JPS62116790A - Electrolytic corrosion preventive device - Google Patents

Abstract

PURPOSE:To economically prevent the corrosion of a metallic body to be protected for a long period of time by connecting an electrode via a solar battery and galvanic anode via a diode in parallel to the body to be protected. CONSTITUTION:The electrode 3 is connected via the solar battery 2a to an embedded steel pipe 1 as the body to be protected. The galvanic anode 4 is connected via the diode 6 in parallel to the above-mentioned solar battery 2a and the electrode 3. The current generated in the solar battery 2a in the daytime in the above-mentioned constitution flows to as to flow out to the ground 5 through the electrode 3, to flow into the pipe 1 and to return to the battery 2a, thereby protecting the pipe 1. No current is generated from the battery 2a at night and the current between the anode 4 and the pipe 1 is generated. Such current flows into the surface of the pipe 1 to prevent corrosion.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a cathodic protection device using a solar cell as a power source, and particularly to a cathodic protection device using a solar cell and a galvanic anode in combination.

[Conventional technology]

Conventionally, as this type of cathodic protection device, a device in which the anode of a solar cell is directly connected to an insoluble electrode and the cathode is connected to an object to be protected against corrosion has been disclosed.

(For example, Japanese Utility Model Publication No. 47-39459) Furthermore, a device is disclosed in which the anode of a solar cell is connected to an insoluble electrode through the positive terminal of a battery, and the cathode is connected to an object to be protected through the negative terminal of the battery. ing.

That is, the current generated by the electromotive force of the solar cell is temporarily stored in a battery, and the output current of this battery flows into the object to be protected as a corrosion protection current through an insoluble electrode, thereby achieving corrosion protection. (For example, Japanese Utility Model Application Publication No. 57-125771) [Problems to be Solved by the Invention] In the above-mentioned conventional cathodic protection equipment using a solar cell as a power source, the former equipment is difficult to operate on rainy or cloudy days. At present, it has not been put into practical use because there is a risk that it may not be able to generate an anti-corrosion current, especially at night, which is a fatal problem.

On the other hand, the latter device temporarily stores the current generated by the solar cell in the battery and then uses it as the anti-corrosion current, so it has the advantage of being able to supply the anti-corrosion current even when there is no current generated by the solar cell, such as at night. With this method of using a battery, the life of the battery is short, less than a few years, so if the battery is to be energized for a long period of time, such as in cathodic protection equipment, it must be replaced with a new one every time the battery life runs out. , the cost of replacement would be enormous.

In addition, there were various problems both economically and technically, such as the need for maintenance and inspection at least several times a year to maintain the battery in good condition. It is an object of the present invention to provide a cathodic protection device which can eliminate the above-mentioned problems of cathodic protection devices using batteries as a power source and can prevent metal corrosion over a long period of time.

[Means for solving problems]

In order to achieve this object, the present invention has the following configuration.

That is, the electrolytic protection device according to the first invention is constructed by connecting an electrode via a solar cell and a galvanic anode via a diode in parallel to the object to be protected.

Further, the electrolytic corrosion protection device according to the second invention is configured by connecting an electrode via a solar cell and a galvanic anode via a switch element to the object to be protected in parallel.

[For production]

Next, the operation of the cathodic protection device configured as described above will be explained.

(Function 1) In a cathodic protection device configured by connecting an electrode via a solar cell and a galvanic anode via a diode in parallel to the object to be protected, during the daytime irradiation of sunlight, the solar cell The generated current flows from the electrode through the electrolyte into the object to be protected from corrosion, thereby protecting the object from corrosion.

In this case, the potential of the object to be protected is polarized in the base direction and approaches the potential of the galvanic anode, and the potential difference between the galvanic anode and the object to be protected becomes small, so during the daytime when the solar cells generate current, ,
Current generation from the galvanic anode is small.

On the other hand, at night when the solar cells do not generate current, the object to be protected from corrosion is protected from corrosion by the current generated by the potential difference between the galvanic anode and the object to be protected.

In this case, the diode inserted between the galvanic anode and the object to be protected is such that the electric potential of the object is lower than that of the galvanic anode, and the current from the solar cell is directed only to the object to be protected. It also prevents current from flowing into the galvanic anode, and serves to prevent alkali corrosion caused by current flowing into the galvanic anode.

(Effect 2) In a cathodic protection device configured by connecting in parallel an electrode via a solar cell and a galvanic anode via a switch element to the object to be protected, during the daytime irradiation with sunlight, the The object to be corroded is protected from corrosion by the current generated by the battery.

