation as shown and described. Rather, those skilled in the art will appreciate that many changes and modifications to the present invention are possible without departing from the spirit and scope of the appended claims.

10: iron frame 12, 12a, 12b, 12c: iron bar
13: corner 14: weld
100, 200, 300, 400: Corrosion prevention device for iron frame
110, 210, 310, 410: sacrificial anode material 120, 420: magnet
220, 430: conductive portion 212, 214: first, second attachment portion
320, 325: 1st and 2nd conductive parts

Claims (10)

A plurality of iron bars are coupled to a welded iron frame to prevent corrosion of the iron frame, the corrosion protection device of the iron frame,
A sacrificial anode material made of a low-potential metal having a greater ionization tendency than iron constituting the iron frame; And
And a fixing mechanism coupled to the sacrificial anode material so as to be detachably attached to the iron frame.
According to claim 1,
And a conductive portion coupled to the sacrificial cathode material so as to extend outward from the surface of the sacrificial cathode material to electrically connect the sacrificial cathode material to the iron frame in contact with the iron frame. Prevention device.
According to claim 2,
The sacrificial positive electrode material is made of iron to which the first attachment portion is attached to any one iron bar among a plurality of iron bars constituting the iron frame, and the first attachment portion is attached to a plurality of iron bars constituting the iron frame. A second attachment portion substantially vertically disposed with respect to the first attachment portion so that its end can be attached to another iron bar substantially vertically disposed with the bar,
The fixing mechanism is a magnet disposed at each end of the first attachment portion and the end of the second attachment portion,
The conductive portion, a corner portion of the iron frame where two iron bars to which the first attachment portion and the second attachment portion are respectively attached intersect at a portion where the first attachment portion and the second attachment portion are connected among the sacrificial cathode materials. The anti-corrosion device of the iron frame, which is extended toward, and is elastically deformable in contact with the iron frame.
According to claim 1,
A first conductive part elastically deformablely coupled to the sacrificial cathode material so as to extend outward from one side of the sacrificial cathode material to electrically connect the sacrificial cathode material to the iron frame in contact with the iron frame; And
It includes; a second conductive portion elastically deformablely coupled to the sacrificial cathode material so as to extend outward from the other side of the sacrificial cathode material to electrically connect the sacrificial cathode material to the iron frame in contact with the iron frame;
When the first conductive portion and the second conductive portion are disposed to face each other, when the minimum gap between the first conductive portion and the second conductive portion is smaller than the thickness of the iron bar, the fixing mechanism is coupled to the iron bar The first conductive portion and the second conductive portion are corrosion-resistant devices of the iron frame, characterized in that elastically deformed in contact with both sides of the iron bar.
According to claim 1,
The fixing mechanism is a magnet made of at least a portion of an arcuate shape so that one of two iron bars connected to each other among a plurality of iron bars constituting the iron frame is in contact with one side and the other can be joined to the other side. Corrosion prevention device of the iron frame, characterized in that.
The method of claim 5,
In order to electrically connect the iron frame and the sacrificial positive electrode material in contact with the iron frame, the iron frame extends from a surface of the sacrificial positive electrode material toward an edge portion of the iron frame where two iron bars contacting the arcuate magnet intersect. A conductive frame that can be elastically deformed in contact with the apparatus for preventing corrosion of an iron frame.
A method for preventing corrosion of an iron frame for preventing corrosion of an iron frame in which a plurality of iron bars are welded,
(a) a plurality of corrosion comprising a sacrificial positive electrode material made of a low-potential metal having a greater ionization tendency than iron constituting the iron frame, and a magnet coupled to the sacrificial positive electrode material so as to be detachably attached to the iron frame. Preparing a prevention device; And
(b) attaching the plurality of corrosion preventing devices to a plurality of places of the iron frame so as to be adjacent to the welding portion of the iron frame using respective fixing mechanisms; .
The method of claim 7,
In step (a), at least one of the plurality of corrosion preventing devices, the sacrificial cathode material so as to extend outwardly from the surface of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame. It includes a conductive portion coupled to,
In the step (b), the corrosion preventing method of the iron frame, characterized in that attached to the iron frame so that the conductive portion in contact with the welding portion, the corrosion preventing device including the conductive portion.
The method of claim 7,
In the step (a), at least one of the plurality of corrosion preventing devices, the sacrificial anode so as to extend outward from one side of the sacrificial cathode material to electrically connect the iron frame and the sacrificial cathode material in contact with the iron frame. Elastic to the sacrificial positive electrode material so as to extend outwardly from the other side of the sacrificial positive electrode material to electrically connect the first conductive portion elastically deformable to the ash and the iron frame and the sacrificial cathode material in contact with the iron frame. It includes a second conductive portion that is deformably coupled,
In the step (b), the anti-corrosion device including the first conductive portion and the second conductive portion is attached to the steel frame so that the first conductive portion and the second conductive portion are elastically deformed by respectively contacting both sides of the iron bar. Method of preventing corrosion of an iron frame, characterized in that attached.
The method of claim 7,
In the step (a), at least one of the plurality of anti-corrosion devices, the fixing mechanism provided therein is an arcuate magnet, and the sacrificial anode to electrically connect the iron frame and the sacrificial cathode material in contact with an iron frame. It includes a conductive portion coupled to the sacrificial positive electrode material to extend outward from the surface of the ash,
In the step (b), the anti-corrosion device having the arcuate magnet is contacted by two iron bars connected to each other so that the arcuate magnets cross each other, and the conductive part is connected to the two iron bars contacted by the arcuate magnet. Method for preventing corrosion of the iron frame, characterized in that attached to the iron frame to contact the portion.

Images