DE1080609B - Protection circuit for an amplifier tube - Google Patents

Description

Protection circuit for an amplifier tube The invention relates on a protective circuit for an amplifier tube, in which with the help of a relay the anode voltage and, if applicable, the voltage of another positive electrode is reduced or switched off if the requirements for the tube load are observed Limit values are exceeded, causing thermal overload and damage of the tube is to be feared.

It is known, depending on the type of tube cooling by radiation, Cooling air, cooling water or evaporation triggering the tube protection from one to derive to the temperature of the tube parts or the coolant responsive organ. Due to the delay with which the temperature increase follows the heat supply, With circuits of this type, the tube protection is not immediately activated when the Current overload effective. This can occur in the event of a sudden increase in load, such as in the event of a sudden shift in the operating point setting, lead to the tube is damaged before the protection circuit responds. One therefore prefers generally protective circuits of a different type, in which the disconnection of the Load is triggered directly by the electrode currents when they are exceed permissible limit values. For example, a protective circuit is known in which the anode current is switched off with the aid of a relay with two windings takes place, which are fed from different circles of the tube system and their magnetic excitations are directed opposite to each other. This type of circuit has, besides the possibility given by the differential principle, several To monitor circuits simultaneously, the advantage that the shutdown occurs suddenly occurring overloads occurs very quickly, but it is with amplifier stages, whose arithmetic anode current - mean value increases with the alternating current modulation, So for amplifier stages with a so-called B or C setting of the operating point, not readily applicable. In the case of an amplifier stage in B mode, for example the maximum permissible value of the anode quiescent current with no modulation is essential be smaller than the arithmetic that is available and permissible at full modulation Average anode current. The protection circuit can therefore be triggered by the latter not deduce if the protection is also against displacements of the operating point setting and the associated changes in the quiescent current should be effective.

The invention is based on the task of specifying a protective circuit, their trigger criterion directly from the current of one of the tube electrodes, preferably the anode, which is consequently derived from the response delay mentioned is free and with amplifier tubes for alternating voltages with such an operating point setting It can be applied that the arithmetic anode current mean value increases with increasing AC grid voltage increases, and at which with the help of a relay the anode voltage and optionally reduced the voltage of another positive electrode or is switched off if the operating point setting is too high a quiescent current value shifts. In order to achieve this object, the protective circuit is according to the invention in such a way designed that to actuate the relay in the event of an overload of the tube a electrical quantity is used, which corresponds to the difference in the mean anode current Size and a size corresponding to the anode alternating current at least approximately is equivalent to. This gives the circuit the property; that she is one with the AC modulation allows increasing mean anode current as required of the tube protection in the case of a B or C setting.

In the drawing are in the big. 1 and 2 two different embodiments of protective circuits for amplifier tubes, which according to the principle of the invention work. On the representation of all for the explanation of the invention non-essential parts were omitted. Fig. 3 is a current-time diagram, which serves to explain the mode of operation of the circuit shown in FIG.

