RU2713898C1 - Device for cathodic protection with autonomous power supply - Google Patents

Abstract

FIELD: technological processes; electrical engineering.

SUBSTANCE: invention relates to electrochemical protection of metal structures from corrosion and can be used in corrosion-active electrolytic media, particularly in marine environment. Device comprises a solar battery, a comparison electrode, an electromagnetic circuit breaker, an electrical current conversion system, wherein it contains insoluble anode and electrical measuring devices in the form of potentiometer and ammeter, electric current conversion system is made in form of pulse DC converter, wherein the solar battery outputs are connected to the DC pulse inverter supply inputs, the electromagnetic circuit breaker coil power supply is made from the DC pulse converter, the negative output of the DC converter is electrically connected to the protected structure, and the positive output is connected to the insoluble anode through the switching contact of the electromagnetic circuit breaker, the ammeter is installed in the power supply circuit breakthrough of the insoluble anode, the potentiometer is connected to the comparison electrode by one clamp, and the other clamp is connected to the protected structure.

EFFECT: simplifying the cathodic protection device, improving the reliability of electrochemical protection of metal structures, eliminating the need for continuous operation of the cathode protection.

3 cl, 2 dwg

Description

The invention relates to the field of electrochemical protection of marine and other metal structures from corrosion located in corrosive electrolytic environments with rigidity due to the content of calcium and magnesium.

For example, there is a known system for cathodic protection (PM RF No. 114055 U1, IPC C23F 13/02, publication PM 10.03.2012), which assumes that tread protection is included in the simultaneous absence of renewable energy sources (wind generator, solar panel or battery) . This system allows continuous protection of metal structures from corrosion. Its disadvantages include greater complexity and relatively high cost of implementation, since it contains many different types of sources of electrical energy and devices to maintain the required operating modes, and tread materials, as is known, are intensively destroyed during operation and therefore require periodic replacement.

It is known, for example, a device for cathodic protection with autonomous power supply, adopted as a prototype (RF patent No. 2486289 C2, IPC C23F 13/02, publication of the patent 06/27/2013) containing a wind generator, a battery, a pulse amplitude generating unit, an anode ground electrode and a reference electrode connected to the first input of this unit of formation of the amplitude of the pulses. At the same time, a protector, an isolator, a resistor, a reserve control unit with two outputs and a data exchange port, a solar battery, first and second decoupling diodes, and a battery charge current limitation controller are introduced into this device. This device allows continuous protection of metal structures from corrosion. In the absence of electricity from a renewable energy source (wind generator, solar panel, etc.), the energy stored in the battery is used during the operation of the renewable energy source (in windy weather or during daylight, etc.).

This device has the following disadvantages. The presence of a battery to ensure the continuity of the cathodic protection process of a structure leads to an increase in the cost of this device (since the cost of the battery is comparable to or exceeds the cost of solar panels) and to a decrease in the duration of its work on cathodic protection (since the battery life is several times lower than the life of solar panels, and therefore the battery requires periodic replacement), which ultimately reduces the reliability of the cathodic protection as a whole (since for reliable battery operation in the electrical system anija requires an additional device (controller) regulates the current in the battery charge and discharge process).

The technical problem to be solved by the claimed invention is directed, is to eliminate these disadvantages, namely: reducing the cost of equipment of the device, simplifying its design, as well as improving reliability.

This object is achieved in that in the known device for cathodic protection with autonomous power supply containing a solar battery, a reference electrode, an electromagnetic circuit breaker, an electric current conversion system, in contrast to the claimed device for cathodic protection with autonomous power, the electric current conversion system is made in in the form of a pulsed DC-DC converter (IPPT). Also, an insoluble anode and electrical measuring instruments in the form of a potentiometer and ammeter are introduced into the device. In this case, the conclusions of the solar battery are connected to the supply inputs of a pulsed DC / DC converter. The power supply of the electromagnetic breaker coil is made from a pulsed DC / DC converter; its negative output is electrically connected to the protected structure, and the positive output is connected to the insoluble anode through the switching contact of the electromagnetic breaker. The ammeter is installed in the open circuit of the insoluble anode. The potentiometer is connected by one clamp to the reference electrode, and the other clamp is connected to the protected structure. In a particular case, the relay-disconnector is made according to type SRD-03VDC-SL-C, and the solar panel is made according to type SDM-500.

Due to the fact that the proposed device for cathodic protection does not have a battery, a wind generator, a battery charge controller, a protector, a reserve control unit and a pulse amplitude generating unit, a significant reduction in the cost of the device’s equipment is achieved, as well as a simplification of its design.

Thus, due to the fact that in the proposed device protection against corrosion in the dark provides cathode deposit and only one source of electricity is used, it contains fewer elements compared to the prototype and therefore has a simpler design and lower cost. In addition, due to the fact that the proposed device contains fewer elements, it is characterized by greater reliability, durability and virtually no maintenance, which is an additional advantage of the claimed invention.

The invention is illustrated in FIG. 1 and FIG. 2. In FIG. 1 shows a self-powered cathodic protection circuit. In FIG. Figure 2 shows a photograph of cathodic protected samples and control samples.

