JP2012180556A - Electrolytic protection structure and method for forming the electrolytic protection structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrolytic protection structure which can uniformly perform electrolytic protection of the tidal range of a pillar section.SOLUTION: The electrolytic protection structure 1 suppresses the erosion of a pillar section 210 which is formed of a steel pipe or reinforced concrete so as to extend in the upper and lower directions, and in which one edge side is arranged in the air, and further, the other edge is arranged into electrolytic water W where the height of the water surface L periodically changes. The electrolytic protection structure includes: a conductor 20 arranged to cover the whole of the outer circumferential face of the pillar section in a tidal range 212 where the height of the water surface periodically changes; a substrate 30 filled between the outer circumferential face in the tidal range and the conductor and retaining the conducting state between the pillar section and the conductor by being deformed in accordance with the changes in the shapes of the outer circumferential face in the tidal range and the conductor in a state of holding the electrolytic water; and an electric current generation section 40 electrically connected to the steel pipe or a reinforcing rod in the reinforced concrete, further arranged in the electrolytic water, and generating electric current between itself and the conductor through the electrolytic water.

Description

  The present invention relates to an anticorrosion structure for preventing a structure formed of steel or reinforced concrete from being corroded by electrolyzed water such as seawater, and a method for forming the anticorrosion structure.

Conventionally, piles (columns) made of reinforced concrete or steel pipe are provided in seawater (electrolyzed water) to support bridges, roads, offshore platforms, quay walls, wave-dissipating facilities, and the like.
Piles in seawater corrode when steel in the pile or iron in the reinforcing bar ionizes and flows into the seawater. In order to prevent this corrosion, a current generating part such as a sacrificial anode is provided on the pile to generate a direct current that can overcome the corrosion current.
As one example of such an anti-corrosion structure, for example, an anti-corrosion structure of a concrete structure described in Patent Document 1 is known.

In this cathodic protection structure, the surface of the concrete pile is made of a conductive covering such as a conductive paint (conductor), a current suction material such as a nonwoven sheet containing an acrylic water-absorbing polymer, and a fiber reinforced plastic. The exterior materials are sequentially covered. The current wicking material is arranged so that its lower part is immersed in seawater. In addition, an galvanic anode is connected to a portion of the concrete pile in seawater.
According to this cathodic protection structure, the conductive coating serves as a distributed electrode for cathodic protection, and the current wicking material that sucks up seawater shields the concrete pile from the atmosphere. It can be said.

  Moreover, generally, in a pile, a portion (a tidal range) that repeats a dry state in the atmosphere and a submerged state in seawater due to sea surface tidal is significantly accelerated. For this reason, the anti-corrosion of the pile is performed around this tidal range.

Japanese Patent Laid-Open No. 62-267485

  However, in the anticorrosion structure disclosed in Patent Document 1, since the conductive coating is directly coated on the surface of the concrete pile, when the pile is dried, the conductive coating is peeled off from the surface of the pile. In some cases, a gap may be formed between the pile and the conductive coating. For this reason, there is a problem that current concentrates and flows in the portion where the conductive coating is in contact with the concrete pile, the conductive coating is unevenly worn, and the concrete pile cannot be stably protected.

  This invention is made | formed in view of such a problem, Comprising: It aims at providing the cathodic protection structure which can carry out the corrosion prevention of the tidal range of a pillar part uniformly.

In order to solve the above problems, the present invention proposes the following means.
The cathodic protection structure of the present invention is a column that is formed of steel pipe or reinforced concrete so as to extend in the vertical direction, one end side is disposed in the atmosphere, and the other end side is disposed in the electrolytic water in which the height of the water surface changes periodically. An electro-corrosion preventing structure that suppresses erosion of a portion, and a conductor disposed so as to cover the entire outer peripheral surface of the pillar portion in a tidal range in which the height of the water surface periodically changes, and the tidal range The column portion and the conductor are deformed corresponding to a change in the shape of the outer peripheral surface of the tidal range and the conductor in a state of being filled between the outer peripheral surface of the conductor and the conductor and holding the electrolyzed water. A base body that maintains a conductive state with the conductor, and is electrically connected to the steel pipe or the reinforcing bar in the reinforced concrete and disposed in the electrolyzed water, and generates an electric current between the conductor through the electrolyzed water. It is characterized in that it comprises a current generator that, the.

  In addition, the method for forming the cathodic protection structure of the present invention is formed in steel or reinforced concrete so as to extend in the vertical direction, and the other end is placed in the electrolytic water in which one end side is disposed in the atmosphere and the height of the water surface changes periodically. A method of forming an anti-corrosion structure that suppresses erosion of a pillar portion on which a side is disposed, wherein the conductor covers the entire outer peripheral surface of the pillar portion in a tidal range where the height of the water surface changes periodically. The base body is filled between the outer peripheral surface of the tidal range and the conductor, and the base body holding the electrolyzed water is deformed corresponding to the outer peripheral surface of the tidal range and the shape of the conductor. By doing so, the current generation part that maintains the conduction state between the pillar part and the conductor and is electrically connected to the steel or the reinforcing steel in the reinforced concrete is disposed in the electrolyzed water, and the electrolyzed water passes through the electrolyzed water. Current It is characterized by generating an electric current between the raw portion the conductor.