The circuit shown in Fig. 1 can be used to amplify low-frequency or high-frequency = vibrations. 1 and 2 are the input terminals, 4 and 5 are the output terminals of the amplifier stage. For the sake of simplicity, a normal triode tube 3 is selected as the amplifier tube. Of course, instead of the tube 3, a pentode or some other amplifier tube could also be used. The voltage to be amplified is supplied to terminals 1 and 2 in a known manner, while the increased voltage can be tapped at terminals 4 and 5. The anode of the tube 3 is supplied with the necessary bias voltage and the anode current from the voltage source 6 via the load resistor 7. The desired negative bias of the control grid is applied to terminal -G. According to the principle of the invention, a voltage corresponding to the mean anode current and a first voltage is taken from the resistor 8 through which the anode current flows and at the same time lies in the cathode circuit. The excitation winding of the electromagnetic relay 12 is fed, while a voltage corresponding to the anode alternating current is taken from the same resistor 8 through which the anode alternating current flows and, after rectification by means of the rectifier 13, is fed to a second excitation winding of the relay 12 with such a pole that the magnetic excitations produced by the windings are directed opposite to each other. The connection used to decrease the voltage corresponding to the average anode current leads via the primary coil of the transformer 9 and the series resistor 10. The connection serving to decrease the alternating current component of the voltage lying across a resistor 8 leads via the transformer 9 to the equality 13 and via the series resistor 14 to the associated excitation winding of the relay 12. The transformer 9 forms a means for eliminating the direct current component of the resistor 8 occurring voltage. Behind the rectifier 13 are in the form of the series resistor 14 and. of the parallel capacitor 15 means are provided for filtering out the remaining alternating current component. It can be seen that a resulting excitation occurs in the magnetic circuit of the relay 12; which corresponds to the difference between a variable corresponding to the mean anode current and a variable corresponding to the anode alternating current. As a result, the circuit also allows an increasing size of the average anode current as the alternating current menu control increases, without the anode voltage source 6 being switched off with the aid of the normally closed contact 16 of the relay 12. Only when the mean anode current increases to a greater extent than is determined by the differential effect of the two relay excitations, for example when the quiescent anode current suddenly increases due to a shift in the operating point setting, the anode voltage source 6 is switched off. In this case, namely, the excitation predominates over - the left excitation winding of the relay 12 so strong that the relay attracts its armature. It can therefore be seen that the circuit shown has the property of allowing larger values of the mean anode current with increasing alternating current modulation. It can therefore also be adapted to the requirements of an amplifier circuit in which the arithmetic mean value of the anode current increases with the alternating current modulation of the amplifier tube. A protective circuit of the type shown in FIG. 1 operating according to the principle of the invention can therefore also be used for amplifier tubes which operate in the so-called B or C setting.

The amplifier circuit shown in FIG. 2 can also serve to amplify high-frequency or low-frequency voltages. Corresponding parts are denoted by the same reference numerals in FIGS. 1 and 2. In the circuit according to FIG. 2, however, in contrast to FIG. 1, the differential effect is not brought about by relay windings connected against one another, but in a different way in the part of the circuit intended for the decrease of the two interacting voltage components. Therefore, both the transformer 9 and the second relay winding are omitted. To explain the mode of operation, reference is made to the graph in FIG. 3, in which the course of the current flowing through the resistor 8 is shown over time. Ik "denotes the cathode peak current which flows when the amplifier tube 3 is fully driven. A voltage drop occurs across the cathode resistor 8 of the tube 3 which corresponds to the course of the cathode current. The areas below the curve sections k and h ' form. A voltage corresponding to this mean value is taken from the end of the resistor 8 connected to the cathode in the circuit according to FIG Relay 22. The other side of the excitation winding is connected to earth via the voltage divider 23 and further to the negative terminal of the anode voltage source via the series resistor 24. In order to allow an electrical quantity to act on the relay 22 according to the principle of the invention, which is the Difference between the arithmetic mean anode current and the anode value echselstromantenles corresponds at least approximately, a subtraction is carried out in the circuit according to FIG. 2 with the aid of a passive polarized element in the form of a diode or a rectifier element 19, by means of which the hatched areas in FIG. 3 under the curve parts k and k 'are cut away . If we look at the graph according to FIG. 3 as a recording of the voltage profile at the resistor 8, the voltage a, above which all further voltage increases are prevented by the rectifier element 19, can be selected so that the arithmetic mean value of the parts remaining below the hatched areas, in Approaching the trapezoidal voltage curve is definitely lower than the voltage value corresponding to the anode current quiescent value at which the automatic switch-off is to take place. This mean value of the trapezoidal oscillation is indicated by the quantity b plotted with broken lines. The method of setting described thus amounts to subtracting a further variable from the variable corresponding to the arithmetic anode current mean value, which corresponds to the hatched areas in FIG. 3 and depends on the size of the alternating current modulation. This quantity to be subtracted is dimensioned in such a way that the remaining residual oscillation has a mean value b which remains below the critical value of the anode current quiescent value. Due to the increase in the arithmetic anode current mean value with the alternating current modulation, no automatic shutdown of the anode voltage can be effected if this condition is met. An accidental increase in the anode current quiescent value would quickly lead to the mean value limit b being exceeded, so that a shutdown can be brought about with certainty.

