DE720084C - Tube heated with alternating current or pulsating direct current, which contains at least cathode, anode and control grid - Google Patents

Description

Tubes heated with alternating current or pulsating direct current, which contains at least cathode, anode and control grid. The invention relates to measures to reduce the amount that occurs with discharge tubes with indirectly heated cathodes Hum interference.

Indirectly heated cathodes are practically never fed with pure direct current, but mostly with mains alternating current of 50 Hz. In addition, heating with alternating current of higher frequency, which is obtained from a direct voltage source by means of a chopper, or mains direct current, which is practically always one, is also possible AC component is superimposed. As is well known, this causes hum disturbances, the absolute value of which has hitherto been attempted to be kept small by means of circuitry or structural measures. It is already known to twist the heating leads to form a tube and to bring the shielding of this lead right up to the tube pins and also to surround the base of the tube with a metal sleeve. This reduces the external stray fields; However, a complete elimination of the hum is not possible, since the hum inside the tube cannot be detected. - Using Fig. I, an overview of the different types of interference voltage generation is to be given. Fig. I shows a tube i with the anode , a grid 3 and an indirectly heated cathode, the equipotential layer of which is denoted by q. and its heater is denoted by 5. The alternating heating voltage is supplied by a transformer 6. 7 with an adjustable voltage divider is referred to, with whose tap the circuits connected to the discharge electrodes are connected. The anode circuit resistance is denoted by 8, the grid resistance by g and the cathode resistance frequently used to generate a negative grid bias is denoted by io; the latter is usually bridged with a capacitor ii of large capacitance, about 20 microfarads. There are the following possibilities for the emergence of an interference voltage in the anode circuit (see - the work of the inventor in the journal "Die Telefunkenröhre", issue 12, page 6 ff.) the heating circuit, in particular by the heating wire ends on the grid, b) the static anode hum, which is caused in the same way by capacitive voltage transmission from the heating circuit to the anode, c) the induction hum, which is caused by inductive transmission of alternating voltages from the heating current lines into the Leads to other electrodes, in particular to the control grid, arise, d) the magnetic hum, which is caused by the stray magnetic field of the heating wire and influences both the electron space charge near the cathode surface and the direction of the electron paths, e) the insulation hum, which is caused by the insulation current arises, which the I insulating layer flows through between heater and equipotential layer.

The two interference voltages listed under a and b can be used for can be practically eliminated by setting the voltage divider 7 appropriately. The induction hum can be weakened by twisting the heating current leads; it is independent of the setting of the voltage divider. The magnetic hum can be reduced by using a bifilar wound heater. aside from that one has also already had a heating current flowing through it coaxially to the electrode system Coil tries to eliminate this fault. The isolation brumin can be through a excellent insulation between the heater and the discharge electrodes and: through Application of a positive bias voltage to the heating wire with respect to the equipotential layer be counteracted. However, none of these measures bring about a complete elimination of all hum disturbances.

According to the invention is therefore with an alternating current or pulsating Direct current heated tube containing at least cathode, anode and control electrode, the spatial arrangement of the heating current supply lines and the other electrode supply lines, in particular the supply line to the control electrode, within the vacuum vessel and of the base so that the inductive and capacitive through the heating current leads Ripple voltages transmitted to the other leads correspond to the ripple voltages transmitted to the control electrodes or Anode leads alone counteract transmitted ripple voltages and become in their effect on the anode current for a prescribed working point and prescribed Remove grid and anode circuit resistances completely or except for a harmless remainder.

The invention is based on the consideration that the various interference voltages differ from one another in terms of their phase relation to the heating voltage. the both statically transmitted ripple voltages rush in phase by 9o "against the AC heating voltage before, while the induction ripple voltage has a phase lag of 9o '. The one generated by the magnetic influence of the discharge current Hum generally manifests itself in an anode alternating current component twice that Frequency of the heating current. The insulation ripple voltage is essentially ohmic, d. H. konphas, with the alternating heating voltage. In some cases, however, it also shows a reactive component.

This possibility is particularly easy to see with regard to the static and the inductively transmitted interference voltages a-c, as these differ from each other by i8o ' are out of phase. So you just have to make sure that the The amplitudes of the interference voltages appearing at the anode in both phase positions are mutually exclusive are equal to achieve total annulment. So far you have, as already known, the static ripple voltages against each other by setting the voltage divider 7 in Fig. I and when assembling the tube made sure that the transmitted interference voltage amplitude is not too large per se. The induction ripple voltage but cannot be influenced at all by means of the voltage divider, so that Up to now one had to be content with using twisted cables as much as possible to achieve a small value of this interference voltage component. In carrying out the invention In contrast to before, one proceeds in such a way that these two tensions are not each disappear for themselves, but merely counteract each other. It is obvious that you can make the tube construction considerably easier "because one the shield and decoupling the interacting electrodes does not need to go to extremes. The capacity between the heater and the other electrodes or electrode leads are given by the sequence the melts in the pinch foot and through .the distance and the thickness of the supply lines largely in hand. Also the mutual induction between two lines can be done by choosing a suitable distance and a suitable length of the supply lines influence as desired.

But it is also a further elimination of the interference voltages possible. For example, it is also possible to cancel an existing one Reactive component of the insulation ripple voltage, which is caused by electrochemical polarization phenomena is generated in the insulating layer between the heating wire and the cathode. Due to hysteresis phenomena Within the cathode insulation, the insulation hum can also be an inductive reactive component obtain. On the other hand, the electrostatically transmitted grid and anode hum have an ohmic component as soon as between the heating wire and the grid or between The heating wire and anode have an ohmic conductivity; so it is also one The isolation hum can be canceled by the other cause of the hum.