  According to this invention, even if the outer peripheral surface of the tidal range in the column portion and the shape of the conductor are deformed due to drying or thermal expansion, the substrate holding the electrolytic water corresponding to the deformed shape is deformed. Then, the conduction between the column portion and the conductor is maintained over the entire contact surface of the substrate.

Further, in the above-described cathodic protection structure, a support base made of reinforced concrete is attached to the one end of the column portion, and the conductor is an air that is a portion above the tidal range in the column portion. And the base is filled between the air range and the outer peripheral surface of the support base and the conductor, and when the water surface becomes the highest. More preferably, a distal end is disposed below the level of the water surface, and a base end is provided with an auxiliary conductor electrically connected to a portion of the conductor covering the outer peripheral surface of the support base.
In this case, the current generated by the current generator and flowing in the electrolyzed water flows to the conductor covering the outer peripheral surface of the support base through the auxiliary conductor. Then, due to the conductor, the base body, and the auxiliary conductor, a current flows almost uniformly in the tidal range, the atmospheric range, and the outer peripheral surface of the support base.

In the above-described cathodic protection structure, it is more preferable that the lower end portion of the conductor is configured to extend below the lower end portion of the base body. In this case, the current flowing from the current generator is received in a wider area near the current generator.
In the above-described cathodic protection structure, it is more preferable that an insulating member is provided between a portion of the conductor that extends downward from the base body and the column portion.
In the above-described cathodic protection structure, it is more preferable that a second conductor formed of a material having a smaller ionization tendency than the conductor is provided at the lower end of the conductor.

Further, in the above-described anticorrosion structure, the conductor is formed integrally with the plate material in a state of being disposed on one surface of the plate material to constitute a conductive plate, and the conductive plate is configured to convert the conductor into the column. It is more preferable that it is attached to the column part in a state of being arranged on the part side.
Further, in the above-described cathodic protection structure, a through-hole is formed below the height of the water surface when the water surface of the conductor is the highest, and the electrolyzed water is passed so as to cover the through-hole. More preferably, a permeable membrane that does not pass through the substrate is provided.
Moreover, in the above-described cathodic protection structure, it is more preferable that the conductor is configured to approach the column portion as it goes downward. In this case, the substrate is pressed against the outer peripheral surface of the tidal range by gravity acting on the substrate. In addition, due to the influence of gravity, the substrate that is reduced in electrolyzed water and dried and lightened easily moves upward, and the substrate that sufficiently contains electrolyzed water and moves easily moves downward.

In the present invention, according to the method of forming an anticorrosion structure according to claim 1 and an anticorrosion structure according to claim 9, the current generating part is passed through the base body holding the electrolyzed water, the conductor and the electrolyzed water to the column part. An electric current can be reliably flowed, and a potential difference can be uniformly generated between the current generating portion and the tidal range in the column portion. Thereby, the tidal range in a pillar part can be prevented uniformly.
According to the cathodic protection structure of the second aspect, the loss of current can be suppressed, and the tidal range, the atmospheric range, and the support base in the column portion can be effectively catalysed.

According to the cathodic protection structure of the third aspect, a larger amount of current can flow in the tidal range through the conductor.
According to the cathodic protection structure of the fourth aspect, the current flowing through the conductor can be increased by suppressing the current that has entered the lower end of the conductor from flowing into the column.
According to the cathodic protection structure of the fifth aspect, the current flowing through the conductor can be increased by adding the electromotive force of the second conductor to the electromotive force of the conductor.

According to the cathodic protection structure of the sixth aspect, by handling the conductive plate, the work of attaching the conductor to the column portion can be easily performed.
According to the cathodic protection structure of the seventh aspect, by taking electrolytic water into the substrate through the permeable membrane, it is possible to suppress the substrate from drying and deterioration of the conduction between the column portion and the conductor.
According to the cathodic protection structure of the eighth aspect, it is possible to increase the adhesion between the column portion and the substrate, and more reliably suppress the current from flowing from the substrate to the column portion. In addition, replacement of the substrate that has lost its water retention function and replenishment of electrolyzed water can be easily performed above the substrate, that is, in the atmosphere.

It is front sectional drawing of the pier where the cathodic protection structure of 1st Embodiment of this invention was used. It is a principal part enlarged view in FIG. It is principal part sectional drawing in the cathodic protection structure of the modification of 1st Embodiment of this invention. It is principal part sectional drawing in the cathodic protection structure of the modification of 1st Embodiment of this invention. It is principal part sectional drawing in the cathodic protection structure of the modification of 1st Embodiment of this invention. It is front sectional drawing in the cathodic protection structure of the modification of 1st Embodiment of this invention. It is front sectional drawing of the pier where the cathodic protection structure of 2nd Embodiment of this invention was used. It is principal part sectional drawing in the cathodic protection structure of the modification of 2nd Embodiment of this invention. It is principal part sectional drawing in the cathodic protection structure of the modification of 2nd Embodiment of this invention. It is principal part sectional drawing in the cathodic protection structure of the modification of 2nd Embodiment of this invention. It is principal part sectional drawing in the cathodic protection structure of the modification of 2nd Embodiment of this invention. It is front sectional drawing of the jetty in which the cathodic protection structure of 3rd Embodiment of this invention was used. It is front sectional drawing of the pier where the cathodic protection structure of the modification of 3rd Embodiment of this invention was used. It is front sectional drawing of the pier where the cathodic protection structure of 4th Embodiment of this invention was used. It is front sectional drawing of the pier where the cathodic protection structure of the modification of 4th Embodiment of this invention was used. It is a figure explaining the method of maintaining the cathodic protection structure of the present invention.

