RU140224U1 - SOURCE OF ELECTRICAL SUPPLY OF THE REMOTE CATHODIC PROTECTION STATION (OPTIONS) - Google Patents

Abstract

1. The power source of the remote cathodic protection station, characterized in that it is made in the form of a single-wire resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the consumed current, an increased frequency generator, a resonant transformer with a capacitor and an earthing switch, connected by a single-wire power line with a reverse transducer, including a step-down resonant transformer with an earthing switch and a rectifier with a corrector of the shape of the current consumption, at In this case, the power source is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the boost resonant transformer through a capacitor, one output of the output winding of the boost resonant transformer is connected to the ground electrode, and the second output of the output winding of the boost resonant transformer is connected by a single-wire power line with the output winding of the step-down resonant transformer, the second output of the input winding is connected to mlitelem, lowering the resonant transformer winding coupled to a rectifier, the output of which is configured to connect with equipment cathodic protection station, protected against corrosion electroconductive anode structure and deep zazemleniem.2. The power supply source of a remote cathodic protection station, characterized in that it is made in the form of a resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the current consumption, an increased frequency generator that increases resonance�

Description

The utility model relates to electric power transmission systems and electrochemical protection devices for pipelines and steel structures.

From RU No. 2161663 dated January 10, 2001, a power supply system for cathodic protection stations of trunk pipelines is known, which consists of a high-voltage compartment containing a high-voltage disconnector from a power line with a blocked grounding knife and a dry power transformer, as well as high-voltage fuses, valve arresters from lightning overvoltages and bushing insulators and a low-voltage compartment, powered by a dry power transformer, in which a guaranteed power source with a step-down transformer is located rum.

Closest to the proposed utility model is the source of network power, disclosed in RF patent No. 87425 of 10.10.2009 which contains a measuring shunt, a power filter, a filter unit, while the input of the network power source is connected to current transformers.

The disadvantages of the known power sources of the remote cathodic protection stations are the need to bring a high-voltage power line to the installation site of the remote cathodic protection station, then converting the high voltage to low 220/380 V, then converting it to low voltage supplied to the electrodes through an automation system. The disadvantages noted above lead to significant economic costs in the construction and operation of remote cathodic protection stations.

The objective of the proposed utility model is to simplify the power supply devices of remote cathodic protection stations, to eliminate intermediate voltage conversions and to reduce the overall dimensions of the station.

To reduce the overall dimensions of the power supply devices, a resonant electric power transmission system was developed comprising an increased frequency generator, voltage converter, increasing the resonant circuit, single-wire power line, lowering the resonant circuit (RF patent No. 2423772, published July 10, 2011 Bull. No. 19) Single-wire operation The resonant electric energy transmission system is based on the use of two resonant circuits with a frequency of 0.5-50 kHz and a single-wire line between circuits with a voltage of l lines 0.7-100 kV when operating in the mode of voltage resonance. The line wire is a guide channel along which electromagnetic energy moves.

This ensures the transmission of electric energy over long distances without the use of intermediate transformer substations, the reduction of losses in the line during transmission of electricity, the absence of a short circuit in the wires, including the elimination of accidents on the line associated with dangerous weather events (strong wind, ice, etc. )

As a result of the use of the proposed utility model, the design of power supply sources is simplified in which the voltage of a resonant single-wire transmission line is converted to the required voltage of 10 ... 100 V DC, for the operation of the internal equipment of the cathodic protection station, consisting of: an information measuring and processing unit and a power unit without using nodes and blocks of standard systems of transformation and transmission of electricity operating at an industrial frequency of 50 Hz.

The above technical result is achieved by the fact that the proposed power supply source of the remote cathodic protection station is made in the form of a single-wire resonant power transmission system, including a power source, a rectifier with a current shape corrector, an increased frequency generator that boosts a resonant transformer with a capacitor and an earthing switch connected by a single-wire power line with a inverter including a step-down resonant transformer with an earthing switch and straighten l with a corrector of the shape of the consumed current, while the power source is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the boost resonant transformer through a capacitor, one output terminal of the output winding of the boost resonant transformer is connected to the ground electrode, and the second output terminal windings of the step-up resonant transformer is connected by a single-wire power line to the output from the input winding of the step-down resonant transformer a, the second output terminal of the input winding is connected to the ground electrode, the lowering winding of the resonant transformer is connected to the rectifier, the output of which is configured to connect to the equipment of the cathodic protection station, with an electrically conductive structure protected from corrosion and deep anode grounding.

