RU2258299C1 - Tube amplifier with directly intercoupled stages - Google Patents

Abstract

FIELD: high-frequency sound reproduction.

SUBSTANCE: proposed tube amplifier whose stages are directly intercoupled and are separately supplied with power has anode of first tube VL1 connected to grid of second tube VL2, and resistor R2 is inserted between their common point and cathode of second tube VL2; cathode of second tube VL2 is connected to positive pole of first-stage power supply E2 and to negative pole of second-stage power supply E3.

EFFECT: reduced distortions of amplified signal.

4 cl, 4 dwg

Description

This invention relates to the field of high-quality sound reproduction in terms of amplification devices.

To eliminate or reduce the effect on the sound quality of radio elements in amplifying devices, they seek to reduce the number of both active and passive radio elements along the path of the sound of an electric signal. Experts well appreciate the sound of DC amplifiers included in the amplification circuit of an audio electric signal.

The closest analogue of the invention is the amplifier described in the journal "Radio Front", No. 2, 1931 "New Loftin White circuit."

When designing direct current amplifiers (DC) on vacuum tubes, the main task is to equate the voltage at the load of the first lamp with the bias voltage of the second lamp. This is achieved by powering the amplifier from a multi-link voltage divider, or by incorporating resistors into the cathode circuits, or by powering the CTF cascades from separate anode voltage sources.

When the amplifier is powered by a voltage divider, the anode current of the output lamp passes through the divider, which leads to spurious feedback and, as a result, to subjective deterioration in sound quality.

When resistors are included in the cathode circuit of the lamps to set the lamp modes, local negative feedback (MEP) occurs, which reduces the gain. To eliminate the action of the MOOS, resistors are shunted with large capacitors, which leads to a subjective deterioration in sound quality.

When powering the cascades of CTFs from separate sources of anode voltage, a current source or dynamic load (SRPP) is used as the load of the first lamp. In such circuitry solutions, there is negative feedback, which, according to some experts, leads to degradation of the sound of the amplifier.

The essence of the invention is to include such an active resistance as the load of the first stage of the CTF, so that when the cascades are supplied from separate sources of the anode voltage, the voltage at the load of the first stage is the bias voltage for the lamp of the second stage, without the need to include additional resistors in the cathode circuits or use multi-link voltage dividers to power the amplifier.

The technical result of this solution is the elimination of distortions arising from the passage of the signal through isolation capacitors and transformers, as well as through cathode resistors and capacitors shunting them.

In the patented amplifier, the cascades have separate power supplies connected in series, the positive pole of the first source being connected to the negative pole of the second source. Between the grid of the first lamp and its cathode, through a source of negative bias, a first resistor is connected, in parallel with which an amplified signal is connected. The cathode of the first lamp is connected to the negative pole of the first power source, and the anode through the second resistor to the positive pole of the first power source. The grid of the second lamp is connected to the anode of the first lamp, the cathode to the negative pole of the second power source, and the anode through the amplifier load to the positive pole of the second power source. In an amplifier embodiment, a third resistor is connected between the grid of the second lamp and the positive pole of the second power source.

Figure 1 and Figure 2 shows a diagram of a two-stage UPT with an output sound transformer. The difference in the circuit shown in figure 2, is the presence of a compensating resistor R3. In both schemes, the resistor R1 is the leakage resistor of the first triode VL1, R2 is the anode load resistor of the first triode VL1, which also performs the function of the leakage resistor for the second triode VL2. E1 is the bias voltage for VL1, E2 is the anode voltage of VL1, E3 is the anode voltage of the terminal triode VL2. I1 is the anode current of the first lamp VL1.

When the amplifier operates according to the circuit shown in FIG. 1, the anode current of the first lamp I1 creates a voltage across the resistor R2. This voltage has an alternating component (a useful amplified signal by Lama VL1) and a constant component, the presence of which is due to the quiescent current of the first lamp VL1. The DC component of the voltage is negative with respect to the grid of the second lamp. The resistance value of the resistor R2 is selected so that the constant voltage caused by the passage of the quiescent current through it of the first lamp is equal to the negative bias voltage for the second lamp.

If the passport value of the bias voltage of the second lamp is less than that obtained in the circuit of FIG. 1, and a decrease in the resistance of the resistor R2 leads to an unacceptable decrease in the gain of the first stage, then it is necessary to use a compensating resistor R3, indicated in FIG. 2.

When the amplifier operates according to the circuit shown in FIG. 2, the current flowing through the circuit E3-R3-R2-E3 creates a compensating voltage of positive polarity on the resistor R2. Given the supply voltage of the terminal stage E3, the voltage at the anode VL1, the bias voltage for VL2, as well as the load resistance to the alternating current of the first stage, we can calculate the values of the resistances R1, R2, as well as the supply voltage of the first stage E2.

The circuit shown in FIG. 3 is a push-pull version of the amplifier, and the circuit shown in FIG. 4 is a push-pull version of the amplifier with compensating resistors R3 and R3 ′.

Claims (4)

1. A tube amplifier with direct interstage communication and separate cascade supply, characterized in that the anode of the first lamp is connected to the grid of the second lamp, and a resistor is connected between the point of their connection and the cathode of the second lamp, while the cathode of the second lamp is connected to the positive pole of the power supply of the first cascade and to the negative pole of the power source of the second cascade. 2. The tube amplifier according to claim 1, characterized in that a resistor is connected between the grid of the second lamp and the positive pole of the power source of the second stage. 3. The tube amplifier according to claim 1, characterized in that it has two identical arms for amplification in push-pull mode. 4. The tube amplifier according to claim 2, characterized in that it has two identical arms for amplification in push-pull mode.

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