(First embodiment)
Hereinafter, a first embodiment of the cathodic protection structure according to the present invention and a jetty using the cathodic protection structure will be described with reference to FIGS. 1 to 6.
As shown in FIG. 1, the pier 200 includes a pedestal (column) 210 formed to extend in the vertical direction by a steel pipe, and a support base 220 attached to one end 210 a of the pedestal 210. The other end 210b of the pedestal 210 is fixed to a foundation (not shown) provided on the ground G located below the seawater (electrolyzed water) W. Generally, the seawater W has electrical conductivity.
L1 in FIG. 1 indicates the envy average high tide surface, that is, the high tide water surface L1 that is the highest water surface, and L2 is the envy average low tide surface, that is, the low tide water surface that is the lowest water surface. L2 is shown. The height of the water surface L periodically changes between the height of the high tide water surface L1 and the height of the low tide water surface L2 with about 6 hours as one cycle.
The pedestal 210 is located above the high tide water surface L1 and is always arranged in the atmosphere (atmosphere range) 211, and a tidal portion (below the high tide water surface L1 and above the low tide water surface L2). (Tidal range) 212 and an underwater part 213 which is located below the low tide water surface L2 and is always arranged in the seawater W. The tidal portion 212 is located below the water surface L at high tide and wet with the seawater W, and is dry above the water surface L at low tide, so that corrosion tends to proceed.

In the present embodiment, a mortar layer 215 is provided in a substantially cylindrical shape on the outer peripheral surface from the atmosphere part 211 to the upper part of the underwater part 213.
The mortar layer 215 has a reinforcing bar 216 whose end is connected to the pedestal 210 and a mortar 217 arranged to cover the reinforcing bar 216. The mortar layer 215 is moistened to some extent when at least the lower part is immersed in the seawater W.
As shown in FIG. 2, an angle member 218 for attaching a metal plate 20 to be described later is fixed to the lower part of the outer peripheral surface of the mortar layer 215. The angle member 218 is made of an insulating material.

The support table 220 is made of reinforced concrete. As shown in FIG. 1, the support base 220 includes a columnar base portion 221 connected to one end 210 a of the pedestal 210 and the top surface of the mortar layer 215, and a pair of adjacent base portions 221 (one base portion 221 is And a cross-linked portion 222 that is cross-linked.
The end of the reinforcing bar 223 built in the support base 220 is connected to one end 210 a of the pedestal 210.

Then, the cathodic protection structure 1 of this embodiment is demonstrated.
This cathodic protection structure 1 is filled between a metal plate (conductor) 20 disposed so as to cover the entire outer peripheral surface of the tidal portion 212 and the atmosphere portion 211, and between the mortar layer 215 and the metal plate 20, and is not illustrated. The base 30 that holds the seawater W, the sacrificial anode (current generation unit) 40 connected to the underwater part 213 of the pedestal 210, and the auxiliary metal plate (auxiliary conductivity) in which the base end 50 a is electrically connected to the metal plate 20. Body) 50.

In this example, the metal plate 20 is formed of a metal such as stainless steel or titanium having high corrosion resistance. The lower end of the metal plate 20 is set to be positioned below the low tide water surface L2.
The metal plate 20 not only covers the entire outer peripheral surface of the mortar layer 215 at a position spaced apart from the outer peripheral surface by a certain distance, but also covers the outer peripheral surface of the base portion 221 and the bottom surface of the bridging portion 222 of the support base 220. It is covered at a position spaced a certain distance from.
As shown in FIG. 2, an angle member 21 made of an insulating material is fixed to the lower part of the inner peripheral surface of the metal plate 20. The metal plate 20 is attached to an angle member 218 fixed to the mortar layer 215 by an anchor 22 a provided at the tip of the insulating bolt 22. Between the angle member 218 and the angle member 21, a lower permeable membrane 23 which has water absorption and water retention properties and does not allow the base 30 to pass is attached so that the base 30 does not leak into the seawater W from below. In the present embodiment, the lower permeable membrane 23 is disposed below the low tide water surface L2 (see FIG. 1).

In this embodiment, the substrate 30 is formed of a polymer material having water absorption. The base 30 is filled not only between the metal plate 20 and the mortar layer 215 but also between the metal plate 20 and the base portion 221 and the bridging portion 222.
The base body 30 holding the seawater W has a certain fluidity, and is deformed in accordance with the outer peripheral surface of the mortar layer 215 and the shape of the metal plate 20, so that the mortar layer 215 and the metal plate 20 are electrically connected. Is supposed to maintain. The base body 30 is connected to the end of the reinforcing bar 223.
The sacrificial anode 40 is formed of a metal such as magnesium, aluminum, and zinc, which has a higher ionization tendency than the metal plate 20 and iron, and is disposed in the seawater W. The sacrificial anode 40 is electrically connected to the underwater portion 213 by being attached to the underwater portion 213 of the pedestal 210.