In another embodiment, the technical result is achieved by the fact that the proposed power source of the remote cathodic protection station is made in the form of a resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the consumed current, an increased frequency generator that increases the resonant transformer with a capacitor, connected by a shielded cable power line with a reverse transducer, including a step-down resonant transformer and a rectifier with a shape corrector current, while the power source is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the step-up resonant transformer through a capacitor, the outputs of the step-up winding of the step-up resonance transformer are connected by a shielded cable power line to the input winding of the step-down resonance transformer, connected with a rectifier, the output of which is configured to connect to the equipment of the cathodic protection station, with protection sought from corrosion by an electrically conductive structure and deep anode grounding.

In another embodiment, the above technical result is achieved by the fact that the proposed power supply source of the remote cathodic protection station is made in the form of a single-wire resonant power transmission system including a power source, a rectifier with a current shape corrector, an increased frequency generator that increases a resonant transformer with a capacitor and an earthing switch connected by a single-wire power line to a inverse converter including a step-down resonant transformer, and you a rectifier with a corrector of the shape of the consumed current, while the power source is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the boost resonant transformer through a capacitor, one output of the output winding of the boost resonant transformer is connected to the ground electrode, and the second output terminal windings of the step-up resonant transformer is connected by a single-wire power line to the output of the input winding of the step-down resonant transf a mator connected to a rectifier, the output of which is configured to connect to the equipment of the cathodic protection station, with an electrically conductive structure protected from corrosion and deep anode grounding, while the second terminal of the input winding of the step-down transformer is configured to be connected via capacitors to an electrically conductive structure protected from corrosion, and deep anode grounding.

The essence of the proposed utility model is illustrated in FIGS. 1, 2, 3.

Figure 1 presents the General diagram of the power source of the cathodic protection station with grounding transmitting and receiving equipment. Figure 2 presents the General diagram of the power source of the cathodic protection station, in which a shielded cable line is used as the power line. In figure 3. The general scheme of the power supply source of the cathodic protection station with grounding of the transmitting equipment and connection to the electrodes through the capacitor of the receiving equipment is presented.

The power supply source of the remote cathodic protection station of FIG. 1 contains a power source 1, a rectifier with a power consumption corrector 2, an increased frequency generator 3, the capacity of a resonant transformer 4, an increasing resonant transformer 5, a single-wire power line 6, lowering a resonant transformer 7, grounding 8 and 9, a rectifier with a corrector of the shape of the consumed current 10, the equipment of the cathodic protection station 11, the structure 12 protected against corrosion, the system of deep anode earthing switches 13.

The power supply source of the remote cathodic protection station of FIG. 2 contains a power source 1, a rectifier with a power consumption corrector 2, an increased frequency generator 3, a resonant transformer 4 capacitance, a resonant transformer 5 boost, a shielded cable power line 14, a resonant transformer 7 lower, a rectifier with the corrector of the shape of the consumed current 10, the equipment of the cathodic protection station 11, the structure 12 protected against corrosion, the system of deep anode grounding conductors 13.

The power supply source of the remote cathodic protection station of FIG. 3 contains a power source 1, a rectifier with a power-supply current corrector 2, an increased frequency generator 3, a resonant transformer 4 capacitance, a resonant transformer 5 boost, a single-wire power line 6, a resonant transformer 7 lower, ground 8, rectifier with a corrector of the shape of the consumed current 10, the equipment of the cathodic protection station 11, the structure 12 protected against corrosion, the system of deep anode grounding conductors 13 and grounding capacitors 15 and 16.

