DEP0040686DA - Circuit arrangement for hum compensation - Google Patents

Description

It is known (DRP 330 275, Fig. 4) to connect a voltage divider in parallel to the anode voltage source of a tube and to connect the cathode of the tube to a tap of this voltage divider selected in such a way that the grid voltage tapped from one partial resistor of this voltage divider converts the ripple current into compensated for the tube. It is also known (USA patent 1 806 813) to switch a capacitor into this voltage divider so that the voltage divider does not consume any additional direct current.

As is known from radio receivers, hum compensation is particularly necessary when the anode voltage of the output tube is taken from the charging capacitor. In this case, the invention shows how it is possible to avoid additional switching elements for the voltage divider mentioned.

According to the invention, when the anode voltage of the output tube is drawn directly from the charging capacitor, the following switching elements form the voltage divider for hum compensation: The filter resistor and filter capacitor used for the anode and possibly screen grid voltages of the preliminary stages and the resistor used to generate the negative grid bias for the output tube.

The invention is explained in more detail below with reference to the illustration serving as an exemplary embodiment. The end tube of the amplifier is labeled 3 and the rectifier tube of the power supply is labeled 1. The anode and protective grid voltage of the output tube 3 are taken directly from the charging capacitor 2.

A voltage divider 4, 6, 5, at the tap 10 of which the cathode of the end tube 3 is connected, is located parallel to the charging capacitor 2. The capacitor 6 must be of such a size that the alternating current flowing through the voltage divider does not undergo any noticeable deformation or a noticeable phase shift in relation to the alternating voltage to be compensated. Since there is no direct current flowing through the voltage divider, the partial resistors 4 and 5 of the voltage regulator can be designed with low resistance and the resistor 5 can be given a value such that the correct bias voltage for the tube 3 is tapped from it. The ratio of the resistors 4 and 5 to each other must be selected according to the gain of the tube. Then the ripple alternating current in the tube 3 is compensated. The resistor 4 and the capacitor 6 also form a filter element for the anode and screen grid voltages of the pre-tubes.

Finally, it should be pointed out that the circuit described can not only compensate for ripple voltages that are fed through the anode and screen grid lines to the tube whose grid is supplied with the compensation voltage. In many cases, a disturbing ripple voltage is already applied to the grid of this tube, for example from a pre-tube. If this ripple voltage component is in phase or antiphase with the ripple voltage component that is intentionally fed to the grating for compensation, then this additional hum component can also be compensated for by changing the compensation ripple voltage accordingly.

Claims (2)

Circuit arrangement for hum compensation in the end tube of an amplifier using a voltage divider which is connected to the anode voltage source and at whose tap the cathode of the end tube is connected and from its positive end the anode voltage of the end tube without a filter element and from its negative end the grid bias of the output tube without a filter element is taken, characterized in that when the anode voltage of the output tube (3) is taken directly from the charging capacitor (2), the following switching elements form the voltage divider for hum compensation: The filter resistor (4) and filter capacitor (4) used for the anode voltage and possibly the shield voltage of the preliminary stages. 6) and the resistor (5) used to generate the negative grid bias for the end tube. 2) Circuit arrangement according to claim 1, characterized in that the protective grid voltage of the end tube is taken directly from the charging capacitor (2).