SU1053279A2 - Pulse modulator - Google Patents

Abstract

PULSE.ZH DULYATO on avt.s. 467458, in order to increase the pulse repetition rate, two chains are introduced into it consisting of series-connected sources, a resistor and throttles, each chain being connected by a parslly charged capacitor in a non-conductive direct current direction , the condition, where the total capacity of the charging capacitors must be fulfilled; n - transformation ratio of step-up transformer}. capacitance of the line FO1 shrovani 5 cl 00 to h WITH

Description

The invention relates to pulsed radio transmitting devices for various types of radio equipment. According to the main auth. No. 467458, a modulator is known which contains a power source in parallel which includes two series-connected charge capacitors, a step-up transformer, the middle output of which is connected to the combined capacitor charge, and between the edges of which are the leads and the power source output. at. Two thyristors are connected to the conductive direction, coaxial control electrodes with the corresponding outputs of the control pulse generator, the input of which is connected to the combined outputs of the trigger pulse generator and the input of the delay element, the output of which is connected to the control input through the submodulator. the switch, and parallel to the secondary winding of the step-up transformer, the switch and the series-connected forming lines and load are connectedC. The disadvantage of the known pulse modulator is The repetition rate of the output pulses is low due to the large recovery time during load breakdowns or the switch is accidentally turned on during the process of charging the NIN line. The aim of the invention is to increase the pulse repetition rate. The goal is achieved by the fact that a pulse modulator containing a power source, in parallel with which are connected two series-connected charging capacitors, increases the transformer, the middle output of the primary winding of which is connected to the combined terminals of the charging capacitors, and between the extreme terminals of which and the output of the power source Two thyristors connected in the conducting direction are connected by control electrodes with the corresponding outputs of the generator of control pulses, the input of which is connected Connected to the combined outputs of the generator of the trigger pulses and the input of the delay element, the output of which through the submodulator is connected to the control input of the switch, and parallel to the secondary winding of the raising transformer the switch is connected and the series-connected formation and load, two chains are inserted of a series-connected diode, resistor, and droplet, each chain connected in parallel to a charged capacitor in a non-conductive direct current direction, with Condition C, / n-iC should be satisfied where C is the total capacitance of the charge capacitors; n transformation ratio of step-up transformer; Sff-line capacity of the formation. Figure 1 shows the pulse, modulator; Fig. 2 is a simplified equivalent circuit of a charge circuit of a line forming t when charging a charge capacitor; in Fig. 3, the same when discharging a charge capacitor; Fig. 4 shows voltage plots at the nodal points of the modulator circuit. A pulse modulator contains a power supply 1, a power supply circuit 2 and 3, which include diodes 4 and 5, chokes b and 7, resistors 8 and 9, charge capacitors 10 and 11 / thyristors 12 and 13, and step-up transformer 14, respectively. with primary 15 and secondary 16 windings, formation line 17, load 18, switch 19, initial pulse generator 20, control pulse generator 21, delay element 22 and submodulator 23. Parallel to power supply 1 1 two successively connected charge capacitors are inserted 10 and 11, to the combined in The outputs are connected to the average output of the primary winding 15 of the step-up transformer 14, the extreme leads of which are connected to the power source 1 through the thyristors 12 and 13, the secondary winding 16 of the step-up transformer 14 is bridged by line 17 and sequentially connected by the load 18 and the switch 19. The output of the generator 20, triggering pulses connected to the control of the electrodes of the thyristors 12 and 13 through the generator 21 of control pulses, and the control input of the switch 18 through the serially connected delay elements 22 and submodules op 23. The pulse modulator operates as follows. The start-up pulses CDA of the modulator (fig. 4a) from the output of the generator 20 arrive simultaneously at the input of the element 22 and at the input of the generator 21. The output pulses of the generator 21, which coincide in time with the starting ones, alternately fire the thyristors 12 and 13. In this case, the charging capacitors 10 and 11 are charged up to the voltage of the power source or discharged to zero through the corresponding half of the primary winding 15 of the step-up transformer 14.. The processes in the circuit are not disturbed if the charging capacitor 11 is connected in parallel with the charging capacitor L6 or vice versa (as shown by the solid line in (Fig. 1). When the thyristor 12 is ignited, the charging of the capacitor 11 occurs, and Ignition of the thyristor 13 is its discharge. Therefore, further explanations of the operation of the circuit relate specifically to this case. At time i, when the charge capacitor 11 is discharged (FIG. 4b / a voltage and currents in the circuit are zero, the first pulse the start-up, the thyristor 12 is ignited. In this case, the charge capacitor 11 The circuit is charged: plus source 1 - thyristor 12 upper half of primary winding 1 of step-up transformer - minus source 1. During charging of charging capacitor 11, line 17 is charged with current flowing through the secondary winding 16 of step-up transformer. The two lines of formation and charge of the charge capacitor flow in the equivalent circuit shown in Fig. 2, in which the total capacity of the cells of the formation line is equivalent to the capacitance C df, the charge capacitor's capacitance is the capacitance inductance of the scattering ayusche1Go transformer - t .. inductance circuit elements pereschitanyv povyshak Oleg Zhegoyev primary winding of the transformer. From the equivalent scheme, it can be seen that the charge of the serially connected capacitance C and the capacitance Cd flows in the RLC circuit, and depending on the goodness of this circuit, the voltage Up can theoretically reach the double voltage of the power source, i.e. Uc 2 E. The voltage Uj on the capacitance C 3 and the voltage. Udf on the capacitance C is