RU2066086C1 - Thyristor oscillator - Google Patents

Abstract

FIELD: power supplies, geophysics. SUBSTANCE: device has direct current source, inverter, which has two serial circuit of filter capacitor, commutation choke, thyristor and commutation capacitor. In addition device has control pulse generator to which master oscillator is connected; control pulse generator is supplied by means of current transformer which is connected to common diagonal of serial circuits, is by-passed by capacitor and which load is output amplifier of control pulse generator. Outputs of amplifier are connected to corresponding control inputs of thyristors. EFFECT: increased reliability, increased functional capabilities. 1 dwg

Description

 The invention relates to thyristor frequency converters and is intended, for example, for use in geophysical downhole devices when conducting geophysical work in the well.

 Known single-phase inverter with self-excitation according to A.S. USSR N 1427527, class H 02 M 7/515, 01.07.86 pr., Containing a thyristor bridge with a capacitor in the diagonal of an alternating current, a choke in one of the bridge power buses, four diodes, each of which is connected to the control electrode of one of the four thyristors of the bridge by a cathode, to the capacitor of which the start-up circuit is connected in parallel, as well as the thyristor control pulse shaper with the frequency control connected to it, while the pulse shaper is made in the form of a chain of series-connected limiting resistor and auxiliary shooting gallery a source connected between a direct current terminal of a bridge of positive polarity and a point of association of the anodes of the four anodes.

 This inverter allows you to get an alternating voltage at the output while ensuring reliable operation of the oscillation excitation system.

Depending on the depth of immersion, the temperature in the well varies from 25 to 30 ^o C, while the temperatures in different wells may vary by 40-50 ^o C, i.e., the inverter must provide stable operation in the temperature range of about 80 ^o C, however This circuit design does not provide frequency stability at such temperature differences. In addition, the large overall dimensions of the inverter due to the presence of a large filter choke, as well as a large number of circuit elements, do not allow its use in a downhole generator.

 A key element of the known inverter circuit is a thyristor, which forms the edges of the control pulses. To unlock the inverter thyristors, it is necessary to provide a current per pulse from 1 to several A. The limiting resistor in this circuit is included in the power circuit and its power at an input voltage of 300 V will be about 300 W. For the normal opening of the inverter thyristor, the passport duration of its control pulse should be about 5 μs. At an output frequency of 20-22 kHz (in the case of a magnetostrictive load), the pulse repetition period does not exceed 25 μs. Thus, the power dissipated by the limiting resistor will be at least 150 watts. With this power, the resistor is a powerful source of heat, which will violate the thermal regime in the closed volume of the downhole generator and reduce the reliability of its operation (the circuit will be inoperative).

 In addition, a generator based on this inverter does not provide the operation of a magnetostrictive load (magnetostrictive converters), which narrows the scope of its possible application (for the effective operation of magnetostrictive converters, the simultaneous passage of alternating current of the excitation current and direct polarization current).

 The developers were faced with the task of creating a thyristor generator circuit, which allows it to be reliably used in geophysical borehole (immersed) devices under various, including magnetostrictive, loads.

 Thus, the technical problem solved by the present invention is the creation of a reliable thyristor generator having wide functional capabilities.

 The problem is solved in that in a thyristor generator containing two thyristors connected in series through a load circuit, a first switching capacitor connected to a connection point of the cathode of the first thyristor with a load circuit, a pulse shaper with a driving oscillator connected to it, the first and second inputs of which are connected to a valve connected in series with the resistor. In addition, four filter capacitors, a diode, two switching chokes and a second switching capacitor are connected to the thyristor generator, connected by one plate to the connection point of the anode of the second thyristor with a load circuit, and the other plate with a free plate of the first switching capacitor and with a common point of two in series connected by the first and second filter capacitors connected to the terminals of the direct current source and through switching inductors to the free electrodes of the thyristors, and form The current is made in the form of a primary current transformer connected to a pair of switching and filter capacitors, the current winding of the transformer, a rectifier with a third filter capacitor at the output connected to the secondary winding, connected by a positive plate to the first input of the output amplifier connected to the control electrodes of the thyristors, and negative lining - with a negative output of the source connected to the fourth filter capacitor and the anode of the said valve, as which n a zener diode connected by a cathode with a free lining of the fourth filter capacitor, through a resistor with a positive output of the source, and through a diode with the first input of the output amplifier, to the second input of which a master oscillator is connected.

 With this circuit design of the thyristor generator, the current flowing through the load has alternating and constant components, as with any of the two thyristors turned on, the current (its constant component) through the load always has the same direction, namely: from a terminal that has a common point with the terminal of the first thyristor, to a terminal that has a common point with the input of the second thyristor.

 Those. the circuit allows the use of magnetostrictive converters as a load without the use of an additional source for their magnetization (polarization).

