PL226794B1 - Method and system for cathodic protection of an object - Google Patents

Description

Description of the invention

The subject of the invention is a method and system for cathodic protection of an object. It is used wherever underground objects, e.g. metal tanks, pipelines are exposed to corrosion, which shortens their service life, and therefore should be equipped with an anticorrosive electrochemical protection system.

In the known typical solutions, the electrolytic cathodic protection systems contain an anode placed near the protected metal object and biased by an external source of direct current or voltage. This source is connected between the anode and the protected object, creating the basic protection current circuit between the cathode, which is protected by the metal structure, and the anode. With the help of an external source, a specific electric potential of the protected object is determined, thanks to which oxidation, i.e. metal corrosion, does not occur in such a system. The electrolytic cathodic protection systems are also equipped with a measuring electrode, which is the reference electrode, which is used to carry out measurements on the basis of which the protection effectiveness is assessed. In the known solutions, measurements of protection parameters are performed periodically by temporarily switching off the cathodic protection current and measuring the value of the tank potential with respect to the reference electrode. The value of the object protection potential measured in this way is compared with the standard requirements, which allows for the assessment of the effectiveness of the anti-corrosion protection. In the simplest systems, measurements of protection parameters are performed at specified intervals by the operator. There are also many systems equipped with programmed drivers, e.g. microcontrollers, by means of which the key is automatically controlled and cyclically disconnects the polarization current. Advanced systems are additionally equipped with various types of systems and elements that allow for automatic measurements and processing of their results, which allows the assessment of the quality of protection. There is known from the European patent application published under the number EP 2655690 a method and a cathodic protection system, in which a protected metal structure in the form of a tube is connected with a system including a DC source and an anode and a monitoring apparatus. The monitoring apparatus has a central station located on the surface adjacent to the source of electrode polarization and a tool placed inside the tube. The central station contains a processor, memory and a bias current meter, as well as a meter that allows you to measure the potential difference between the protected object and the test location where the structure serving as the reference electrode is located. The solution is used to assess the effectiveness of protection by measuring the protection potential. In various variants and variants of the solution, means are provided for measuring the potential of the protected structure with respect to the potential of the environment at different distances from the connection point of the pipe to the current source, and means for transmitting data and signals.

Electrochemical cathodic protection is effective if the protection potential is within the corrosion resistance range established for a given circuit. In known electrochemical cathodic protection systems for objects located in the ground, voltage sources with a constant object protection potential or current sources with a constant object polarization current are used as the polarization sources. Thus, such systems implement two different methods of cathodic protection: one is to maintain a constant protection potential, and the other is to provide a constant bias current. In the protection methods with a constant potential, the problem is sudden, very fast and large changes in the value of the bias current caused by changing protection conditions and disturbances, which causes instability of the devices. Devices used in the protection method with a constant polarization current are stable, but do not react to changes in the protection potential caused by changes in the protection conditions, caused by e.g. weather changes (rainfall, snowfall, drought, soil freezing, etc.). Then the protection potential is changed and may be outside the corrosion resistance range: if the set polarization current is too high there is an unfavorable over-protection, and if the polarization current is too low - insufficient protection.

The method of cathodic protection of an object consisting in inducing the desired chemical reactions on the surface of the object by connecting it in a system equipped with a microcontroller with an anode placed in its vicinity through a current source polarizing the anode and measuring the current protection parameters according to the invention at predetermined time intervals. of the microcontroller, the set value of the nominal bias current coming from the current source and its limit values as well as the value of the nominal protection potential are entered, and then the instantaneous values of the current protection potential and the current polarization current are measured and are also entered into the microcontroller, where they are

The processing and comparison with the given values of the nominal object protection potential and the nominal bias current, as a result of which a control signal is generated and output from the microcontroller to the current source, by means of which the value of the current bias current is changed.

The cathodic protection is activated by setting as the initial value the value of the nominal polarization current, and after detecting the difference between the current protection potential and the nominal protection potential value, the current polarization current is changed until one of its fixed limits is reached, and this limit is maintained until the current bias current must be changed to obtain the nominal protection potential.

The cathodic protection system of the object having an anode connected to the object via a current source, a current-voltage converter and a disconnecting key and a measuring electrode, and comprising a microcontroller with a communication interface and an indicator connected to it, and equipped with known power supply units according to the invention, is characterized in that between the object and the measuring electrode, a differential amplifier is switched on, the output of which is connected to an analog-to-digital converter in the microcontroller, to which the output of the current-voltage converter is also connected, and the output of the microcontroller is connected to the current source, while its input is connected to the programming block.

The advantage of the solution according to the invention is that the current protection potential is kept within the corrosion resistance range, irrespective of changes in environmental conditions.

The invention is explained in more detail by means of the illustrated drawing, in which Fig. 1 shows a block diagram of the circuit, Fig. 2 - time diagrams of the current protection potential and current polarization current in the solution according to the invention, and Fig. 3 - corresponding time diagrams for cathodic protection systems without current source control.