It was noted earlier that the magnetic hum is mainly occurs at twice the frequency of the heating voltage. Often the isolation hum also points partly double the heating voltage frequency, because the insulation layer between Heater and 'A' equipotential layer of the cathode in the hot state are non-linear Has current-voltage characteristic, i.e. represents a voltage-dependent resistance. But this means; that a rectifier effect occurs in this part of the current path comes, which explains the occurrence of the double heating voltage frequency without further notice. It is also possible to compensate for this interference voltage of twice the frequency.

It should also be noted that the individual hum components can be distinguished by measurements so that it is possible to determine whether the level of freedom from interference achieved is a consequence of the fact that the with noticeably strong existing interference voltages cancel each other in their effect or that they are in themselves vanishingly small. For example, the static disappears transmitted grid hum when short-circuiting the grid resistor 9. Likewise, can the isolation hum for the most part - by short-circuiting the cathode resistor io, through which the insulation current flows, can be made to disappear. Of the statically transmitted anode hum disappears when the discharge current is locked by a high, negative grid bias. The magnetic hum also disappears with small current. The last two interference voltages mentioned differ, as already mentioned, in terms of their frequency. The one with twice the line frequency Occurring magnetic and insulation ripple voltages differ from each other in that: the latter is temperature-dependent, so that it is influenced by the heating current being affected. The isolation hum can also be reduced by applying a positive bias voltage of the heating wire are throttled against the equipotential layer. The observation it is expedient to carry out the beam in two coordinate directions by means of a Braun tube is deflected, namely in one coordinate by the alternating heating voltage and the other interference voltage conducted via a measuring amplifier. One can from the location and shape of the ray trace appearing on the luminescent screen directly on the phase and amplitude ratios of the interference voltages and their origin.

As noted earlier, it is through appropriate spatial arrangement the supply lines to the heating wire, to the control grid and to the anode possible, the hum disturbances on the tube itself for a certain operating point and prescribed resistances of the grid and anode circle. The working point plays a role because of it the effective steepness and amplification of the transmitted to the grating Ripple voltages depends. On the other hand, z. B. a capacitive from the heating wire The ripple voltage transmitted to the control grid disappear when the grid bleeder resistor is removed to zero or short-circuit. In order to get a To achieve mutual cancellation of the interference voltages, can also outside adjustable capacitive or inductive coupling means are provided for the tube. Both arrangements have an ohmic voltage divider, such as the resistor 7 in Fig. I, the advantage that they do not consume any cross flow.

In Fig.2 the dosage of the static is shown as an exemplary embodiment Grid hum represented by a differential capacitor. So much for this and in the following figures the same components as in Fig. i are shown the same reference numerals as used there. The differential capacitor 12 has two fixed assignments which are connected to the two ends of the heater 5. the middle, movable occupancy is connected to the control grid 3. By setting the medium occupancy, such a large alternating voltage can be fed to the control grid that the choice of unforeseen values of grid and anode resistance and the residual hum interference caused by the operating voltages or is brought to a minimum. The cathode q. is z. B. fixed to the center the secondary winding of the heating converter 6 is connected.

A modification of this arrangement is shown in Fig.3, in which the adjustable Assignment of the differential capacitor 12 not with the control grid, but with the anode 2 is connected.

According to fig. Q. the compensation of the remaining interference voltages takes place inductively by setting the mutual inductance between two lines through which the heating current flows and another line connected to the cathode. In the heating circuit, two parallel wires 13 and 15 are connected at a fixed distance of about a few millimeters. Between them is a wire 1q. arranged, which is displaceable by means of an adjusting screw, so that its distance from the two wires 13 and 15 can be changed until the interference voltage adjustment has occurred. Since of the conductors 13 and 15 in the conductor r q. opposite alternating voltages are induced, the size and direction of the compensation voltage can be set for the distance, which is fed to the grid or anode circuit. The in Fig. 2 to q. devices shown can also be provided in the tube base itself.

Claims (6)

PATENT CLAIMS: r. Tube heated with alternating current or pulsating direct current, which contains at least the cathode, anode and control electrode, characterized in that the spatial arrangement of the heating current supply lines and the other electrode supply lines, in particular the supply line to the control electrode, is made within the vacuum vessel and the base in such a way that the through the heating current leads inductively and capacitively transferred to the other leads counteract the hum voltages transmitted to the control electrode or anode leads alone and cancel each other out in their effect on the anode current for a prescribed operating point and prescribed grid and anode circuit resistances completely or with the exception of a harmless remainder. 2. Arrangement according to claim r, characterized in that parallel wires (13, 15) are switched on in the two heating current leads, between which a conductor lying in the grid, anode or cathode circuit is arranged at adjustable intervals. 3. Arrangement with a Tube according to claim r, characterized in that to cancel residual hum disturbances in the grid circle or the anode circle or both circles an alternating voltage of the interfering frequency capacitively or inductively transferred from the heating circuit will. 4 .. Arrangement according to claim 3, characterized by a differential capacitor with two fixed assignments connected to the ends of the heating wire and one medium, adjustable occupancy connected to the control grid or the anode is. 5. Arrangement according to claim 3, characterized by an adjustable mutual inductance between the cathode circuit and the two heating current leads. 6. Arrangement according to claim 3 to 5, characterized in that the adjustable capacitance or Mutual inductance is built into the tube base.