The auxiliary metal plate 50 is formed of, for example, a metal plate material, and the tip 50b is disposed below the low tide water surface L2. The base end 50 a of the auxiliary metal plate 50 is electrically connected to a portion of the metal plate 20 that covers the bottom surface of the bridging portion 222.
The auxiliary metal plate 50 is inserted into a tube material 51 made of vinyl chloride or the like, and the tube material 51 is attached to the metal plate 20.

Next, a method for forming the cathodic protection structure 1 of the present embodiment configured as described above will be described.
In addition, before performing this formation method, it is preferable to perform a kelen process and repair of a defect part with respect to the mortar layer 215. Keren treatment is removal of dirt on the surface of the mortar 217 with a brush or the like. Further, the repair of the defective portion means that the portion where the mortar 217 is cracked or floated is repaired so that the unevenness is eliminated along the substantially cylindrical outer peripheral surface.

First, the metal plate 20 is formed at a position spaced apart from the mortar layer 215 by a certain distance so as to cover the entire outer peripheral surface of the mortar layer 215 (conductor formation step). At this time, it forms so that the lower end of the metal plate 20 may be located below the low tide water surface L2. A lower permeable membrane 23 is attached between the mortar layer 215 and the metal plate 20 at the lower part of the metal plate 20. The lower permeable membrane 23 is installed below the low tide water surface L2.
Next, the substrate 30 is filled between the outer peripheral surface of the mortar layer 215 and the metal plate 20 and above the lower permeable membrane 23 (substrate filling step). Thereafter, the seawater W penetrates into the base body 30 through the lower permeable membrane 23 as time elapses, but the seawater W may be directly injected into the base body 30 in order to shorten the construction period. The base body 30 holding the seawater W is deformed in accordance with the shapes of the mortar layer 215 and the metal plate 20, and maintains a conductive state between the mortar layer 215 and the metal plate 20.
Subsequently, the sacrificial anode 40 is disposed in the seawater W in a state of being connected to the underwater portion 213 of the pedestal 210, and a corrosion-proof current is generated between the metal plate 20 through the seawater W (anode installation step).

The anticorrosion structure 1 is formed on the jetty 200 by the above process.
In the method for forming the cathodic protection structure, the anode installation step may be performed before the conductor formation step or the substrate filling step.

Next, the effect | action of the anti-corrosion structure 1 comprised as mentioned above is demonstrated.
The following actions occur when the height of the water surface L is higher than the low tide water surface L2 and lower than the high tide water surface L1.
The sacrificial anode 40, the pedestal 210, the reinforcing bar 216, and the reinforcing bar 223 are formed of metal and are electrically connected to each other, and therefore have substantially the same potential. Since the sacrificial anode 40 is formed of a metal having a higher ionization tendency than the metal plate 20, the metal forming the sacrificial anode 40 is ionized and flows into the seawater W, and the corrosion protection current flows from the sacrificial anode 40 to the metal plate 20 through the seawater W. Flows.
On the other hand, the seawater W passes through the lower permeable membrane 23 and rises in the base body 30 formed of the polymer material by a capillary phenomenon. Since the dry substrate 30 is lighter than the substrate 30 wet with seawater W, the relatively light dry substrate 30 moves upward between the mortar layer 215 and the metal plate 20, and the substrate 30 wet with relatively heavy seawater W. Moves downward. By this circulation action, the seawater W spreads over the entire base 30.

At this time, the base body 30 holding the seawater W maintains the conduction state between the mortar layer 215 and the metal plate 20 over the entire contact surface of the base body 30, so that the outer periphery of the tidal portion 212 of the pedestal 210 is interposed via the mortar layer 215. Anticorrosion current flows uniformly on the surface. This anticorrosion current is transmitted upward by the metal plate 20 and also flows to the outer peripheral surface of the atmospheric part 211 of the pedestal 210 and the base part 221 of the support base 220. This electric current prevents the iron molecules in the tidal portion 212 and the reinforcing bars 216 and 223 of the pedestal 210 from being ionized, thereby preventing corrosion.
On the other hand, the anticorrosive current flowing from the sacrificial anode 40 through the seawater W into the auxiliary metal plate 50 from the tip 50b of the auxiliary metal plate 50 is a metal disposed on the support base 220 with the current loss suppressed by the auxiliary metal plate 50. It flows directly to the plate 20.

  As described above, according to the method of forming the anticorrosion structure 1 and the anticorrosion structure 1 of the present embodiment, when the outer peripheral surface of the mortar layer 215 and the shape of the metal plate 20 are deformed due to drying or thermal expansion. Even if it exists, the base | substrate 30 holding the seawater W corresponding to the shape which these deform | transformed deform | transforms, and can conduct | electrically_connect the mortar layer 215 and the metal plate 20 over the whole contact surface of the base | substrate 30. FIG. Accordingly, the current is reliably supplied from the sacrificial anode 40 to the tidal portion 212, the atmospheric portion 211, and the support base 220 of the pedestal 210 through the seawater W, the metal plate 20, the base body 30 holding the seawater W and the mortar layer 215, and uniformly. A potential difference can be generated. Therefore, the tidal part 212, the atmospheric part 211, and the support table 220 can be uniformly prevented from corrosion.