The inventive device for cathodic protection with autonomous power supply (Fig. 1) contains a solar panel (1), a pulsed DC / DC converter (IPPT) (2) with an adjustable output, providing the necessary protective current, a relay-disconnector (3) of the circuit "insoluble anode - protected object ", insoluble anode (4) and reference electrode (5). The negative terminal of the solar panel (1) is connected to the negative input of the IPPT (2), and the positive terminal of the solar panel (1) is connected to the positive input of the IPPT (2). The minus from the output of the IPPT (2) is connected to the protected structure (6), and the plus to the switching contact of the relay-disconnector (3). The insoluble anode (4) is connected to the normally open contact of the relay-disconnector (3), the coil of which is connected to the output of the IPPT (2). The IPPT (2) itself is made on semiconductor elements and serves to control the output voltage and, therefore, the output current.

The cathodic potential U _{to is} controlled by connecting a measuring device (7) between the protected structure (6) and the reference electrode (5), and the protective current I _zash - by connecting an ammeter (8) to the circuit break "normally open contact of the relay-disconnector (3) is insoluble anode (4). "

The formation and regulation of the thickness of this precipitate and its protective properties is carried out using IPPT (2), which regulate the output voltage and, accordingly, the output current of the solar panel during its operation. Moreover, it is known that the solar panel has properties close to the properties of the current source

The solar panel (1) serves as the primary power source for the cathodic protection circuit. As is known, the output voltage and current of the solar panel (1) are absent in the dark, and in daylight they can vary over a fairly wide range, which is unacceptable for powering the cathodic protection circuit. Therefore, to ensure the required value of the output voltage and current of the primary power source of the circuit, which is necessary for effective cathodic protection, an IPPT (2) is connected to the output of the solar panel (1). This IPPT (2) can be equipped with a remote regulator of the output voltage and current (not shown).

The circuit breaker (3) performs the function of mechanically turning on the current supply for cathodic protection when there is sufficient illumination of the solar panel (1) and disconnecting the circuit "anode (4) - protected building (6)", thereby preventing reverse galvanic current from flowing arising between the protected structure (6) and the anode (4) after the termination of the solar panel (1) due to the lack of sunlight.

As a relay-disconnector (3), various circuitry solutions can be selected using low-voltage (of the order of 2 V) relays: a) relays that trigger to turn on (turn off) when the specified coil voltage is reached (lower); b) programmable relays; c) relays controlled by a photosensitive element (photodiode, photoresistor).

The inventive device for cathodic protection with self-contained power is used as follows. In the daytime, the required output voltage and current of the IPPT are set (2), this voltage and current are supplied to the power coil of the relay-disconnector (3). When this relay-breaker is activated, its switching contact closes, thereby connecting the insoluble anode (4) to the positive output of the IPPT (2). On the surface of the protected structure (6), under the influence of the flowing current generated by the solar panel (1), a cathode deposit is formed, which consists mainly of calcium carbonate and magnesium hydroxide [C. Rousseau, F. Baraud, L. Leleyter, M. Jeannin, O. Gil. Calcareous deposit formed under cathodic protection in the presence of natural marine sediments: A 12 month experiment. - Corrosion Science, 52 (2010), 2206-2218; Ph. Refait, M. Jeannin, R. Sabot, H. Antony, S. Pineau. Electrochemical formation and transformation of corrosion products on carbon steel under cathodic protection in seawater. - Corrosion Science, 71 (2013), 32-36]. This poorly soluble precipitate protects the metal from corrosion in the dark by isolating the metal from the corrosive medium, and, dissolving, changes the composition of the corrosive medium near the protected metal in the direction of reducing its corrosiveness.

Thus, during the work of the solar panel (1) in the daytime due to the current generated by it, a coating (9) is formed on the surface of the protected structure (6) in the form of a formed cathode deposit. And in the dark, in the absence of sunlight and, accordingly, protective current, the protection of the structure (6) from corrosion is ensured by this formed cathode deposit.

To prove the operability of the claimed device, corrosion tests of low alloy steel samples (Fig. 2) in natural sea water of Fedorov Bay in Vladivostok were carried out. On the left are samples under cathodic protection, and on the right are control samples. To convince the effectiveness of such protection, tests were deliberately carried out in the winter, when the daylight hours are minimal. The use of the device allowed to reduce the corrosion rate of steel samples up to 20 times, which was a confirmation of the health and effectiveness of the claimed invention.

Claims (3)

1. A self-powered device for the cathodic protection of a metal structure, containing a solar battery, a reference electrode, an electromagnetic circuit breaker, an electric current conversion system, characterized in that it contains an insoluble anode and electrical measuring instruments in the form of a potentiometer and ammeter, the electric current conversion system is made in in the form of a pulsed DC-DC converter, while the conclusions of the solar battery are connected to the power inputs of a pulsed DC-converter current, the power supply of the coil of the electromagnetic breaker is made from a pulsed DC-DC converter, its negative output is electrically connected to the protected structure, and the positive output is connected to the insoluble anode through the switching contact of the electromagnetic breaker, the ammeter is installed in the open circuit of the insoluble anode, the potentiometer is connected to the electrode with one clamp comparison, and another clamp is connected to the protected structure. 2. The device according to p. 1, characterized in that the relay-disconnector is made according to type SRD-03VDC-SL-C. 3. The device according to p. 1, characterized in that the solar panel is made according to type SDM-500.

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