KR102301369B1 - Anti-corrosion structure using the anode of the steel pipe on the under of the slab - Google Patents

Abstract

The present invention relates to a smart anti-corrosion structure using an anode of a steel pipe under a slab and, more specifically, to a smart anti-corrosion structure using an anode of a steel pipe under a slab, which is formed to attach a protective anode, a sacrificial anode, to one side of a steel pipe, in order to prevent the corrosion of the steel pipe, in regard to a situation in which a part of the steel pipe supporting a slab installed in a coast is immersed into the water to be inserted. Moreover, according to the present invention, an electric wire is connected to every steel pipe in a direction to a slab such that an anode attached on one side of a plurality of steel pipes provided under the slab can be electrically connected, and a connection line merged and connected with another connection wire connected from a steel pipe is installed on the slab, and, meanwhile, the connection line is connected to a solar power generator, and, thus, an anode can be operated with electricity generated using sunlight.

Description

Smart anti-corrosion structure using the anode of the steel pipe on the under of the slab

The present invention relates to a smart anti-corrosion structure using an anode of a steel pipe under a slab.

Specifically, when a part of the steel pipe supporting the slab installed on the shore is submerged in water and installed, a protective anode (Sacrificial Anode) is attached to one side of the steel pipe to prevent corrosion of the steel pipe. , relates to an anti-corrosion structure using the anode of the steel pipe under the slab.

In addition, the present invention is such that the electric wires are connected in the slab direction for each steel pipe so that the anodes attached to one side of the steel pipe provided in plurality at the lower side of the slab can be electrically connected, and the connecting wires connected from the steel pipe are merged and connected to the slab. It relates to an anti-corrosion structure using the anode of the steel pipe under the slab, configured so that the connection line is connected to the photovoltaic power generation device while installing it, so that the anode can operate using electricity generated using sunlight.

In general, marine structures are continuously accumulating corrosion due to contact between salt and water, particularly in the case of metal or concrete materials, thereby ultimately reducing the durability of the structure.

If these structures are installed on the ground, they can be replaced or managed through maintenance, but in the case of structures (slabs, etc.) The cost and risk are too large, and there is a problem in that a huge cost is consumed in terms of cost.

The present applicant has come to apply the anode technology to control corrosion prevention as a way to overcome this problem.

In addition, electricity supplied to generate the anode effect is intended to be configured to supply an infinite power source through self-generation.

The anode has been used for corrosion prevention in various fields for a long time. For example, in Korean Patent Application Laid-Open No. 10-2012-0100950, an anode retainer for a cathodic corrosion prevention device of a foundation pipe of an offshore wind power plant, a foundation pipe of an offshore wind power plant A connection structure between the and foundation pipes, a cathodic corrosion protection device for a foundation pipe of an offshore wind power plant, and an offshore wind power plant are described.

The above technology relates to an anode retainer for a cathodic corrosion protection device of a foundation pipe of an offshore wind turbine, the anode retainer comprising a metal cylinder ring having a longitudinal axis, an outer part and an inner part, and a plurality of positioning means are arranged around the perimeter. It is provided on the inner side, and interacts with the corresponding positioning protrusions (70) located on the outer side of the foundation pipe, concentrically self-positioning without a separate tool, and also the cylinder ring on the foundation pipe by gravity The present invention provides a connection structure between the foundation pipe of the offshore wind power plant, in which a plurality of positioning protrusions are provided on the outer side on the cylinder ring region, and the foundation pipe of the offshore wind power plant and the anode retainer. wherein the anode retainer is arranged concentrically around the foundation pipe, and the positioning projections of the foundation pipe are fixed to the positioning means of the anode retainer in a forced locking manner.

Laid-open Patent Publication No. 10-2012-0100950 (2012.09.12.)

An object of the present invention is to attach a protective anode (Sacrificial Anode) to one side of a steel pipe to prevent corrosion of the steel pipe when a part of the steel pipe supporting the slab installed on the shore is submerged in water. To propose a corrosion-resistant structure using the anode of the steel pipe under the slab, configured to do so.

