SU932600A1 - Device for charging reservoir capacitor - Google Patents

Description

The invention relates to pulsed electrical engineering and can be used in devices for charging storage capacitors of generators of powerful energy pulses.

A device for charging a capacitive storage device comprising a transformer, an inductive-capacitive circuit, a rectifier and a capacitive storage device is known. This device is characterized by a relatively low specific power. nostny indicators.

Closest to the proposed “in technical essence is a device for charging a capacitive storage device containing an AC source with two output terminals, an inductive-capacitive circuit, consisting of a series of linear choke and capacitor, two valves and a capacitive storage [2].

However, this device also has low specific power indicators.

The purpose of the invention is the improvement of specific power indicators of the device ⁵ VA for charging a capacitive storage.

This goal is achieved by the fact that in the device for charging a capacitive storage device containing an AC source with two ^{, 0} output terminals, an inductive-capacitive circuit, consisting of a series-connected linear inductor and capacitor, two valves and a capacitive storage, free you ^{, 5} linear water the inductor is connected to the first terminal of the AC source, the common output of the linear inductor and capacitor is connected to its second terminal, the capacitive drive is made of two series-connected drives capacitors, the common output of which is connected to the free output of the condenser 3 932 600 ra, a newly introduced triac is connected in parallel to the capacitor, and the free terminals of the storage capacitors are connected through the fans to the first terminal of the AC source, and the parameters of the inductive capacitive circuit are selected so that the linear choke at the frequency An AC source has a resistance twice that of a capacitor.

In addition, in the device for charging a capacitive storage device, the common output of the linear inductor and capacitor of the inductive-capacitive circuit can be connected to the second terminal of the AC source through a triac ..

On FIG. 1, a schematic electrical diagram of a device for charging a capacitive storage device is presented,. figure 2 is a variant of the device.

The device contains an AC source 1 with two output terminals 2 and 3, a capacitive storage device b, consisting of two series-connected storage capacitors 5 and 6. An inductive-capacitive circuit, consisting of a series-connected capacitor 7 and a linear inductor 8 connected to terminals 2 and. 3 AC source 1, the inductive-capacitive circuit is connected to the terminals of the capacitive storage 4 through the valves 9 and 10, and the capacitor 7 is shunted by the triac 11.

The common output of the linear inductor 8 and the capacitor 7 can be connected to terminal 3 of the AC power source 1 through a triac 12.

A device for charging a capacitive storage device operates as follows. . ‘

We assume that in the first and next odd half-periods of the voltage of the AC source 1, terminal 2 has a positive potential with respect to terminal 3, and in the second and subsequent four half-periods the potential of the terminals is reversed.

At the first stage of the charging cycle (in odd half periods), the storage capacitor 5 is charged through the circuit terminal 2 valve 9, storage capacitor 5, capacitor 7, terminal 3, since the resistance of the linear inductor 8 is two times greater than the resistance of the capacitor 7 and the currents in the linear circuits the inductor and capacitor are in antiphase, the current in the charging circuit is twice the current consumed from the AC source. In this case, the capacitor 7 is charged to the amplitude value of the source voltage in the first quarter of the period, and will be discharged in the second. To the storage capacitor 6 through the valve 10 and the source

1. In addition, in the first quarter of the voltage period of the AC source 1, a linear choke. 8 will give the storage capacitor 5 the energy stored in its magnetic field during the fourth and fourth quarter of the previous period.

In even half-periods, the storage capacitor 6 is charged through the circuit terminal 3 capacitor 7, 25 storage capacitor 6, valve

10, terminal 2.

In this case, the capacitor 7 will be charged for a quarter of the period, and then in the next quarter of the period 30 will be discharged through the AC source 1 and the valve 9 to the storage capacitor 5. In addition, in the third quarter of the period, the linear inductor 8 gives the energy stored in it to the storage capacitor ₃₅ second quarter of the period.

In subsequent periods, the power supply voltage changes, the processes in the device will povtoryat40 ^Xia '

When the storage capacitors 5 and 6 reach a voltage value equal to the amplitude value of the source voltage, si ⁴⁵ mystor 11 is turned on, the shunt capacitor 7.

This increases the rate of energy transfer to the capacitive storage.

The control of the charge process by the triac 12 allows, by adjusting the charge current ⁵⁰ , to limit, if necessary, the magnitude of the charging voltage.