The cathodic protection structure 1 includes an auxiliary metal plate 50 having a distal end 50b disposed below the low tide water surface L2 and a base end 50a electrically connected to the metal plate 20. Therefore, regardless of the height of the water surface L, the current generated by the sacrificial anode 40 and flowing in the seawater W is passed through the auxiliary metal plate 50 to the rebar 223 in the support base 220, thereby suppressing current loss and the support base. More current can be directly applied to 220, so that the support 220 can be effectively anticorrosive.
Since the base body 30 holding the seawater W prevents the outer peripheral surfaces of the mortar layer 215 and the tidal portion 212 of the pedestal 210 from coming into contact with oxygen, the mortar layer 215 and the tidal portion 212 can be prevented from corroding. it can.

  In the present embodiment, the tip 50b of the auxiliary metal plate 50 is configured to be disposed below the low tide water surface L2. However, this is not an essential configuration. For example, when a relatively sufficient current can be supplied to the support base 220, the tip 50b of the auxiliary metal plate 50 may be disposed above the low tide water surface L2 and below the high tide water surface L1. .

As will be described below, the structure of the cathodic protection structure 1 of the present embodiment can be variously modified.
For example, in the present embodiment, as shown in FIG. 3, the lower permeable membrane 23 may be disposed above the low tide water surface L2 and below the high tide water surface L1.
As described above, the height of the water surface L periodically changes approximately every 6 hours between the height of the high tide water surface L1 and the height of the low tide water surface L2. For this reason, if the lower permeable membrane 23 is in the seawater W for a certain period of time, it is possible to transmit the seawater W in such an amount that the base body 30 does not dry.

Further, as shown in FIG. 4, a through hole 20a is formed below the height of the high tide water surface L1 in the metal plate 20, and a side permeable membrane (permeable membrane) 56 is provided so as to cover the through hole 20a. You may comprise. The side permeable membrane 56 is configured to allow seawater W to pass but not the base 30.
In the present modification, seawater W can be permeated through the side permeable membrane 56 provided on the metal plate 20 and taken into the base 30, so that the lower permeable membrane 23 is replaced below the base 30. An insulating material 57 is disposed.
By providing the side permeable membrane 56, it is possible to prevent the base 30 from being dried and the conduction between the mortar layer 215 and the metal plate 20 from being deteriorated.

As shown in FIG. 5, you may comprise so that the metal plate 20 may approach the mortar layer 215 as it goes below.
With this configuration, the base body 30 is pressed against the outer peripheral surface of the mortar layer 215 by gravity acting on the base body 30. For this reason, the adhesiveness between the base body 30 and the mortar layer 215 is enhanced, and it is possible to more reliably suppress the current from being difficult to flow from the base body 30 to the mortar layer 215.
Further, the base 30 that is lightened by the seawater W due to the influence of gravity is easy to move upward, and the base 30 that sufficiently contains the seawater W and is heavy is easy to move downward. For this reason, replacement | exchange of the base | substrate 30 which lost the water retention function, and replenishment of the seawater W can be easily performed above the base | substrate 30, ie, the air | atmosphere.

Even when a gap V is formed between the top surface of the mortar layer 215 and the bottom surface of the base portion 221 as in the pier 201 shown in FIG. 6, the cathodic protection structure 2 of the present invention can be used.
In this case, the cathodic protection structure 2 includes a metal plate 61 disposed above the gap V and a metal plate 62 disposed below the gap V, instead of the metal plate 20 of the cathodic protection structure 1 of the present embodiment. It has.
An anticorrosion layer 63 formed of an anticorrosion paint or the like is provided on the outer surface of the pedestal 210 exposed in the gap V.
It is preferable that the space between the base portion 221 of the support base 220 and the metal plate 62 at the lower part of the metal plate 61 is sealed with the insulating material 57 described above.
By configuring the cathodic protection structure 2 in this manner, the cathodic protection structure 2 of the present invention can be used for the existing jetty 201 as well.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. 7 to 11. However, the same parts as those of the above embodiment are denoted by the same reference numerals, and the description thereof will be omitted. explain.
As shown in FIG. 7, the cathodic protection structure 3 of the present embodiment includes a metal mesh (conductor) 70 and a metal plate 20, a base 30 and a lower transmission film 23 of the cathodic protection structure 1 of the first embodiment. A mortar layer (substrate) 71 is provided.

The metal mesh 70 not only covers the entire outer peripheral surface of the mortar layer 215 at a position spaced apart from the outer peripheral surface, but also fixes the outer peripheral surface of the base portion 221 and the bottom surface of the bridging portion 222 from these surfaces. Covering at a distance. The wire mesh 70 is made of a metal such as stainless steel having high corrosion resistance.
The mortar layer 71 covers the entire outer peripheral surface of the mortar layer 215 and the base portion 221 and the bottom surface of the bridging portion 222, so that the metal mesh 70 is embedded in an intermediate portion in its thickness direction.

