RU64451U1 - PULSE CONVERTER - Google Patents

Abstract

The device relates to the field of electrical engineering and can be used in powerful pulsed sources of stabilized current for the construction of various devices requiring the conversion of alternating voltage to direct, in particular when constructing a converter for cathodic protection of pipelines and other underground metal structures from soil corrosion. The technical result achieved by solving the task is to reduce the distortion created by the converter in the AC network and to ensure a more complete use of network energy. The block diagram of the converter (figure 1) consists of series-connected starting current limiting unit 1, a network noise filter 2, a network voltage rectifier 3, a power correction unit 4, a voltage conversion unit 5, an output rectifier 6 and an output filter 7. Scheme the converter also includes an input potential value control unit 8 connected to a voltage conversion unit 5. The input of the power factor correction unit 4 is connected to the output of the network rectifier 6, the output is connected to the input of the voltage conversion unit 5, and the output of the input potential value control unit 8 is connected to the input of the voltage conversion unit 5. In addition, the converter circuit can be supplemented by the operating time control unit 9, connected to the input potential magnitude control unit 8 and the output rectifier 6. 1 npf, 3 zpf, 2 ill.

Description

The device relates to the field of electrical engineering and can be used in powerful pulsed sources of stabilized current for the construction of various devices requiring the conversion of alternating voltage to direct, in particular when constructing a converter for cathodic protection of pipelines and other underground metal structures from soil corrosion.

Known pulse current regulator containing an inverter, the output transformer of which contains two identical first and second secondary windings, a half-wave rectifier with a midpoint, the output of which is connected to a storage LC filter with load resistance at the output, the first and second current transformers, the ends of the primary windings of which combined at one point and connected to the negative pole of the load resistance, and their beginnings are connected respectively to the end of the first and the beginning of the second secondary a coil of the inverter transformer, a control circuit transistor inverter. The first and second current transformers are equipped with additional identical secondary windings, which, together with the main secondary windings of the current transformers, are connected in series, the end of the main secondary winding of the first current transformer being connected to the end of the additional secondary winding of the second current transformer, the beginning of which is connected to the beginning of the additional the secondary winding of the first current transformer, the end of which is connected to the end of the additional secondary winding of the second trans the current formatter, and its beginning and the beginning of the main secondary winding of the first current transformer are each connected to the anodes of the rectifier diodes, the cathodes of which are combined at one point and connected to one of the inputs of the control circuit of the inverter key transistors, to the other input of which a common connection point of the additional secondary windings of current transformers (see RF patent No. 2234790, IPC Н02М 3/335, publ. 08.20.2004).

A disadvantage of the known pulse stabilizer is the low efficiency and reliability of its operation due to the limitation of the limits for adjusting the output parameters, the inability to work in the mode of maintaining the given potential of the structure, as well as the increased degree of distortion created by the converter in the AC network.

The closest technical solution to the claimed one is an AC to DC converter containing a network rectifier connected in input to input terminals for connecting a supply network, a conversion channel consisting of a high frequency inverter and a power transformer connected in series, the secondary winding of which is connected to the input of a high frequency rectifier, inductive-capacitive smoothing filter and inverter control unit, with the average output of the transformer primary winding The ora is connected to one of the outputs of the network rectifier, one of the outputs of the high-frequency rectifier through the inductive filter element is connected to the first output terminal for connecting the load, and the filter capacitor is connected between the first and second output terminals, the last of which is connected to the common bus. In this case, the network and high-frequency rectifiers are connected in output in series and each of them is made in a bridge circuit, and the power input of the inverter is connected to the output of the inductive-capacitive filter (see RF patent No. 2006163, IPC Н02М 7/06, publ. 15.01.1994 g .).

The known converter also lacks the ability to work in the mode of maintaining the given building potential, the limits for adjusting the output parameters are limited, the degree of distortion created by the converter in the AC network is increased, which reduces the efficiency and reliability of the converter.

The objective of this utility model is to increase the efficiency and reliability of the converter, as well as the ability to work in the mode of maintaining the given building potential or in the current stabilization mode.

The technical result achieved by solving the task is to reduce the distortion created by the converter in the AC network and to ensure a more complete use of network energy.

The task is achieved in that the pulse converter containing a network rectifier, a voltage conversion unit, and an interference filter, according to a utility model, is equipped with a power factor correction unit and an input potential value control unit, while the input of the power factor correction unit is connected to the output of the network rectifier, the output is with the input of the voltage conversion unit, and the output of the control unit of the input potential value is connected to the input of the voltage conversion unit.

In addition, the converter is equipped with an inrush current limiting unit and a network noise suppression filter.

In this case, the power factor correction block is made in the form of a step-up regulator of the rectified mains voltage and includes a power switch, a booster diode, a storage choke, an output buffer capacitor, and a control circuit based on a special controller.

In addition, the input potential magnitude control unit includes a potential sensor and a voltage converter control circuit.

The inventive combination of features can reduce the distortion created by the Converter in the AC network and to ensure a more complete use of the active energy of the supply voltage by reducing the reactive component of the current. In addition, the claimed combination makes it possible to change the operating mode of the Converter, maintaining a given building potential.