The method of cathodic protection of the object in the exemplary implementation consists in automatic, on-going, adjustment of the value of the current polarization current I, depending on the results of current measurements of protection parameters. The cathodic protection system includes: current source 1, current-to-voltage converter 2, disconnecting key 3, differential amplifier 4, microcontroller 5 with analog-to-digital converter, programming block 6, indicator 7, communication interface 8, internal power supply 9, object 10 as cathode , measuring electrode 11, anode 12, external power supply 13 and external communication device 14. Before starting the system, the following data is entered into the non-volatile memory of microcontroller 5 by means of programming block 6: nominal value of protection potential EN, nominal value of polarization current IN and limit current values polarization - minimum polarization current Imin, maximum polarization current Imax. The nominal value of the polarization current is in the range between its minimum and maximum value. The protection system is activated by setting its nominal value IN as the polarization current. During the system operation, the current value of the polarization current I is measured using an analog-to-digital converter in the microcontroller. object 10 and measuring electrode 11. All measured values are converted into digital signals and processed in the microcontroller 5. If the value of the current protection potential E is different from the nominal value of the protection potential EN, an output signal is generated from the programmed microcontroller and given as a control signal to current source 1, which changes the value of the current supplied by the current source so that the difference between the current protection potential E and the nominal protection potential EN is close to zero. The microcontroller 5 is programmed to regulate the value of the bias current of the current source in an integral-proportionate manner. When the current from current source 1 increases and reaches a value equal to the set maximum value lmax, further current increase is stopped, current source 1 sets the bias current to the maximum value of Imax and maintains this value until a lower bias current value is required to reach nominal protection potential EN. When the bias current from the current source decreases and its present value I reaches the preset minimum value Imin, further reduction of the current is stopped, current source 1 sets the present value of the bias current I to the minimum value of Imin and maintains it until the higher value the bias current is required to achieve the rated EN protection potential. As shown in the graphs in Fig. 2, illustrating the exemplary waveforms of the polarization current and the protection potential, when the value of the current polarization current I is regulated by the method according to the invention and changes within the assumed limits between the adopted limit values: minimum polarization current Imin and maximum polarization current Imax , the current protection potential of E essentially

PL 226 794 B1 is within the corrosion resistance range defined by the limits E1, E2. The exceptions are momentary disturbances at moments t1, t2, short interval t3-t4 and t5-t6. A comparison of similar waveforms without current source control, i.e. when the current bias current I is constant, shown for the illustration in Fig. 4, clearly shows much longer time periods when the current protection potential is outside the corrosion resistance range.

In the exemplary embodiment shown in Fig. 1, the system according to the invention has a current source 1 connected on the one hand to the anode 12 and on the other hand, via a current-voltage converter 2 and a disconnecting key 3, to the object 1, which is a cathode in the cathodic protection system. also including measuring electrode 11. Differential amplifier 4 is connected between object 10 and measuring electrode 11. The outputs of the current-voltage converter 2 and the differential amplifier 4 are connected to the analog-to-digital converter in the microcontroller 5, one of the outputs of which is connected to the disconnecting key 3 and the other output is connected to the current source 1. The microcontroller 5 is also connected to the programming block 6, the signaling device 7 and via the communication interface 8 to the external communication device 14. The system also includes an internal power supply 9 supplying DC voltage necessary to power the individual blocks, which it is connected with an external power supply 13. Sign The alizer 7 and the communication device 14 may constitute any device, advantageous and required for a specific application, by means of which the object protection status parameters can be signaled and transmitted.

In the system, the polarization current flowing from the current source 1 to the protected object 10 is introduced to the current-voltage converter 2 and further interrupted by the disconnecting key 3 controlled by the signal from the microcontroller 5. The value of the current polarization current I is measured by the analog-to-digital converter in the microcontroller 5, by means of which, at the output of the differential amplifier 4, at the moment of disconnecting the polarization current, the value of the current protection potential E is also measured as the potential difference between the object 1 and the measuring electrode 11. Based on the data entered using the programming block 6 and the results of current measurements in the microcontroller data is processed according to a predetermined algorithm and control signals are generated to the disconnecting key 3 and to the current source 1. The current source 1 is regulated in such a way that the difference between the current protection potential E and the nominal protection potential EN is close to zero.

The solution according to the invention allows to minimize the impact of disturbances and changes in protection conditions on the stability of the cathodic protection system.

Claims (3)

1. Method of cathodic protection of an object consisting in inducing the desired chemical reactions on the object's surface by connecting it in a system equipped with a microcontroller, with an anode placed in its vicinity, via a current source polarizing the anode and measuring the current protection parameters at predetermined intervals, characterized by: that the set value of the nominal bias current (IN) from the current source (1) and its limit values as well as the value of the nominal protection potential (EN) are introduced into the microcontroller (5), and then the instantaneous values of the current protection potential (E) are measured and current polarization current (I) and is also introduced into the microcontroller (5), where they are processed and compared with the set values of the nominal object protection potential (EN) and the nominal polarization current (IN), resulting in the generation and output of the microcontroller ( 5) to the current source (1) the control signal, using which the value of the current polarization current (I) changes. 2. The method according to p. The method of claim 1, characterized in that the cathodic protection is activated by setting the value of the nominal polarization current (IN) as the initial value, and after detecting the difference between the current protection potential (E) and the value of the nominal protection potential (EN), the current polarization current (I) is changed to one of its predefined limits is reached, and this limit is maintained until a change in the current polarization current (I) is required to obtain the rated protective potential (EN). 3. Object cathodic protection system having an anode connected to the object via a current source, a current-voltage converter and a disconnecting key, and a measuring electrode and containing a microcontroller with a communication interface and signaling device connected to it, and equipped with known power supply blocks, characterized in that between In the object (10) and measuring electrode (11), a differential amplifier (4) is connected, the output of which is connected to an analog-to-digital converter in the microcontroller (5), to which the output of the current-voltage converter (2) is also connected. , and the output of the microcontroller (5) is connected to the current source (1), while its input is connected to the programming block (6).