While the solar cell is generating current, the switching element is configured to open the circuit, so that the galvanic anode does not generate current and no current from the solar cell flows into the galvanic anode.

Next, when the solar cell does not generate current at night, the switch element closes the circuit, so current flows from the current anode to protect the object from corrosion.

〔Example〕

This description will be made below based on the embodiments shown in the drawings.

Fig. C is an explanatory diagram showing one embodiment of the first invention. In this figure, a steel pipe of
a) and electrode (3) in parallel.

When the cathodic protection device is configured as described above, when the solar cell generates current during the day, the current flows from the anode of the solar cell (2a) to the earth (5) via the electrode (3),
) and flows back to the cathode of the solar cell (2a) to protect the steel pipe (1) from corrosion.

At this time, the ground potential of the steel pipe +1) shifts to a less noble direction, and the potential difference with the galvanic anode (4) becomes smaller.
The generated current in 4) is small.

In addition, at night, when the solar cell (2a) does not generate current, a current is generated between the galvanic anode (4) and the steel pipe (1), flows into the surface of the steel pipe (1), and protects it from corrosion. do.

The diode (6) indicates that the potential of the steel pipe (1) is the galvanic anode (
4), or prevents current from flowing into the galvanic anode (4), which occurs when the value is the same as that of the galvanic anode (4) or less than the galvanic anode (4).

FIG. 2 is an explanatory diagram showing one embodiment of the second invention.

In this figure, the same reference numerals as in FIG. 1 are used except for the solar cell (2b), the gate turn-off resistor (7), and the resistors (8a) and (8b).

In parallel with the solar cell (2a) and the electrode (3) connected to this solar cell, a galvanic anode (4) is connected to the steel pipe (1
)It is connected to the.

With such a configuration, during the daytime when the solar cell generates current, the steel pipe t1) is protected from corrosion by the current from the solar cell (2a) flowing out from the electrode (3).

At this time, the solar cell in (2b) also generates current (8b)
Since the off-gate current flows through the gate of the gate turn-off thyristor (7) through the resistor, the gate turn-off thyristor (7) is in the off state, and the current anode (4)
(11 steel pipes or solar cells (2a) and electrodes (3)
) and are insulated.

Therefore, during the day when the solar cells generate current, the current positive i (4
) no current is generated.

Next, when there is no sunlight irradiation at night, the solar cell in (2b) also does not generate current, so no off-gate current flows through the gate of the gate turn-off risk in (7).
Due to the potential difference between the galvanic anode (4) and the steel pipe (1), (
7) Gate turn-off resistor (8) to the gate of the risk
Since the on-gate current flows through a) and conducts the gate turn-off switch (7), a corrosion protection circuit is formed in the galvanic anode, and the current from the galvanic anode (4) flows into the steel pipe (1). It flows in and protects this steel pipe from corrosion.

FIG. 3 shows another embodiment of the second invention.

In this figure, the electrostatic induction sirisk of (9) and (8
Components other than the resistor c) are given the same reference numerals as in FIGS. 1 and 2.

The operation of the cathodic protection circuit in the embodiment shown in this figure is as follows:
This is the same as the case in FIG.

However, in this figure, an electrostatic induction thyristor (9) is used instead of the gate turn-off thyristor of FIG. 2.

When the solar cell (2b) generates a current during the day, an off-gate current flows through the resistor (8c) to the gate of the electrostatic induction silisk (9). The induction cyrisk is in an off state, and the galvanic anode (4) is insulated from the steel pipe (1) or the solar cell and electrode (3) (2a).

Therefore, during the day when the solar cells generate current, the galvanic anode (4
) there is no current generation.

In addition to the above, a commutating turn-off type thyristor may be used as the reverse blocking three-terminal thyristor used in the second invention.

Switch elements using these reverse-blocking three-terminal switches are non-contact switches, so there is no need to worry about the contacts deteriorating (and because they do not require special maintenance during use, they can withstand long-term use.

FIGS. 5 and 6 are explanatory diagrams showing still another embodiment of the second invention.

In the embodiment shown in FIG. 5, a solar cell (2a) and a galvanic anode (4) connected to the solar cell in parallel with the electrode (3) are connected to a steel pipe via an electromagnetic relay Ql as a switch element. (1).

