SU746908A1 - Pulse modulator - Google Patents

Description

(54) PULSE MODULATOR The invention relates to pulse transmitting devices of radio equipment of various HaJHa4emw. A pulsed modulator containing a source of a constant voltage, a charging circuit consisting of series-connected droplets and a diode, a charging capacitor, a step-up transformer, a generator of trigger pulses, a controlled switch, a shaping line connected in parallel with the secondary winding of the step-up circuit are known. transformer, load, the submodule, the delay element included between the trigger pulse generator and the submodule, the thyristor connected in series to the primary winding of the boost transform torus, an ignition generator connected between a trigger pulse generator and a thyristor control electrode, a charge capacitor connected to the output of the charging circuit and parallel to the primary winding of the step-up transformer and the thyristor 11} The disadvantage of this modulator is that it is not possible to adjust the pulse voltage load. Also known is a pulse modulator containing a constant voltage source, in parallel with which are connected two series-connected charging capacitors and a primary winding of a step-up transformer, to the terminals of which two thyristors connected in the conducting direction of the switch are connected to the control electrodes with the corresponding output pulse generator whose input is connected to the connection point of the trigger pulse generator with a delay element connected to the submodulator included in the control There is a switch in the circuit, and in uerei of the secondary winding of the step-up transformer, the lines of junction with the load and switch 2 are turned on. Its disadvantage is also the impossibility of adjusting the amplitude of the pulses on the load. The purpose of the invention is to provide the ability to adjust the amplitude of the pulses on the load. The goal is achieved by the fact that in an impulse modulator containing a source of a fixed voltage, parallel to which

include two series-connected charge capacitors 1x and the primary winding of the step-up transformer, to the outputs of which a thyristor is connected in the conducting direction, connected by control electrodes to the corresponding outputs of the control pulse generator, the input of which is connected to the connection point of the starting pulse generator with the delay element connected to the submodulator and connected to the control circuit of the switch, and the secondary winding circuit of the step-up transformer includes lines forming with Loading the switch and, introduced adjustable inductance, connected between the common point of the compound charge dnyh

a capacitor and a midpoint of the primary winding of the step-up transformer, a capacitor connected in parallel with the secondary winding of the step-up transformer, and a diode connected between the output of the secondary winding of the step-up transformer and the connection point of the formation line with the load, and the load and switch are connected in series with each other and connected in parallel to the formation line.

FIG. 1 shows a pulse modulator circuit; in fig. 2 - voltage plots at nodal points of a pulse modulator circuit.

The pulse modulator contains a source of constant voltage 1, in parallel to which the inclusion of two series-connected charge capacitors 2 and 3; thyristors 4 and 5; a step-up transformer 6, to the primary of which the primary winding 7 is connected

thyristors in the conductive direction, and a diode 9 and parallel to a capacitor 10 are connected in series in the secondary winding 8 and a capacitor 11 is connected between the common bus and the cathode of the diode and the load 12 is connected in series with the switch 13; a starting pulse generator 14, the output of which is connected to the generator input 15 control pulses, which is connected to the thyristor electrodes by means of its outputs. Regulatory inductance 16 is connected between the common connection point of the charge capacitors and the midpoint of the primary winding of the step-up transformer. Delay element 17 and submodule 18 are included in the switch control circuit in series with the starting pulse generator.

Pulse modulator works as follows.

The start-up pulses of the modulator (Fig. 2a) from the up of the generator 14 of the starting impulses arrive simultaneously on the generator 15 of the control pulses and the delay element 17. From the output of the generator 15, the formed

Along with triggering pulses, thyristor starting pulses (Fig. 2 b and c), j are fed to each thyristor in turn. In this case, the charging capacitors 2 and 3 are alternately charged from the constant voltage source 1 and discharged through the step-up transformer 6 to the generation line 11.

At time tj, when the charge capacitor 2 is charged approximately to the voltage of the power source (Fig. 2 d), and the voltage on the charge capacitor 3 is approximately zero (Fig. 2 d), the thyristor start pulse (Fig. 2 c) arrives at the control electrode of the thyristor 4. The thyristor opens, the charging capacitor 2 is discharged to zero through an adjustable release rate 16 and the upper half of the primary winding 7 of the step-up transformer 6, and the charging capacitor 3 is charged before the supply voltage Ejjgj of the circuit : plus 1 power supply source Ristor 4 - the upper half of the primary winding 7 of the step-up transformer 6; inductance 16 - minus the power source. At the same time, the energy stored in the charge capacitors 2 and 3 at the time of their charge and discharge charges the capacitor 10 (Fig. 2.g) and the capacitors of the forming line 11 (Fig. 2, c).

