SU651457A1 - Device for charging storage capacitor - Google Patents

Description

The invention relates to a pulse technique. A device for charging a storage capacitor is known, which contains a power source whose output is connected to the anodes of two thyristors whose cathodes are connected via a capacitor and connected to the anodes of two other thyristors whose cathodes are combined and connected through an inductance / pump lamp to the second output of the power source control unit 1. This device has large dimensions and weight when charging a capacitor to the required voltage. Closest to the proposed device is a charging capacitor charge containing two thyristors, the anodes of which are connected to the first power supply bus, the cathodes are connected through a capacitor and connected to the anodes of the third and fourth thyristors, respectively, connected to a storage capacitor and the first choke, the second choke, the first diode 2. This device has a large size and weight. The purpose of the invention is to reduce the size and weight of the device. The goal is achieved by the fact that the KOTOpiHx anodes are connected to the first power supply bus, the cathodes are connected through a capacitor and connected to the anodes of the third and fourth thyristors, respectively, connected in series by a storage capacitor, two drossel, diode , a third choke, a second diode, a fifth, sixth thyristor, a rectifier element, the outputs of which are connected to a circuit of series-connected first throttle and an accumulator terminal, are introduced and the first input of the rectifier through the first diode and the fifth thyristor connected in antiparallel to the cathode of the first thyristor, the second input through the second diode connected in antiparallel and the sixth thyristor to the cathode of the second thyristor. The cathodes of the third and fourth thyristors are connected via successively connected second and third chokes, the common point of which is connected to the second power supply bus.

The drawing shows a circuit diagram of the device.

The device contains a power supply bus 1 and 2, the first thyristor 3, the second thyristor 4, the capacitor 5, the third thyristor 6, the fourth thyristor 7, a storage capacitor 8, the first choke 9, the second choke 10, the first diode 11, the third choke 12, the second. diode 13, fifth, sixth thyristors 14, 15, rectifying element 16.

The device works as follows.

The control signal is supplied to the thyristor .or 3 and the thyristor 6 of the upper branch, the latter are cut off, and the current in the inductor 10 begins to increase (in the inductor 10, energy begins to accumulate). The control signal is then supplied to the thyristor 7, the latter is opened, and the capacitor 5 is charged, after which the thyristor 7 automatically closes. The control signal is applied to the thyristors 4, 7 of the lower branch, the latter are opened, and current begins to increase in choke 12, and the current of the choke 10 is transferred to the circuit: terminal 1, thyristor 4, capacitor 5, thyristor 6, choke 10, power supply terminal 2. In this case, the thyristor 3 is de-energized and spontaneously closes, and the energy concentrated at that time in the inductor 10 is transferred to the capacitor 5, charging it before the voltage, twice the voltage of the storage capacitor 8.

The control signal is supplied to the thyristor 14, the latter is opened, and the dose of energy concentrated in the capacitor 5 is transferred to the choke 10 along the circuit: capacitor 5, diode 13 / rectifying element 16, choke 9, storage capacitor 8, thyristor 14. In this case The rectifying element 16 prevents the recharging of the metering capacitor 5 with the opposite sign and provides the latter with a zero level after the discharge voltage.

The control signal is supplied to the thyristor 6, the latter is opened, and the capacitor 5 is charged through the circuit: thyristor 4, capacitor 5, thyristor 6, throttle 10. Thereafter, the thyristor 6 spontaneously closes. The control signal is supplied to the thyristor 3 and the thyristor 6, the latter are opened, and the current in the inductor 10 begins to increase, and the current of the chokes 12 is transferred to the circuit: power supply terminal 1, thyristor 3, capacitor 5, thyristor 7, choke 12, terminal 2 In this case, the thyristor 4 is de-energized 15 cs and spontaneously closes, and the energy concentrated at that time in the throttle 12 is transferred to the capacitor 5

Next, the control signal is supplied to the thyristor 15, and the dose of energy concentrated in the capacitor 5, as described above, passes to the storage capacitor 8 through the circuit: capacitor 5, diode 11, choke 9, capacitor 8, thyristor 15.

Thus, by alternately feeding the control signals to the corresponding thyristors, the storage capacitor 8 is charged with equal doses of energy previously concentrated in the capacitor 5, i.e. the capacitor is charged at a constant charge cycle for taking power from the mains.

The advantage of the proposed device for charging the storage capacitor in comparison with the prototype is the absence of a step-up transformer at the input, which reduces the weight and dimensions of the device.

Claims (2)

1.Bulatov K.N. and others. Thyristor 60 high-intensity switching circuits light sources. M., Energie, 1976, fig. 4.28, p. 117. 2.Sb. The Problem of Technical Electronics, Vol. , Nauko65 VA Dumka, 1970, p. 103, fig. one. /four