Next, a method for forming the cathodic protection structure 3 of the present embodiment configured as described above will be described.
In addition, before performing this formation method, it is preferable to perform the above-mentioned kelen processing and repair of a defective part. Furthermore, it is preferable to spray a known primer solution on the surface of the mortar 217 so that the mortar described later can easily adhere to the mortar 217.
First, the wire mesh 70 is disposed at a position spaced apart from the entire outer peripheral surface of the mortar layer 215 by a certain distance. In order to dispose the metal mesh 70 at a position separated from the mortar layer 215 or the like, a method of fixing the tip of an anchor pin attached to the metal mesh 70 to the outer peripheral surface of the mortar layer 215 or the like can be used.
Next, a known primer solution is sprayed onto the wire mesh 70 so that the mortar can easily adhere to the wire mesh 70.
Subsequently, a mortar layer 71 is formed by spraying mortar on the wire mesh 70. At this time, the mortar is sprayed so thick that the wire mesh 70 is embedded in the mortar layer 71.
Through the above steps, the cathodic protection structure 3 is formed on the jetty 200.

In the cathodic protection structure 3 configured as described above, since the mortar layer 71 holding the seawater W is deformed in response to changes in the shapes of the mortar layer 215 and the wire mesh 70, the mortar layer 215 and the wire mesh 70 are in a conductive state. Can be maintained.
In this embodiment, the concrete layer may be formed by spraying concrete instead of the mortar layer 71.

As will be described below, the structure of the cathodic protection structure 3 of the present embodiment can be variously modified.
For example, in the present embodiment, as shown in FIG. 8, the wire mesh 70 is integrally formed with the decorative board 81 in a state of being arranged on one surface 81 a of a decorative board (plate material) 81 formed of mortar or the like. The decorative mold (conductive plate) 80 may be configured. The decorative mold 80 is manufactured to have a predetermined size in a factory or the like, and is attached to the outer peripheral surface of the mortar layer 215 at a work site where the anticorrosion structure 3 is constructed.
The decorative mold 80 is attached to the mortar layer 215 with the above-described insulating bolts 22 and the like in a state where the wire mesh 70 is disposed on the mortar layer 215 side.
In the present modification, a base 30 that holds seawater W (not shown) is filled between the decorative mold 80 and the mortar layer 215.
In the present modification, an extended metal plate (conductor) 82 is connected to the lower part of the metal mesh 70 so that the tip extends downward from the lower end of the base 30. The extended metal plate 82 is formed of a metal different from the metal mesh 70. Note that the extended metal plate 82 may be formed of a material having a smaller ionization tendency than the wire mesh 70.

By using the decorative mold 80, it is possible to suppress the work site from being contaminated with mortar splashes during construction, as compared with the case where the mortar layer 71 is formed by spraying mortar. Furthermore, by handling the decorative mold 80, the work of attaching the wire mesh 70 to the mortar layer 215 can be easily performed, and the construction period can be shortened.
By providing the extended metal plate 82, the anticorrosion current flowing from the sacrificial anode 40 through the seawater W is received closer to the sacrificial anode 40 and in a wider area. As a result, a larger amount of anticorrosive current can be passed through the wire net 70 to the tidal portion 212, the atmospheric portion 211, and the support base 220 of the pedestal 210.

As shown in FIG. 9, in the modified example, a through hole 81 b may be formed below the height of the high tide water surface L <b> 1 in the decorative plate 81. In this case, it is preferable that the mesh (gap) of the wire mesh 70 is formed finely so that the seawater W can pass but the base body 30 cannot pass. In this modification, the lower end of the wire mesh 70, the lower end of the decorative plate 81, and the lower permeable membrane 23 are set to have substantially the same height.
By comprising in this way, it can suppress that the base | substrate 30 dries and conduction | electrical_connection with the mortar layer 215 and the metal net | network 70 deteriorates.

Furthermore, in this modification, as shown in FIG. 10, the lower end of the wire mesh 70 may be positioned below the lower end of the decorative plate 81 and the lower permeable membrane 23.
By configuring in this way, more anticorrosion current can be passed through the tidal portion 212, the atmospheric portion 211, and the support base 220 of the pedestal 210, similar to the above-described extended metal plate 82.

As shown in FIG. 11, the extended metal plate 82 is provided with a second conductor 86 (having a noble potential) made of a material having a smaller ionization tendency than the extended metal plate 82, and the mortar layer of the extended metal plate 82 is provided. The insulating member 87 may be provided on the surface on the 215 side.
By providing the second conductor 86, the electromotive force of the second conductor 86 is added to the electromotive force of the extended metal plate 82, whereby the current flowing through the extended metal plate 82 can be increased.
In addition, by providing the insulating member 87, it is possible to suppress the current that has entered the lower end of the extended metal plate 82 from flowing to the mortar layer 215 side, so that the current that flows from the wire mesh 70 to the tidal portion 212 of the pedestal 210, etc. Can be increased.

It is preferable that the insulating member 87 is configured to be disposed between the outer peripheral surface of the pedestal 210 and the extended metal plate 82 without a gap. With this configuration, when any obstacle hits the outer surface of the second conductor 86, the insulating member 87 serves as a buffer material and the second conductor 86 and the extended metal plate 82 are broken. Is prevented.
The insulating member 87 may be attached to the outer peripheral surface of the mortar layer 215 below the mortar layer 71. With this configuration, it is possible to suppress the anticorrosion current flowing from the sacrificial anode 40 from flowing to the mortar layer 215 side.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. 12 and FIG. 13, but the same parts as those in the above-described embodiment will be denoted by the same reference numerals, and the description thereof will be omitted. explain.
As shown in FIG. 12, a pier 202 using the cathodic protection structure of the present embodiment includes a pedestal 230 formed of reinforced concrete instead of the steel pipe pier 210 in the pier 200 of the first embodiment. ing.
The pedestal 230 is formed in a substantially cylindrical shape by a concrete member 231 and a reinforcing bar 232 embedded in the concrete member 231. In this embodiment, the pedestal 230 and the support base 220 are integrally formed, and the reinforcing bar 232 extends into the support base 220.
As with the first embodiment, the pedestal 230 is divided into an atmospheric part 234, a tidal part 235, and an underwater part 236 according to the heights of the high tide water surface L1 and the low tide water surface L2.