At time t2, when the voltage of line 11 of the formaction and capacitor 10 reaches a maximum, the no. 4 closes and the oscillating process begins (dotted line, fig. 2 g) in the circuit formed by the capacitor 10 and the magnetizing inductance of the step-up transformer 6. Voltage the formation lines are fixed by diode 9.

At time t, a start pulse delayed by delay element 17 is sent to submodule 18, the output pulse of which (Fig. 2e) opens switch 13, and a pulse appears on load 12 (Fig. 2; I). At the end of the process of depositing a switch (thyratron) 13, the scheme is ready for the arrival of the next after the sky pulse. The charge capacitor 2 is discharged to zero, and the charge capacitor 3 is charged before the voltage of the power source EJJCT. .

The next trigger pulse causes the thyristor 5 to turn on. The processes of discharge of charge capacitor 3 and charge of charge capacitor 2 are similar to the processes of charge - discharge of charge capacitors 2 and 3 described above.

Claims (2)

The next switching on of the thyristors takes place during the oscillation process (Fig. 2 g) in the potour formed by the capacitor 10 and the magnetization inductance of the step-up transformer 6. Moreover, depending on the ratios of the charge-discharge process of the charge capacitors 2 and 3 or the most, the process of charging the capacitors of the line 11 of formation and the period of the oscillatory process noted above with a constant period of following the start-up pulses of the modulator and different values (both in sign and magnitude) of the voltage across the capacitor 10. The duration of the charge-discharge processes of the charge capacitors is determined by the dissipation inductance of the boost transformer 6, the inductance 16, and the total condensation capacitance ditch 2 and 3 and the total capacitance of the capacitors of the forming line 11 and the capacitor 10, and the period of the oscillatory process is determined by the magnetically inductance of the step-up transformer 6 and the capacitance of the capacitor 10. Thus, By varying the inductance 16 or the capacitor of the capacitor 10, it is possible to set the voltage level at the capacitor 10 at which the next thyristors are turned on. FIG. 2, in the time interval ti-t4, processes corresponding to the LI value of the controlled inductance 16 are depicted when the thyristors are turned on at zero voltage on the capacitor 10, which is equivalent to the absence of this capacitor. When the inductance value is 16 Lj LJ, the duration of the charging process of charge capacitors is increased, and the thyristors are turned on at a certain rum negative voltage on the capacitor 10 (time interval t4 -t,). In this case, the energy that capacitor 10 currently possesses returns to charge capacitors 2 and 3, increasing the voltage w of one of them to a value (.E) and recharging the other charge capacitor to a negative value (-DE) which in turn leads to an increase in the voltage on the condis of the VDpax forming line and the amplitude of the voltage on the load. It should be noted that the inclusion of thyristors with a positive voltage on the capacitor U leads to a short discharge of charge capacitors and, accordingly, to a decrease in the amperage of the modulator output voltage. Thus, by changing the magnitude of the inductance or capacitance, it is possible to adjust the amplitude of the pulses on the load of the modulator. This adjustment method is convenient in that reactive 086 elements are used for its implementation, which do not consume energy, and therefore do not impair the efficiency of the modulator. Using the proposed modulator, simplifies the requirements for a power source that does not require adjustment of the output voltage level, as a result of which it becomes possible to use the power source of the modulator to simultaneously power several radio devices; In addition, it is possible to stabilize the amplitude of the output pulses of the modulator with a significant inertia of the power source, making it impossible to respond to rapid changes in the amplitude of the output pulses. An impulse modulator containing a source of constant voltage, in parallel with which are connected two series-connected charging capacitors and the primary winding of a step-up transformer, to the terminals of which two thyristors are connected in the conductive direction connected to the control outputs of the generator of control pulses whose input is connected to the point of connection of the trigger pulse modifier with a delay element connected to the year modulator, 1connected into the control The switch circuit, and the secondary winding of the seam transformer transformer, includes the formation lines with the load and the switch, so that, in order to provide the possibility of adjusting the amplitude of the pulses on the load, the inductance is introduced into it is connected between the common connection point of the charge capacitors and the middle point of the primary winding of the transformer above, the capacitor connected in parallel with the secondary winding of the step-up transformer, and the diode connected between the output of the secondary davyShyuschogo transformer coils and the compound forming point lines with the load, the load and the switch are connected posledovatelbyo each other and connected in parallel liyii forming. Sources of information taken into account during the examination 1. Author's certificate of the USSR N 344570, l. H 03 K 3/53, published. 07.07.72. 2. USSR author's certificate number 467458, l. H 03 K 7/02, published 04.15.75 (prototype).