Claims (2)

The invention relates to a pulsed electrical engineering and can be applied in devices for charging the storage capacitors of high-power energy pulse generators. A device for charging a capacitive storage device is known, which contains a transformer, an inductive-capacitive circuit, a rectifier and a capacitive storage device l. This device is characterized by relatively low power density indicators. The closest to the proposed technical entity is a device for charging a capacitive storage device, which contains an AC source with two output terminals, an inductive-capacitive circuit consisting of a series, connected linear throttle and a capacitor, two valves and a capacitive storage device 2. However This device also has low power density indicators. The purpose of the invention is to improve the specific power indicators of a device for charging a capacitive storage device. The goal is achieved by the fact that in a device for charging a capacitive storage device containing an AC source with two output terminals, an inductive-capacitive circuit consisting of a series-connected linear throttle and a capacitor, two valves and a capacitive storage device, the free output of the linear throttle is connected to the first terminal of the AC source, the common output of the linear throttle and the capacitor is connected to its second terminal, the capacitive drive is made of two series-connected accumulator x capacitors, the common output of which is connected to the free output of the capacitor, a newly inserted triac is connected parallel to the capacitor, and the free outputs of the storage capacitors are connected through vents to the first terminal of the AC source, and the parameters of the inductive-capacitance circuit are chosen in such a way that the linear choke is at the frequency AC power has a resistance twice as large as a capacitor. In addition, in the device for charging a capacitive storage device, a common output of a linear throttle and a capacitor of an inductive-capacitive circuit can be connected to the second terminal of the AC source through a triac. Figure 1 shows the principle of the electrical circuit of the device for charging a capacitive storage device,. figure 2 is a variant of the device. The device contains an AC source 1 with two output terminals 2 and 3, a capacitive drive t, consisting of two serially connected storage capacitors 5 and 6, an inductive-capacitive circuit consisting of series-connected capacitor 7 and a linear throttle 8 connected to terminals 2 and. 3 sources of alternating current 1, an inductive-capacitive circuit is connected to terminals of a capacitive storage device k via gates 9 and 10, and capacitor 7 is bridged by a triac 11. The common output terminal of the line throttle 8 and capacitor 7 can be connected to terminal 3 of the AC power supply 1 through triac 12. A device for charging a capacitive storage device operates as follows. We assume that in the first and next odd semi-modes of the voltage of the source of alternating current 1, terminal 2 has a positive potential relative to terminal 3, and in the second and subsequent four half-periods, the potential of the terminals is reversed. At the first stage of the charge cycle (in odd half-periods), a storage capacitor 5 n of the circuit, terminal 2, valve 9, storage capacitor 5, capacitor 7, terminal 3, occurs because the resistance of the line throttle 8 is twice the resistance of the capacitor 7 and the currents in the circuits the linear throttle and the capacitor are in antiphases, the current in the charge circuit is twice the current consumed from the AC source. In this case, the capacitor 7 is charged to the amplitude value of the source voltage in the first quarter of the period, and the second is discharged to the storage capacitor 6 through the valve 10 and the source 1. In addition, in the first quarter of the period the voltage of the alternating current source 1 is linear throttle. 8 will transfer to the storage capacitor 5 the energy stored in its magnetic field during the fourth quarter of the previous period. During even half-periods, accumulative capacitor 6 is charged through the circuit of terminal 3, capacitor 7, storage capacitor 6, valve 10, terminal 2. At the same time, capacitor 7 is charged for a quarter of a period, and then in the next quarter of a period it will be discharged through an AC source 1 and valve 9 short circuit storage capacitor 5. In addition, in the third quarter of the period, the linear choke 8 gives the storage capacitor 6 the energy stored by it in the second quarter of the period. In subsequent periods of change in the voltage of the power source, the processes in the device will be repeated. When the storage capacitors 5 and 6 reach a voltage value equal to the amplitude value of the source voltage, the triac 11 is turned on, the shunt capacitor 7. This increases the speed of energy transfer to the capacitive drive. Controlling the charging process by the triac 12 allows, by regulating the charging current, to limit, if necessary, the magnitude of the charging voltage. Claim 1. A device for charging a capacitive storage device comprising an alternating current source with two output terminals, an inductive-capacitive circuit consisting of a series-connected linear throttle and a capacitor, two valves and a capacitive storage device, characterized in that improving specific power indicators, a free output of a linear throttle is connected to the first terminal of an AC power source, a common output of a linear throttle and a capacitor is connected to its second terminal, a capacitive drive made of two series-connected storage capacitors, to the common output of which a free capacitor output is connected, a newly inserted triac is connected in parallel with the capacitor, and the free outputs of the storage capacitor are connected via gates to the first terminal of the AC source, and the parameters of the inductive-capacitive circuit are selected in such a way that The line choke at the source frequency, AC, has a resistance twice as large as the capacitor. 2. The device according to claim 1, of which the common conclusion is. Line choke and capacitor inductive-capacitive circuit connected to the second terminal of the source through the triac. Sources of information taken into account in the examination 1. USSR author's certificate number 375768 ,. cl. H 03 K 3/53, 1973. 2. USSR author's certificate №, cl. H 03 K 3/57. 1973 (prototype) ..