In this case, the power source 1 (Fig. 1) is connected to the rectifier with the corrector of the shape of the consumed current 2, the output of which is connected to the high-frequency generator 3, the output of which is connected to the boost resonant transformer 5 through a capacitor 4, one output of the output winding of the boost resonant transformer is connected to grounding 8, the second output terminal of the output winding of the boost resonant transformer is connected to a single-wire power line 6, to which the input winding of the lower resonance about transformer 7, the second output of the input winding of the step-down resonant transformer is connected to ground 9, the step-down winding of the step-down transformer is connected to a rectifier with a shape corrector for the current consumption 10 whose output is connected to the equipment of the cathodic protection station 11, to the output of which the cathode is connected in the form of an electrically conductive corrosion protected design 12 and deep anode grounding 13.

In another embodiment, the power source 1 (Fig. 2) is connected to a rectifier with a corrector of the shape of the consumed current 2, the output of which is connected to a high-frequency generator 3, the output of which is connected to a boost resonant transformer 5 through a capacitor 4, the outputs of the boost resonant transformer are connected to a shielded cable power line 14, which is connected to the input winding of a step-down resonant transformer 7, the step-down winding of a step-down transformer is connected to a rectifier with a form corrector consumed current 10 whose output is connected to the cathodic protection station equipment 11, which is connected to the output of the cathode in the form of corrosion of the protected conductive structure 12 and the depth 13 of the anode grounding.

In another embodiment, the power source 1 (Fig. 3) is connected to a rectifier with a corrector of the shape of the consumed current 2, the output of which is connected to an increased frequency generator 3, the output of which is connected to a boost resonant transformer 5 through a capacitor 4, one output of the output winding of a boost resonant transformer is connected with grounding 8, the second terminal of the output winding of the boost resonant transformer is connected to a single-wire power line 6, to which the input winding of the step-down re onance transformer 7, the second output terminal of the input winding of the step-down resonant transformer is connected to grounding capacitors 15 and 16, the step-down winding of the step-down transformer is connected to a rectifier with a current shape corrector 10, the output of which is connected to the equipment of the cathodic protection station 11, to the output of which the cathode is connected in the form of a shielded from corrosion of the conductive structure 12 and deep anode grounding 13.

The proposed utility model (figure 1) works as follows:

From a power source 1, a voltage of 10 ... 380 V is supplied to a rectifier with a corrector of the shape of the consumed current 2, from the output of which it is supplied to a high-frequency generator 3, is converted to alternating voltage with a frequency of 1 ... 100 kHz and fed to a boost resonant transformer 5 through a capacitor 4, from the output winding of a step-up resonant transformer, an alternating voltage of 0.5 ... 100 kV is supplied to a single-wire power line 6, then the voltage is reduced by a receiving resonant transformer 7 and a rectifier with a corrector s input current 10 to the voltage required for operation of the main ground electrode submerged anode 13 and the cathode protection station equipment 11 voltage of 10 ... 100 V, while the high voltage windings of the transformers are grounded via grounding conductors 8 and 9.

The proposed utility model (figure 2) works as follows:

From a power source 1, a voltage of 10 ... 380 V is supplied to a rectifier with a corrector of the shape of the consumed current 2 from the output of which is supplied to a high-frequency generator 3, converted to alternating voltage with a frequency of 1 ... 100 kHz and fed to a boost resonant transformer 5 through a capacitor 4, s the output winding of the step-up resonant transformer an alternating voltage of 0.5 ... 100 kV is supplied to the shielded cable power line 14, then the voltage is reduced by the receiving resonant transformer 7 and the rectifier with Ktorov form input current 10 to the voltage required for operation of the main ground electrode submerged anode 13 and the cathode protection station equipment 11, 10 ... voltage of 100 V.