The cathodic protection structure 4 used for the pier 202 is configured such that the auxiliary metal plate 50 and the pipe material 51 are not provided in the cathodic protection structure 1 of the first embodiment.
In the present embodiment, the sacrificial anode 40 is electrically connected to the reinforcing bar 232 by the connecting member 40a.

Next, the operation of the cathodic protection structure 4 configured as described above will be described.
All the reinforcing bars 232 have substantially the same potential, and the metal forming the sacrificial anode 40 is ionized and flows into the seawater W, and a corrosion-proof current flows from the sacrificial anode 40 through the seawater W to the metal plate 20.
The base body 30 holding the seawater W (not shown) is deformed corresponding to changes in the shapes of the pedestal 230, the support base 220, and the metal plate 20, thereby connecting the pedestal 230, the support base 220 and the metal plate 20. The state is maintained.
Then, the anti-corrosion current flowing from the sacrificial anode 40 causes the tidal portion 235 and the atmospheric portion 234 of the pedestal 230 to be electrically anticorrosive.
Even when the pedestal 230 is formed of reinforced concrete, the cathodic protection structure 4 configured as described above can achieve the same effects as the above embodiment.
Furthermore, the pedestal 230 with the small covering thickness of the concrete member 231 can be used by performing an anti-corrosion.

  For the jetty 202, as in the cathodic protection structure 5 shown in FIG. It is good also as a structure provided with the board 50 and the pipe material 51. FIG.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. 14 and FIG. 15. The same parts as those of the above embodiment are denoted by the same reference numerals, and the description thereof will be omitted. explain.
As shown in FIG. 14, the pier 203 in which the cathodic protection structure 6 of the present embodiment is used is formed between the above-described pedestal 210 and the support base 220 so as to have a larger diameter than the pedestal 210 and the base portion 221. Pile head concrete 240 is provided.
The pile head concrete 240 is formed of reinforced concrete. The ends of the reinforcing bars (not shown) embedded in the pile head concrete 240 are connected to the pillars 210 and the reinforcing bars 223 of the support base 220.
An anticorrosion layer 245 formed of an anticorrosion paint or the like is provided on the outer peripheral surface of the tidal portion 212 in the pedestal 210.

The cathodic protection structure 6 is the same as the cathodic protection structure 1 of the first embodiment. The metal plate 20 and the base body 30 are formed on the outer peripheral surface and the top surface of the pile head concrete 240, the outer peripheral surface of the base portion 221, and the bottom surface of the bridging portion 222. It has a configuration arranged to cover.
Note that a sealing material 90 is provided at the upper end of the metal plate 20 opposite to the lower permeable membrane 23 to maintain airtightness between the bridging portion 222 and the metal plate 20. Further, a backup material 91 is provided on the base material 30 side of the sealing material 90. The backup material 91 is provided on the joint bottom where sealing is performed for the purpose of avoiding the three-surface adhesion of the sealing material 90 provided on the joint, adjusting the filling depth, and forming the joint bottom.

  By configuring the cathodic protection structure 6 in this way, the pile head concrete 240 can be uniformly corroded, and the cathodic protection structure 6 of the present invention is also suitable for the pier 203 provided with the pile head concrete 240. Can be used.

It should be noted that the pier 203 can use an anticorrosion structure 7 as shown in FIG.
This cathodic protection structure 7 includes a metal mesh 70 and a mortar layer 71 instead of the metal plate 20 and the base 30 of the cathodic protection structure 6 of the present embodiment.
By configuring the cathodic protection structure 7 in this way, the same effects as those of the cathodic protection structure 6 of the present embodiment can be obtained.

The first to fourth embodiments of the present invention have been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and the configuration does not depart from the gist of the present invention. Changes are also included. Furthermore, it goes without saying that the configurations shown in the embodiments can be used in appropriate combinations.
For example, in the first to fourth embodiments, the substrate is a polymer material having water absorption or a mortar layer. However, other than these, for example, a material called backfill can be used as the substrate. The backfill is a mixture of a clay-based material called kaolin that retains moisture and a carbon-based powdered or fibrous conductive material such as graphite. The backfill can hold the seawater W and can be deformed while holding the seawater W.
In the first embodiment and the second embodiment, the mortar layer 215 may not be provided on the pedestal 210.

  In the second to fourth embodiments, the mortar constituting the mortar layer 71 is generally an inorganic material in which cement, water, and fine aggregate are mixed. In order to flow the current sucked up by the metal plate 20 uniformly, metal fibers or metal powder (carbon black, graphite, coke powder, etc.) may be mixed into the mortar in addition to cement, water, and fine aggregate. By configuring the mortar layer in this way, a current can be passed through the mortar layer even if the wire mesh 70 used in the anticorrosion structure is downsized or the wire mesh 70 is not provided.