 To ensure the optimal operating mode of the thyristor generator under magnetostrictive load, it is necessary to adjust the converter to the optimal operating mode (providing maximum radiation power), for which it is necessary to coordinate the impedance of the electrical part of the thyristor generator and the impedance of the magnetostrictive converter. This coordination is achieved at certain specific values of the alternating current excitation and direct current polarization. Coordination of the operation of two converter power sources requires additional devices and circuit solutions, which degrades reliability and significantly increases the overall dimensions of the generator.

 The proposed technical solution, eliminating the need for an additional current source to provide a magnetostrictive load, allows for matching the impedance of the generator (electrical part of the generator) and the magnetostrictive load with a single power source by selecting the parameters of the generator circuit elements for a specific magnetostrictive load, in the future there is no need to control the electrical impedance parts of the generator and load, as their ratio will be constant, determined only by the parameters of the elements of the generator circuit.

 This ensures reliable and stable operation of the generator when it is included in the magnetostrictive load circuit.

 In addition, in the proposed generator, its high-frequency part, consisting of two series circuits and a load, is separated from the DC power source by filter capacitors, for this the filter capacitors are selected to be much larger than the capacitance of the switching capacitors. Therefore, for reliable operation of the generator, an additional filter choke is not required, which allows to reduce the overall dimensions of the generator.

 To ensure reliable operation of the generator in the well, it is necessary to have a thyristor control system that works efficiently in the confined space of the well and does not worsen the overall dimensions of the generator.

 The thyristor control system will not worsen the mass-dimensional parameters of the generator if it lacks powerful circuit elements that consume significant energy. To this end, in the proposed generator, the power supply providing the operation of the thyristor control system was divided so that it was not necessary to have large power at the input of the control system to provide enough current at its output to unlock the thyristors.

 To reduce the installed power of the power supply system by the thyristors in the proposed generator, an intermediate source was provided to power the output amplifier, with the output of which control pulses are fed to the thyristors.

 A low-current (8-10 mA) master oscillator, including a pulse distribution system, is fed through a chain limiting resistor - a zener diode. In this case, the power of the resistor is selected so as to provide power to this master oscillator (at a voltage of a direct current source of 300 V, it is enough to have a resistor of 40-50 kOhm, while the allocated power will be 3-5 W) and nothing more.

 To power the output amplifier (or amplifiers), a source is used, which is a current transformer included in the diagonal of the inverter AC current, from the transformer output through the rectifier, the current flows to the third filter capacitor and then to the output amplifier. In order to prevent the current transformer from burning out in the event of an open circuit, a quenching capacitance is used, which is connected to the terminals of the secondary winding of the transformer.

 When a voltage is applied to the input of the inverter through the limiting resistor, the fourth filter capacitor is charged, while the voltage of its charge, which is the supply for the master oscillator, is controlled by the first input of the master oscillator and the generation is not allowed until the voltage reaches the specified value, after which the pulses from the output of the master oscillator arrive at the input of the output amplifier.

 Simultaneously with the beginning of the charge of the fourth filter capacitor through the limiting resistor and the diode, a third filter capacitor is charged, the voltage of which is the power supply to the output amplifier. When the voltage at the resolving input of the master oscillator of a given value is reached, generation starts, while the master oscillator generates pulses of the required frequency and distributes them into two clock cycles. The pulses of each cycle are amplified by the output amplifier. In this case, the energy stored in the third filter capacitor is enough to turn on the inverter thyristors. Simultaneously with turning on the thyristors of one of the inverter arms, the diagonal current of the inverter through the current transformer and rectifier feeds the third filter capacity and from this moment the current transformer is the power source of the output amplifier.

 The diode serves to exclude the discharge of the third filter capacity through the input circuit of the master oscillator, and also separates the power source of the master oscillator and the output amplifier.

 The power of the introduced limiting resistor does not exceed 3-6 W, which will not affect the violation of the thermal regime in the well at the location of the downhole geophysical instrument equipped with this generator (the limiting resistor at this power will not be an additional heat source that disrupts the normal functioning of the downhole instrument). When the generator is operating, this resistor will only serve to power the low-current power supply system of the master oscillator.

 The current required for unlocking the thyristors is provided by the parameters of the current transformer, rectifier, third filter capacitor and output amplifier, providing such directional power (there are no energy costs associated with powering the other functional nodes of the circuit) allows you to choose the minimum necessary and sufficient parameters for the normal operation of the circuit for these elements .

 The proposed thyristor converter circuit does not have large and bulky circuit elements (filter chokes, powerful resistors and capacitors, etc.), which allows the generator to be executed in small volumes. The introduced elements also do not have significant overall dimensions and therefore their introduction will not affect a significant increase in the mass-dimensional parameters of the generator, therefore, the proposed thyristor generator circuit will allow its use as a borehole.