With this configuration, the steel pipe (1) is protected from corrosion by the current from the solar cell (2a) flowing out from the electrode (3) during the daytime when the solar cell generates current.

At this time, the current of the solar cell (2a) is
The current is also shunted to the coil (10a), and the b contact is opened. (
A B contact is a contact that opens a circuit when current flows through the coil of an electromagnetic relay. ) When the b contact is opened, the galvanic anode (4) becomes insulated from the +1) steel pipe or solar cell (2a) and the electrode (3).

Therefore, during the day when the solar cell generates current, the galvanic anode (4
) no current is generated.

Next, when there is no sunlight irradiation at night, solar cells (2a
) does not generate current, so the coil of electromagnetic relay aω (
Since no current flows in 10a), the b contact (10b) is closed and the galvanic anode (4) is connected to the steel pipe (1), and the current flowing from the galvanic anode (41) protects the steel pipe (1) from corrosion. Ru.

Figure 6 shows that the electromagnetic relay as a switching element opens and closes the B contact of the electromagnetic relay not by the current of the solar cell (2a) for cathodic protection, but by separately providing a solar cell (2b) dedicated to driving the electromagnetic relay. This figure shows an embodiment configured as follows.

The operation of the cathodic protection circuit according to the embodiment shown in FIG. 6 is similar to that shown in FIG.

Further, in order to reduce the contact resistance of the contacts, a plurality of electromagnetic relays used in the second invention can be connected in parallel.

The electrodes used in the first and second inventions include insoluble electrodes such as magnetic iron oxide electrodes, ferrite electrodes, platinum-titanium electrodes, platinum-tantalum electrodes, platinum-niobium electrodes, and graphite electrodes, or steel or copper alloys. It is possible to use a completely melted electrode such as the above, or an electrode made of a conductive resin.

In addition, the galvanic anodes used in this invention include magnesium alloy molten metal, aluminum alloy anodes, zinc anodes, etc., but these galvanic anodes are Additionally, the shape can be made larger, or a plurality of the same shape can be connected in parallel.

〔Effect of the invention〕

As explained above, in this invention, since the electrode through the solar cell and the galvanic anode are connected in parallel to the object to be protected, during the day when the solar cell receives sunlight, the current generated by the solar cell The object to be protected can be protected from corrosion, and at night when there is no sunlight, the electric current generated from the galvanic anode can
The object to be protected from corrosion can be protected from corrosion.

Further, in this invention, the current WA electrode is connected to the electrode and the object to be protected via the solar cell through a switch element whose circuit is open when the diode or the solar cell is generating current. Therefore, the current from the solar cell flows only into the object to be protected and does not flow into the galvanic anode.

Therefore, the galvanic anode does not cause alkaline corrosion due to current flow.

Furthermore, in this invention, the galvanic anode is connected to the object to be corroded via a switch element driven by a solar cell, and when the solar cell generates a current, the switch element operates to open a circuit. During the daytime, when the object to be protected is protected from corrosion by the current generated by the solar cell, no current is generated from the galvanic anode, and at night, only when there is no current generated by the solar cell, the switch element closes the circuit, and the galvanic current 1 The corrosion protector is connected to the object to be protected, and a corrosion protection current is caused to flow into the object from the galvanic anode.

Therefore, the galvanic anode has little wear and tear and can be used together with the solar cell for a long period of time to protect the object to be protected from corrosion.

Since the galvanic anode continues to generate a predetermined current after being installed, according to this invention, the object to be corroded can be protected from corrosion for a long period of time without special maintenance. .

As explained above, the present invention greatly contributes to the corrosion prevention of metals.

1. person / ji mortar

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram showing one embodiment of the first invention. FIG. 2 is an explanatory diagram showing an embodiment of the second invention. FIG. 3 is an explanatory diagram showing another embodiment of the second invention. FIGS. 4 and 5 are explanatory diagrams showing still another embodiment of the second invention.

Claims (1)

[Claims] 1. An electrolytic protection device characterized in that an electrode via a solar cell and a galvanic anode via a diode are connected in parallel to an object to be protected. 2. An electrolytic protection device characterized in that an electrode via a solar cell and a galvanic anode via a switch element are connected in parallel to the object to be protected. 3. The cathodic protection device according to claim 2, wherein the switch element is a reverse blocking three-terminal thyristor operated by a solar cell. 4. The cathodic protection device according to claim 2, wherein the switch element is an electromagnetic relay having a b contact driven by a current generated by a solar cell.