SU623243A1 - Ripple filter - Google Patents

Description

(54) FASTENING FILTER

The non-inverting input of which is connected to the output of the first differential amplifier, the inverting input and the output respectively to the output and input of the terminal amplifier, and the control input is connected to the output of the load current sensor.

The drawing shows a structural electrical circuit of the proposed filter.

The smoothing filter contains choke 2 connected in series between one of the input source bus 1 and common bus and load 3 and the electronic equivalent of capacitance made as the first differential amplifier 4 with negative negative feedback, the non-inverting input of which is connected to the resistor connection point 5 and capacitor 6.sequential

T C-circuit connected in parallel to the load 3, and the final amplifier 7, the output of which is connected to the inverting input of the first differential amplifier 4 via an additional serial T C-tsegl 8, 9, as well as the load current sensor Yu connected between the second bus of the input source 1 signal and common bus, and additional differential controlled amplifier 11, non-inverting input of which is connected to the output of the first differential amplifier 4, inverting input. and the output is respectively to the output and the input of the final amplifier 7, and the control input is connected to the output of the load current sensor iO.

The device works as follows

The depth of the local negative feedback covering the first differential amplifier 4 through the resistor 12 and the T C circuit 8.9 decreases with increasing frequency, due to a decrease in the capacitance, resulting in the gain of the alternating voltage of the differential amplifier 4 and the gain in the feedback loop The signals formed by the serially connected first and additional differential amplifiers 4.11 and terminal amplifier 7 increase with increasing frequency of the smoothing signal. Therefore, the resistance between the output of the terminal amplifier 7 and the common bus decreases inversely with the signal frequency in the same way as the capacitance resistance and shunts the load 3 of the filter.

The drossel resistance 2 increases with increasing frequency and the decreasing resistance of the equivalent capacitance forms a frequency-dependent voltage divider with a low-frequency type transmission characteristic providing a smoothing effect,

The JA circuit 5, 6, smoothing the variable component of the output voltage of the filter, sets the non-inverting input of the differential amplifier 4 continuously into the component of the output voltage of the filter, which, when the resistance value of the resistor 12 is smaller than the input resistance of the differential amplifier 4, passes without changes through the amplifier 4 and the additional differential — the real amplifier 11 with a single static voltage gain at the input of the terminal amplifier. 7. When the differential load current 3 to the control input of the additional differential controlled amplifier 11 receives a signal differential from the sensor 1O.

An additional differential controlled amplifier 11 converts this difference to a pulse of such a shape that is required to change the gain according to the law of rapid increase and then gradually decrease the gain to the original static level. Therefore, according to the signal from sensor 10, the gain is increased by increasing the output impedance of a voltage follower formed by an additional differential controlled amplifier 11 and terminal amplifier 7 covered by one hundred percent feedback, and thus increasing the value of the equivalent capacitance.

As a result, the amplitude of the output voltage of the filter is reduced. The gradual return of the gain of the additional differential controlled amplifier 11 to the initial level as the filter decays to a load drop 3 restores the original value of the output impedance of the filter corresponding to the specified level of smoothing and low power dissipation on the final amplifier 7. Since load drops 3 are relatively rare, This increased power dissipation in the final amplifier 7 during the transient response of the filter to the load differential does not increase the slip s average losses substantially without reducing the efficiency and increasing a device size due teprootvodov.

The proposed device reduces the instability of the output voltage of the filter with changes in load.

Claims (1)

1. US Patent No. 367О23О, cl. 321-1O, 1972.