inversely proportional to the values of these capacitances. Therefore, so that after the end of the charging process C and Sdfne there is a discharge of capacitance C 3 through circuit 2, the energy return (Uj iE), the value of capacitance C a is chosen to be greater than or equal to capacitance Cpf, i.e. when recalculating the bone of the formation line to the primary winding of the step-up transformer, the condition must be met. From the Under Cs Slfie E. Under the action of reverse voltage and CS, JCB E applied to the thyristor 12, the latter is turned off at time t (fig. and 4d). From this point in time, the discharge of the formation lines through the secondary winding 16 begins. The step-up transformer through the magnetization inductance to the moment since the arrival time t from the output under the modulator 23 impulse and the fFL, delayed by element 22, voltage Rdf of FIG. 4g almost no time to change. The pulse C, dd ignites the switch 19 of the line 17 is discharged, and on the load 18 a pulse is formed and (Fig.Ed /. The next charge cycle of the line 17 starts at the time of arrival of the second start pulse (Fig.4al) At this time the thyristor 13 is set on fire and the discharge of the charge capacitor 11 occurs through the lower half of the primary winding 15 of the step-up transformer and the simultaneous charge of the line 17. The discharge of the charge capacitor and the charge of the formation line in this case flows in an equivalent circuit (Fig. Zb. B time point U, -E, O ΦO and Uj. + E, the polarity of the charge of the capacitors is indicated on the equivalent circuit. By the end of the process Ue -E and with C} Sdf, Uj O, and Odf E. After the discharge of the capacitance Ce, the opposite voltage is applied to the thyristor C and: -E, under the action of which it is turned off. At the time of 15 arrival of the pulse in Fig. 4b), the formation line (Fig. 4d) is discharged and a pulse is formed on the load (Fig. 4e}. The formation and charge line charge cycle the charge capacitor begins at a time instant t occurs three-fold as in the first case with the thyristor switched on or 12. When the formation line is discharged through the load 18 and the switch 19 at the time t.B, a breakdown occurs to the load. In this case, the line of formation is discharged almost to a short-circuited load, and therefore the voltage on the line of formation by the end of its discharge becomes negative And is equal in magnitude to the initial one, i.e. and / UV -E (Fig.46). . After the recharge of the formation line, its slow discharge through the secondary winding of the step-up transformer begins (dotted line in fig.4g) and by the time tg of the beginning of the fourth charge cycle, the voltage on the formation line changes slightly. The charge of the formation line proceeds when the thyristor 13 is turned on in the equivalent circuit (Fig. 3) under the initial conditions Uj + E, -E. In this case, by the end of the process of charging the line of formation of the voltage fc 2E, cdf + E, and -E (Fig. 3g and Sv), the polarity is indicated in parentheses in the equivalent circuit (Fig. 3BB) the time point tg of the formation line is discharged , a pulse is formed on the load, and the capacitance Cj is recharged through the power return circuit 3 to the voltage Uj + E (Fig. 4c). The next, fifth, charge cycle of the line of formation and the output HMninbc of the modulator, in this case will be absent, since when the thyristor 12 is burned, the latter is not included, because a voltage is applied to its cathode. (J + E. formation will take place only when the thyristor 12 is ignited at the moment t of which the charge capacitor 11 is discharged (Fig. 4c). Similarly, the processes in the circuit will flow if the formation line is overcharged as a result of breakdown in the load before turning on the thyristor 12 time point In this case ie after charge line formirova audio TSC voltage + E and .U fyg.4v 4-2E, and an equivalent circuit 4d 2). Under the action of the voltage C 4icT applied to the circuit at the gate of energy 2, the full discharge of capacitor C through this circuit occurs and the power is returned to the power source. Therefore, with the subsequent. turning on the thyristor 13 again there will be no charge of the line of formation and, consequently, a pulse at the output of the modulator. The subsequent operation of the modulator proceeds normally. The processes occurring in the modulator scheme in the case of an arbitrary switching on the switch 19 by typing the charge of the formation line are understood when considering the processes in equivalent circuits (Fig. 2 and 3. When the thyristor 12 is ignited (Fig. 21 and the short-circuited capacitor C) switch 19 charges the capacitance of the charge capacitor C3 to the voltage - Uj 2E, after which it is discharged to the voltage Oj E through circuit 2 to return energy and return energy to the power source. to Yes, the charge of the line of formation proceeds when the thyristor is on, 13 (FIG. 3, in this case, the capacity of the charge capacitor C is recharged (the polarity is indicated in brackets J and its subsequent discharge through the energy return circuit 3. Connection parallel to the charge capacitors return circuit; 1 and the energy containing a series-connected diode, resistor and inductance distinguishes the proposed circuit from the known ones. First, the recovery time of the pedestrians after a breakdown in the load; practically determined by the value (INDUCTANCE of the energy return circuit, which can be made small. As a result, the maximum pulse repetition rate can be increased. Secondly, the return circuit is switched on in the low voltage circuit and does not reduce the reliability of the modulator because of the possibility of surface breakdown, and finally, in the third, the energy stored in the line of formation before the breakdown in the load, and the energy stored in the charged capacitor during an accidental ignition of the switch, for the second time. in the next cycle; charge, thereby increasing the efficiency of the modulator.

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Claims (1)

PULSE MODULATOR »467458, the reason is that, in order to increase the pulse repetition rate ^ two circuits are introduced into it, consisting of a diode, a resistor and a choke connected in series, each circuit being connected in parallel with the charging capacitor in the direction non-conductive by direct current, while the condition Сз>, n ² Сл ^, where С ₃ is the total capacity of the charging capacitors, * η is the transformation coefficient of the step-up transformer; C ^ f is the capacity of the formation line. 1. 1053272