In addition, the reliability of the device as a whole is improved by eliminating sudden surges in current and voltage when the device is turned on and off.

The inventive utility model is illustrated by drawings, in which Fig. 1 shows a functional block diagram of a converter; figure 2 - electrical schematic diagram of the Converter.

Positions in the drawings mean the following: 1 - block limiting inrush currents; 2 - network noise filter; 3 - network voltage rectifier; 4 - power correction unit; 5 - voltage conversion unit; 6 - output rectifier; 7 - output filter; 8 - control unit of the magnitude of the input potential; 9 - time control unit; 10 - thermistor; 11 - varistor; 12 - power key; 13 - booster diode; 14 - cumulative throttle; 15 - output buffer capacitor; 16 is a control diagram; 17 - power keys; 18 is a power key management diagram 17; 19 - diodes; 20 is a control diagram.

The block diagram of the converter (figure 1) consists of series-connected starting current limiting unit 1, a network noise filter 2, a network voltage rectifier 3, a power correction unit 4, a voltage conversion unit 5, an output rectifier 6 and an output filter 7. Scheme the converter also includes an input potential value control unit 8 connected to a voltage conversion unit 5. The input of the power factor correction unit 4 is connected to the output of the network rectifier 6, the output is connected to the input of the voltage conversion unit 5, and the output of the input potential value control unit 8 is connected to the input of the voltage conversion unit 5.

In addition, the converter circuit can be supplemented by a running time control unit 9 connected to the input potential value control unit 8 and the output rectifier 6.

An electrical circuit diagram of the implementation of the Converter is given in figure 2.

According to the circuit diagram, the inrush current limiting unit 1 may include a thermistor 10 with a negative temperature coefficient and a high-current high-speed varistor 11 to limit surge surges, the amplitude of which can reach 2 kV.

Block 1 limiting inrush currents limits the inrush current at the time of switching on the device, which avoids overloading of elements during transients.

The network noise filter 2, for example, type C1L0C2C3C4, suppresses electromagnetic interference, both from the network side and from the side of the pulse converter.

The power correction unit 4 is made in the form of a boost pulse regulator of the rectified mains voltage and includes a power switch 12, a booster diode 13, a storage choke 14, an output buffer capacitor 15, and a control circuit 16 based on a special controller.

The control circuit 16 of the power switch 12 allows you to reduce the reactive component of the power, which provides a more complete use of energy, increasing the power factor to a value of 0.99.

Block 5 voltage conversion is performed according to the bridge circuit, includes power switches 17 and control circuit 18 of power keys 17. Block 5 converts a constant voltage of 350-400 V into an output of 46 or 96 V.

The output rectifier 6 is made on diodes 19 connected in a bridge circuit to provide less ripple of the output voltage.

Block 7 output filter, suppresses stray vibrations and interference present in the output voltage.

Block 8 monitoring the magnitude of the potential contains an input for connecting a potential sensor and a control circuit 20, which allows you to change the operating mode of block 5 in such a way as to ensure the magnitude of the potential of the structure at a given level.

The control circuit 18 may be performed, for example, based on a PWM controller.

The operating time control unit 9 counts down the time when the potential of the protected structure is at a given level or when the device provides a given output current depending on the operating mode.

The converter operates as follows.

An input voltage of 220 volts is supplied to the inrush current limiting unit 1, where the inrush current is limited at the moment the device is turned on. Further, the voltage is supplied to the network noise suppression filter 2, which suppresses electromagnetic interference, both from the network side and from the side of the pulse converter itself, and then to the voltage rectifier 3. After rectifier 3, a constant voltage is supplied to power correction unit 4, which provides an almost sinusoidal form of current consumption from the network. The voltage conversion unit 5 converts the direct voltage (350-400 V) to the output 48 or 96 V and supplies it to the output rectifier 6. Rectified and filtered by the output rectifier 6, the voltage is supplied to the load, which is used as a protected structure and an anode ground electrode.

Block 8 monitors the potential of the structure and adjusts the operation of the circuit nodes in such a way that the potential of the structure remains equal to the specified value. The value of the potential of the structure is also set in block 8. When the device is operating in the current stabilization mode, the control circuit 18 ensures that the output value of the device is obtained at the device output.

The operating time control unit 9 counts down the time when the protective potential is located on the protected structure or when the device provides a given output current depending on the operating mode.

Claims (4)

1. An AC to DC converter comprising a network rectifier, a voltage conversion unit and an interference filter, characterized in that it is equipped with a power factor correction unit and an input potential value control unit, wherein the input of the power factor correction unit is connected to the output of the network rectifier, output - with the input of the voltage conversion unit, and the output of the control unit of the magnitude of the input potential is connected to the input of the voltage conversion unit. 2. The Converter according to claim 1, characterized in that it is equipped with a block limiting inrush currents and a network noise filter. 3. The Converter according to claim 1, characterized in that the power factor correction unit is made in the form of a boost pulse regulator of the rectified mains voltage and includes a power switch, a booster diode, a storage choke, an output buffer capacitor and a control circuit based on a special controller. 4. The Converter according to claim 1, characterized in that the control unit of the magnitude of the input potential contains a control circuit of the voltage conversion unit.