It can be seen that in FIG. 2 neither the transformer 9 nor the second relay winding of FIG. 1 are required. The bridging capacitor 21 and the series inductance 20: serve to filter out interfering alternating current components, but these screen elements can also be omitted in many cases. The cut-off level a is set with the aid of the voltage divider 18 ″, one connection of which is connected to the line coming from the resistor 8 in the anode circuit and the second connection of which is connected to the polarized element 19. The third connection leads to the negative pole of a voltage source . the series resistor 17 has to take the purpose of taking into account the sensitivities of the relay 22, a part of the voltage drop occurring at the resistor 8. the setting of the average voltage value at which the relay 22 attracts its anchor and thus the anode voltage of the tube 3 turns off via the contact 16 , is also possible with the aid of the voltage divider 23 and by selecting the series resistor 24 accordingly.

It can therefore be seen that the resistance through which the anode current flows 8 a voltage is taken, which is both the arithmetic anode current mean value as well as a component corresponding to the anode alternating current. Of this Voltage becomes a magnitude approximately corresponding to the anode alternating current with the help of the rectifier element 19 is subtracted, the cutoff limit a by corresponding Voltage setting can be selected. The rectifier element 19 forms a parallel branch bridging the excitation winding of the relay, in which only when the limit voltage determined by the preload setting is exceeded Electricity flows. This limit voltage is now chosen so that the increase in the DC component of the voltage supplied to the relay when transitioning from one AC control voltage zero at full level is less than the difference between the normal quiescent current and the highest permissible quiescent current.

Claims (6)

PATENT CLAIMS: 1. Protection circuit for an amplifier tube for AC voltages with iderartiger working point setting, that the arithmetic mean value of the anode current increases with increasing grid AC voltage, at which with the help of a relay, the anadens voltage and possibly the voltage of another positive electrode is reduced or switched off when the The operating point setting shifts to an excessively high quiescent current value, characterized in that an electrical variable is used to actuate the relay (12, 22) in the event of the tube (3) being overloaded, which is the difference between a variable corresponding to the mean anode current and a variable corresponding to the anode alternating current at least roughly corresponds. 2. A circuit according to claim 1, characterized in that one of the Anode current of the tube (3) flowing through it, preferably lying in the cathode circuit Resistance (8) picked up a voltage corresponding to the mean anode current and fed to a first field winding of an electromagnetic relay (12) is, while at one of the anode alternating current flowing through, preferably the same Resistance (8) lying in the cathode circuit has a corresponding to the anode alternating current Voltage removed and after rectification of a second excitation winding of the relay (12) is fed with such a polarity that the windings produced magnetic excitations are directed opposite to each other (Fig. 1). 3. Circuit according to claims 1 and 2, characterized in that within the for acceptance the connection serving the mean anode current corresponding voltage means to weaken the alternating current component, preferably a shunt capacitor (11) and a series resistor (10) are provided (Fig.1). 4. Circuit after claims 1 and 2, characterized in that within the to decrease the the voltage corresponding to the anode alternating current serving a means for Attenuation or elimination of the direct current component, for example a transformer (9), is provided (Fis. 1). 5. Circuit according to claim 1, characterized in that that on one of the anode current of the tube (3) flowed through, preferably in the cathode circuit lying resistor (8) a voltage is taken, which is both a middle Contains anode current as well as a component corresponding to the anode alternating current, and that as a means for electrically subtracting one of the anode alternating current approximately corresponding size of the voltage picked up at the said resistor the excitation winding of the relay (22) at least partially bridging parallel branch is provided in which by switching on a passive polarized element (19), for example a diode, current only when a predetermined value is exceeded Limit voltage flows, which is chosen such that the increase in the direct current component the voltage supplied to the relay during the transition from an AC control voltage Zero to full scale is less than the difference between the normal Quiescent current and the highest permissible quiescent current (Fis. 2). 6. Circuit according to claim 5, characterized in that a resistor voltage divider for setting the limit voltage (18) is provided, one connection of which with that of the one in the anode circuit Resistance (8) coming line, whose second connection to the polarized one Element (19) and its third connection to the negative pole of a bias voltage source connected (Fis. 2). Publications considered: German patent specification No. 430 102.