Another object of the present invention is to connect an electric wire in the slab direction for each steel pipe so that the anode attached to one side of the steel pipe provided in plurality under the slab can be electrically connected, and another connecting line that merges and connects the connecting lines connected from the steel pipe is installed in the slab, this connection line is connected to the photovoltaic device, so that the anode can operate using electricity generated using sunlight. is doing

It was devised to achieve the above object, and according to the present invention, a corrosion protection structure using an anode of a steel pipe under a slab includes: a slab 10; a steel pipe 20 installed on the lower side of the slab 10, a part of which is installed in water; It is characterized in that it is configured to include; a power generation device (30) electrically connected to the steel pipe (20), configured to enable self-generation, and transmit the generated power to the steel pipe (20).

At this time, it is characterized in that the anode 21 is attached to one side of the outside of the steel pipe 20 .

In addition, the anode 21 is connected to an individual connecting line 31 , which functions as an electric line for receiving electricity from the power generation device 30 for an electric action, and the individual connecting line 31 is connected to the inside of the steel pipe 20 . It is characterized in that it is buried in

In addition, in the slab 10, a merge connection line 32 connecting the individual connection lines 31 exposed from the steel pipe 20 is embedded, and the merge connection line 32 is exposed to the outside of the slab 10 to generate a power generation device It is characterized in that it is connected to (30).

On the other hand, the power generation device is characterized in that the solar power generation device.

According to the corrosion prevention structure using the anode of the steel pipe under the slab according to the present invention, when a part of the steel pipe supporting the slab installed on the shore is submerged in water and installed, a Protective Anode (Sacrificial Anode) is applied to one side of the steel pipe By configuring to attach to the, it is possible to prevent corrosion of the steel pipe.

In addition, electric wires are connected in the slab direction for each steel pipe so that the anodes attached to one side of the steel pipe provided in multiple pieces at the lower side of the slab can be electrically connected, and the other connecting wires that connect the connecting wires connected from the steel pipes are installed in the slab. , by allowing this connection line to be connected to the photovoltaic device, it has the advantage of enabling infinite driving.

1 is a lateral view showing a corrosion-preventing structure using an anode of a steel pipe under a slab according to the present invention.
2 is a perspective view showing a corrosion-preventing structure using the anode of the steel pipe under the slab according to the present invention.

The terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concepts of the terms to best describe his invention. Based on the principle, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

Hereinafter, prior to the description with reference to the drawings, it is not shown or specifically described for the known configurations that are not necessary to reveal the gist of the present invention, that is, those skilled in the art that can be added obviously by those skilled in the art. reveal the sound

The present invention relates to a smart anti-corrosion structure using an anode of a steel pipe under a slab.

Specifically, when a part of the steel pipe supporting the slab installed on the shore is submerged in water and installed, a protective anode (Sacrificial Anode) is attached to one side of the steel pipe to prevent corrosion of the steel pipe. , relates to an anti-corrosion structure using the anode of the steel pipe under the slab.

In addition, the present invention is such that the electric wires are connected in the slab direction for each steel pipe so that the anodes attached to one side of the steel pipe provided in plurality at the lower side of the slab can be electrically connected, and the connecting wires connected from the steel pipe are merged and connected to the slab. It relates to an anti-corrosion structure using the anode of the steel pipe under the slab, configured so that the connection line is connected to the photovoltaic power generation device while installing it, so that the anode can operate using electricity generated using sunlight.

Hereinafter, the above-described electric wire is sufficient if the connection wire, which is an electric wire, is prepared to be buried when manufacturing a steel pipe or slab, which is based on the expertise of a person skilled in the art.

1 is a lateral view showing a corrosion prevention structure using an anode of a steel pipe under a slab according to the present invention, and FIG. 2 is a perspective view showing a corrosion prevention structure using an anode of a steel pipe under a slab according to the present invention.

According to FIG. 1 of the accompanying drawings, a slab 10 and; a steel pipe 20 installed on the lower side of the slab 10, a part of which is installed in water; It is configured to include a; is electrically connected to the steel pipe 20, is configured to enable self-generation and transmits the generated electric power to the steel pipe 20;

At this time, the anode 21 may be attached to one side of the outside of the steel pipe 20 .