In the first to fourth embodiments, the description has been given of the case where the anticorrosion structure is used for the tidal part of the pier column of the pier. However, the cathodic protection structure of the present invention is not limited to a pier, but is a wall-shaped structure that is installed on the quay of a fishing port and formed of reinforced concrete, or a steel pipe or reinforced concrete that is installed in seawater and supports a road or quay. It can be suitably used for the formed columnar structure.
In the first to fourth embodiments, the current generating unit is the sacrificial anode 40, but a battery that generates a direct current may be used as the current generating unit.

In addition, the cathodic protection structure provided with the base body 30 in the first to fourth embodiments can be maintained as follows.
As shown in FIG. 16, an electrode 96 is arranged in a base body 30 holding unillustrated seawater W, and a potential difference between a steel pipe pedestal 210 or a reinforcing bar 232 of the pedestal 230 and the electrode 96 is measured by a voltmeter 97. Measure with
Then, the absolute value of this potential difference is continuously monitored, and when the absolute value becomes smaller than a predetermined reference value, the substrate 30 is replenished between the mortar layer 215 and the metal plate 20, or the substrate 30 is replaced with a new one. Replace it with something.
According to the maintenance method of the cathodic protection structure, the cathodic protection performance can be maintained in a suitable state.

1, 2, 3, 4, 5, 6, 7 Anticorrosion structure 20, 61, 62 Metal plate (conductor)
20a Through hole 30 Base 40 Sacrificial anode (current generation part)
50 Auxiliary metal plate (auxiliary conductor)
56 Side permeable membrane (permeable membrane)
70 Wire mesh (conductor)
80 Makeup mold (conductive plate)
81 Decorative plate (plate material)
82 Extension metal plate (conductor)
71 Mortar layer (base)
210, 230 pedestal (column)
211 Atmosphere (atmosphere range)
212, 235 Tidal range (Tidal range)
220 Support stand L Water surface W Seawater (electrolyzed water)

Claims (9)

An anti-corrosion structure that is formed of steel pipe or reinforced concrete so as to extend in the vertical direction, one end side is placed in the atmosphere and the other end side is placed in the electrolytic water in which the height of the water surface changes periodically. Because
A conductor disposed so as to cover the entire outer peripheral surface of the pillar portion in a tidal range that is a range in which the height of the water surface periodically changes;
The column is filled between the outer peripheral surface of the tidal range and the conductor and deformed in response to a change in the shape of the outer peripheral surface of the tidal range and the conductor while holding the electrolyzed water. A base for maintaining a conductive state between the portion and the conductor;
A current generator that is electrically connected to the steel pipe or the reinforcing steel in the reinforced concrete and is disposed in the electrolytic water and generates a current between the conductor and the electrolytic water;
An anti-corrosion structure characterized by comprising. A support base made of reinforced concrete is attached to the one end of the column part,
The conductor is arranged so as to cover the air range above the tidal range in the column part and the outer peripheral surface of the support base,
The base body is filled between the air range and the outer peripheral surface of the support base and the conductor,
Provided with an auxiliary conductor whose distal end is disposed below the height of the water surface when the water surface is the highest and whose base end is electrically connected to a portion of the conductor covering the outer peripheral surface of the support base. The cathodic protection structure according to claim 1.   The anticorrosion structure according to claim 1 or 2, wherein the lower end portion of the conductor is configured to extend below the lower end portion of the base body.   4. The cathodic protection structure according to claim 3, wherein an insulating member is provided between a portion of the conductor that extends downward from the base body and the column portion. 5.   The second conductor made of a material having a smaller ionization tendency than the conductor is provided at the lower end of the conductor. The described anti-corrosion structure. The conductor is formed integrally with the plate material in a state of being disposed on one surface of the plate material to constitute a conductive plate,
The said anti-corrosion structure as described in any one of Claim 1 to 5 with which the said electrically conductive plate is attached to the said pillar part in the state which has arrange | positioned the said conductor to the said pillar part side. A through-hole is formed below the height of the water surface when the water surface is the highest in the conductor,
The cathodic protection structure according to any one of claims 1 to 6, further comprising a permeable membrane through which the electrolyzed water passes but not through the base so as to cover the through hole.   The said corrosion body is comprised so that the said pillar part may be approached as it goes below, The anticorrosion structure as described in any one of Claim 1 to 7 characterized by the above-mentioned. An anti-corrosion structure that is formed of steel or reinforced concrete so as to extend in the vertical direction, one end side is placed in the atmosphere and the other end side is placed in the electrolytic water in which the height of the water surface changes periodically. A forming method of
Forming a conductor so as to cover the entire outer peripheral surface of the pillar portion in a tidal range where the height of the water surface changes periodically;
Filling a base between the outer peripheral surface of the tidal range and the conductor;
By deforming the base body holding the electrolyzed water corresponding to the outer peripheral surface of the tidal range and the shape of the conductor, the conduction state between the pillar portion and the conductor is maintained,
A current generating part electrically connected to a reinforcing bar in the steel or the reinforced concrete is disposed in the electrolytic water, and a current is generated between the current generating part and the conductor through the electrolytic water. A method for forming an anticorrosion structure.

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