The proposed utility model (figure 3) works as follows:

From a power source 1, a voltage of 10 ... 380 V is supplied to a rectifier with a corrector of the shape of the consumed current 2 from the output of which is supplied to a high-frequency generator 3, converted to alternating voltage with a frequency of 1 ... 100 kHz and fed to a boost resonant transformer 5 through a capacitor 4, s the output winding of a step-up resonant transformer an alternating voltage of 0.5 ... 100 kV is supplied to a single-wire power line 6, then the voltage is reduced by a receiving resonant transformer 7 and a rectifier with a form corrector s of the consumed current 10 to the voltage required for the operation of the main electrodes of deep anode grounding 13 and the equipment of the cathodic protection station 11 with a voltage of 10 ... 100 V, while the high-voltage winding of the step-up transformer 5 is grounded and the high-voltage winding of the step-down transformer is grounded through capacitors 15 and 16 so that alternating high-frequency voltage was distributed evenly between the electrodes of deep anode grounding 13 and the protected structure 12.

The transmitting equipment can be grounded to both the ground electrode and the power source. Rectifier 2 with the corrector of the shape of the current consumption reduces the current consumption from the power source, filters high-frequency noise and at the same time stabilizes the rectified voltage. The rectifier 10 with the corrector of the shape of the consumed current allows you to increase the throughput of the power line, because uses for rectification the entire area of the waveform of the input high-frequency voltage. This rectifier also has the function of stabilizing and limiting the rectified voltage.

The system of the main electrodes includes anodes of deep anode grounding 13 located at the optimal (calculated) distance from the protected structure and a cathode or negative electrode that is connected to the electrically conductive body or structure 12 that is protected from corrosion.

The structures that need to be protected from corrosion are usually trunk product pipelines including oil and gas pipelines, circuits of heat and water systems, biogas bunkers, metal foundations, storages of chemically active fertilizers, agricultural and other objects. At the same time, several cathodic protection stations can be connected to the power line with different distances from the transmitting unit through step-down receiving transformers.

Claims (3)

1. The power source of the remote cathodic protection station, characterized in that it is made in the form of a single-wire resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the consumed current, an increased frequency generator, a resonant transformer with a capacitor and an earthing switch, connected by a single-wire power line with a reverse transducer, including a step-down resonant transformer with an earthing switch and a rectifier with a corrector of the shape of the current consumption, at In this case, the power source is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the boost resonant transformer through a capacitor, one output of the output winding of the boost resonant transformer is connected to the ground electrode, and the second output of the output winding of the boost resonant transformer is connected by a single-wire power line with the output winding of the step-down resonant transformer, the second output of the input winding is connected to mlitelem, lowering the resonant transformer winding coupled to a rectifier, the output of which is configured to connect with equipment cathodic protection station, protected against corrosion electroconductive anode structure and the deep earth. 2. The power source of the remote cathodic protection station, characterized in that it is made in the form of a resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the consumed current, an increased frequency generator, a resonant transformer with a capacitor, connected by a shielded cable power line with a reverse converter including a step-down resonant transformer and a rectifier with a corrector of the shape of the consumed current, while the power source is connected to a rectifier, the output of which is connected to a high-frequency generator, the output of a high-frequency generator is connected to a step-up resonant transformer through a capacitor, the outputs of the step-up winding of the step-up resonant transformer are connected by a shielded cable power line to the input winding of the step-down resonant transformer, connected to the rectifier, the output of which is made with the possibility of connection with equipment of a cathodic protection station, with an electrically conductive structure protected from corrosion cation and deep anode grounding. 3. The power source of the remote cathodic protection station, characterized in that it is made in the form of a single-wire resonant power transmission system, including a power source, a rectifier with a corrector of the shape of the consumed current, an increased frequency generator, a resonant transformer with a capacitor and an earthing switch, connected by a single-wire power line with a reverse transducer, including a step-down resonance transformer, and a rectifier with a corrector of the shape of the current consumption, while the power supply is connected to a rectifier, the output of which is connected to the high-frequency generator, the output of the high-frequency generator is connected to the boost resonant transformer via a capacitor, one output of the output winding of the boost resonant transformer is connected to the ground electrode, and the second output of the output winding of the boost resonant transformer is connected by a single-wire power line to the output input winding of a step-down resonant transformer connected to a rectifier, the output of which is made with possibility of connection to the cathodic protection station equipment, protected from corrosion with conductive structure and deep anode grounding, wherein the second terminal of the input winding of step down transformer adapted to be connected through capacitors protected against corrosion electroconductive anode structure and the deep earth.

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