The anode 21 is a metal having a lower potential than the steel pipe 20 , and when an electric action is generated, an anode effect is generated in the steel pipe 20 to prevent corrosion.

Here, the anode effect refers to a phenomenon in which reactants are generated according to the progress of electrolysis in molten salt electrolysis, and the wettability with the electrolytic bath is deteriorated, so that the voltage is significantly increased, only the arc current flows, and the electrolytic reaction does not proceed. .

That is, the anode 21 is dissolved as an anode by an electric action to prevent dissolution (corrosion) of a metal to be corroded (steel pipe 20), for example, aluminum, zinc, magnesium, or the like.

The anode 21 is connected to an individual connection line 31 which functions as an electric wire for receiving electricity from the generator 30 for an electrical action, and the individual connection line 31 is buried in the steel pipe 20 . do.

At this time, the slab 10 forms a first hole 11 on one surface that the steel pipe 20 is in contact with, and accordingly, inside the slab 10, a plurality of first holes ( 11) is formed.

The first hole 11 may be used for inserting the end of the steel pipe 20 , or may be used for penetrating the individual connecting lines 31 exposed from the steel pipe 20 .

Further, in the slab 10, a merge connection line 32 connecting the individual connection lines 31 exposed from the steel pipe 20 may be embedded, and the second side of the slab 10 so that the merge connection line 32 is exposed on the other side. It may include a hole 12 .

At this time, the above-described first hole 11 and second hole 12 may be configured as a hole as shown in the drawings or the above description, but in the case of exposing only by burying each connection line according to design conditions, the connection line is exposed. It may mean the smallest gap.

For example, in the latter case, in manufacturing the slab, it means that each connecting line is installed and cured before curing, and accordingly, only the connecting line is exposed through small fine gaps as holes 11 and 12.

In addition, the merge connection line 32 connecting the individual connection lines 31 achieves a merge connection based on the expertise of those skilled in the art in the form of series or parallel.

When the merged connection line 32 is exposed from the slab 10 , it is connected to the power generation device 30 so that the anode 21 can receive the power of the power generation device 30 .

The power generation device 30 may be a solar power generation device that performs self-generation based on sunlight. Alternatively, it may be configured as a power generation device that performs self-generation by using wave or tidal power at the shore.

On the other hand, the anode 21 according to the present invention may be coupled (attached) to the steel pipe 20 using a coupling device 40 as shown in [Table 1] according to design conditions, in which case the coupling device 40 Using the same material as the steel pipe 20 may be effective in preventing corrosion of the coupling device 40 .

The coupling device 40 according to [Table 1] is composed of a predetermined plate shape as shown in (A), and the bolt (b) is a bolt hole (b) through which the other end of the bolt is penetrated and exposed in a form in which the head is interpolated. 41) and;

a fixing part 42 for fixing the anode 21 by protruding from one surface in the direction of the anode 21 of the coupling device 40 and having an inner surface corresponding to the outer shape of the anode 21;

One surface of the coupling device 40 in the direction of the anode 21 is formed to protrude in a direction symmetrical to the fixing part 42, and is movable so that the fixing part 42 can be adjusted by a predetermined interval as a target. It is configured to include; a movable fixing unit 43 configured.

At this time, the bolt (b) having a part of the end exposed through the bolt hole (41) may be inserted and covered in the bolt cap (c).

This bolt cap (c) can be inserted into a groove formed in advance in the steel pipe 20, which is when the anode 21 needs to be replaced, when the bolt (b) of the coupling device 40 is somewhat loosened, otherwise , in order to continue using the same groove without continuously forming a groove for bolt fastening in the steel pipe 20 when it is necessary to change the coupling device 40 itself.

The movable fixing unit 43 may refer to (B) of [Table 1].