 Thus, the proposed technical solution allows to minimize the size of the thyristor generator, which makes it possible to use it as a borehole to power downhole geophysical devices and, thereby, also extends its functionality, and ensuring the normal operation of such a generator in a confined space of the well allows to increase stability and reliability of its work.

 The drawing shows a diagram of the proposed thyristor generator.

 The thyristor generator contains an input rectifier 1 connected to a series-connected pair of filter capacitors 2, 3, which are connected through the switching chokes 4, 5 respectively to the anode of the thyristor 6 and to the cathode of the thyristor 7. A pair of series connected to the cathode of the thyristor 6 and the anode of the thyristor 7 switching capacitors 8, 9, shunted by the load 10 magnetostrictive Converter. The common points of the filter capacitors 2, 3 and switching capacitors 8, 9 are interconnected via the primary winding of the transformer 11. The control terminals of the thyristors 6, 7 are connected to the outputs of the output amplifier 12.

 The secondary winding of the transformer 11 is shunted by the capacitor 13 and connected to the input terminals of the rectifier 14 (for example, a single-phase bridge rectifier on diodes). The rectifier 14 is shunted by the capacitor 15, one of which is connected to the negative terminal of the power source, and the positive plate is connected to the power terminal (first input) of the amplifier 12. Between the positive and negative terminals of the power source (between the outputs of the rectifier 1) a chain of resistor 16 and a zener diode 17, shunted by the capacitor 18. The common point of the zener diode 17 and the capacitor 18 through a resistor 16 is connected to the positive output of the power source and simultaneously connected to the first (allowing mu) Valid oscillator 19, to the second input of which is connected to another common point of capacitor 18 and zener diode 17.

 The first input of the master oscillator 19 is connected to the anode of the diode 20, the cathode of which is connected to the first input of the amplifier 12.

 The generator operates as follows.

 In the initial state, the alternating voltage of the power supply network of industrial frequency supplied to the input terminals of the rectifier 1 is converted to constant. Capacitors 2, 3 are charged in total to approximately the amplitude value of the supply voltage.

 At the same time, a capacitor 18 is charged through a limiting resistor 16 (50 kΩ), while the master oscillator 19 does not start generation until the charge voltage of the capacitor 18 reaches a predetermined level. Simultaneously with the beginning of the charge of the capacitor 18 through the resistor 16 and the diode 20, the charge of the capacitor 15 occurs. When the voltage at the resolving input of the master oscillator 19 of a given value is reached, generation starts, the pulses of the master oscillator 19 are fed to the second input of the amplifier 12. At the same time, the energy stored for this period the time in the capacitor 15 is enough to turn on the thyristors of the inverter through the amplifier 12. When one of the thyristors is turned on, the diagonal current of the inverter through the current transformer 11 and the rectifier 14 feed the capacitor 15. Next, the power source of the output amplifier is a current transformer 11.

 The master oscillator 19 distributes the pulses in two clock cycles so that the pulses did not arrive at the inverter arms simultaneously, but in a predetermined sequence.

 When applying control pulses from the output of the amplifier 12 to the thyristors 6, 7, the process of converting the input DC current to a high-frequency current occurs.

При переключении тиристоров (с тиристора 6 на тиристор 7) ток будет протекать по контуру:

При протекании тока по магнитострикционной нагрузке последняя начинает работать в режиме, определяемом параметрами схемы тиристорного генератора.When thyristor 6 is turned on, a half-wave current, close in shape to a sinusoidal one, flows along the circuit:

When switching thyristors (from thyristor 6 to thyristor 7), the current will flow along the circuit:

When the current flows through the magnetostrictive load, the latter starts to work in the mode determined by the parameters of the thyristor generator circuit.

Claims (1)

 A thyristor generator containing two thyristors connected in series through a load circuit, a first switching capacitor connected to a cathode connection point of the first thyristor and a load circuit, a pulse shaper with a master oscillator connected to it, the first and second inputs of which are connected to a valve connected in series with a resistor, characterized in that four filter capacitors, a diode, two switching reactors and a second switching capacitor connected by one plate to t are introduced into it by connecting the anode of the second thyristor to the load circuit, and another lining with a free lining of the first switching capacitor and with a common point of two series-connected first and second filter capacitors connected to the terminals of the DC source and through switching chokes to the free electrodes of the thyristors, and the current driver in the form of a primary winding of a current transformer included in a circuit connecting a pair of switching and filter capacitors, to the secondary winding of which I connect a rectifier with a third filter capacitor at the output is connected, connected positively to the first input of the output amplifier, connected to the control electrodes of the thyristors, and negatively connected to the negative output of the source, connected to the fourth filter capacitor and the anode of the valve, which is used as a zener diode connected by a cathode with a loose lining of the fourth filter capacitor, through a resistor with a positive output of the source, through a diode with the first input of the output th amplifier, to the second input of which a master oscillator is connected.