The coupling device 40 corresponding to the movable fixing part 43 has a through hole 43a penetrated in the width direction; a guide plate (43b) connected to one side of the movable fixing part (43) and passing through the through hole (43a) but bent in a 'L' shape; and a long hole 43c formed at a position corresponding to the bolt hole 41 among one side of the guide plate 43b.

In addition, the through hole 43a has a thickness greater than the thickness of the guide plate 43b, and accordingly, a plurality of springs may be provided in the space between the through hole 43a and the guide plate 43b. .

According to this configuration, when the tightening of the bolt penetrating through the bolt hole is somewhat loosened, the tightening of the long hole 43c is released and the movement of the guide plate 43b is possible, and thereby, the movable fixing part 43 is movable in a direction away from the fixing part 42 .

In this case, the combination and separation of the anode 21 can be performed, so that the replacement operation is possible. The plate 43b is held while generating friction so that the moving fixing part 43 does not move.

At this time, the spring provided in the through-hole 43a is provided in the through-hole 43a upwards based on the drawing of the guide plate 43b so as to always push the guide plate 43b.

What has been described above using the drawings is to describe only the main points of the present invention, and as many designs are possible within the technical scope, it is obvious that the present invention is not limited to the configuration of the drawings.

10: slab
11: 1st hall
12: 2nd hole
20: steel pipe
21 : anode
30: power generation device
31: individual connection line
32: merge connector

Claims (5)

a slab 10;
a steel pipe 20 installed on the lower side of the slab 10, a part of which is installed in water;
Corrosion prevention structure using the anode of the steel pipe under the slab, which is electrically connected to the steel pipe 20, and is configured to enable self-generation and transmits the generated electric power to the steel pipe 20; In
An anode 21 is attached to the outer side of the steel pipe 20 using a coupling device 40,
The coupling device 40,
Doedoe composed of a predetermined plate shape, the bolt hole 41 through which the other end of the bolt is exposed in a form in which the head of the bolt (b) is interpolated;
a fixing part 42 for fixing the anode 21 by protruding from one surface in the direction of the anode 21 of the coupling device 40 and having an inner surface corresponding to the outer shape of the anode 21;
One surface of the coupling device 40 in the direction of the anode 21 is formed to protrude in a direction symmetrical to the fixing part 42, and is movable so that it can be adjusted by a predetermined interval with respect to the fixing part 42 as a target. Constructed to include a movable fixing unit 43;
In the coupling device 40 corresponding to the movable fixing part 43,
a through hole (43a) penetrated in the width direction; a guide plate 43b connected to one side of the movable fixing part 43 and passing through the through hole 43a but bent in a 'L'shape; A long hole (43c) formed at a position corresponding to the bolt hole (41) of one side of the guide plate (43b); is included,
The through hole 43a has a thickness greater than that of the guide plate 43b, and as a plurality of springs are provided in the space between the through hole 43a and the guide plate 43b,
When loosening the fastening of the bolt penetrating through the bolt hole 41, the fastening of the long hole 43c is released to enable movement of the guide plate 43b, and the movable fixing part 43 is fixed to the fixing part 42. to be able to move in a direction away from
Since the anode 21 can be coupled and separated, the replacement operation is possible, and when the bolt is tightened again, the surface of the bolt coupling device 40 and the surface of the steel pipe 20 are the guide plate 43b. ), a corrosion-resistant structure using the anode of the steel pipe under the slab, characterized in that it is held while generating friction so that the moving fixing part 43 does not move.
delete The method according to claim 1,
The anode 21 is connected to an individual connection line 31 which functions as an electric wire for receiving electricity from the generator 30 for an electrical action, and the individual connection line 31 is buried in the steel pipe 20 . Corrosion prevention structure using the anode of the steel pipe under the slab, characterized in that it becomes.
4. The method according to claim 3,
In the slab 10, a merge connecting line 32 connecting the individual connecting lines 31 exposed from the steel pipe 20 is embedded,
The merging connection line (32) is exposed to the outside of the slab (10) and is connected to the power generation device (30).
The method according to claim 1,
The power generation device is a photovoltaic power generation device, characterized in that the corrosion prevention structure using the anode of the steel pipe under the slab.

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