DEP0054794DA - Mains connection device for alternating current - Google Patents

Description

In the art of electron tube circuits, it is generally customary to obtain the anode voltage from a mains connection device which generates the direct voltage from the usual alternating current network, possibly via a transformer, by rectifying it. Such devices, if they use indirectly heated electron tubes, often have the disadvantage that a high DC voltage arises shortly after switching on, which only decays when the indirectly heated tubes have reached their operating temperature and the anode current begins to flow. This means a very considerable overstressing of the sieve means, which as a result have to be designed for a higher tension. This undesirable effect occurs especially when a directly heated rectifier tube is used, as it is heated up much faster than that of the indirectly heated tubes and, as a result, the voltage peak lasts a particularly long time. But even with indirectly heated rectifier tubes, such as those that are common in so-called all-current devices, the case will often arise that the rectifier tube is more heated than the connected electron tubes.

The invention now aims to improve such network connection devices for alternating current with rectifiers and filter means for electron tube circuits with indirectly heated tubes and is characterized in that the filter resistor arrangement has a negative temperature coefficient.

The use of resistors with a negative temperature coefficient is known per se in electron tube technology, but so far they have only been used to protect lighting lamps that are in series with the heating filaments of the tubes, as is the case with all-current devices, i.e. for optional connection to DC or AC networks is common.

The subject matter of the invention will now be explained in more detail with the aid of the enclosed circuit diagrams and the exemplary embodiments described below.

In Figure 1, a filter circuit consisting of the charging capacitor 2, the filter resistor 4 and the filter capacitor 3 is connected to the rectifier tube 1 of the mains connection device for alternating current in order to free the direct voltage as far as possible from the superimposed alternating voltage. In the exemplary embodiment, the alternating voltage is fed to the rectifier 1 via the transformer 6. According to the invention, the screen resistor 4 is now designed so that it has a negative temperature coefficient of a suitable size in order to eliminate the voltage spike after switching on. For this purpose, it is also necessary that a load resistor 5 is present parallel to the filter capacitor 3, so that a voltage divider is formed from the resistors 4 and 5 for the direct voltage. The resistor 5 can be formed, for example, by a resistor in the connected electron tube circuit, as is customary, for example, for producing a negative grid bias in radio receivers by switching on a special voltage divider. In the latter case, for example, let the resistor 5 be 20 kSt. It is then expedient to give the screen resistor 4 such a rating that when cold has a resistance of approx Size decreases, which is caused by the required sieving.

However, it is not absolutely necessary to design the entire resistor 4 as a resistor with a negative temperature coefficient, but this resistor with a negative temperature coefficient can also be placed as a series resistor in front of a fixed filter resistor, e.g. a filter throttle, as shown in Figure 2. The filter throttle 7 in FIG. 2 then need not be selected to deviate from the usual dimensioning, provided that the upstream resistor 8 with the negative temperature coefficient is given a corresponding dimensioning.

In order to stay with the above example, it would now be advisable to dimension the resistor 8 so that it again has 10 kSt in the cold state, but only 200 ohms in the warm state. This resistor can be designed in the usual way as a uranium thermistor or a so-called capillary thermistor and is expediently combined spatially with the filter throttle to form a structural unit. In particular, it will be expedient to arrange the existing connection soldering lugs of the filter throttle in such a way that the thermistor can be soldered to it directly.

A radio receiver with three indirectly heated tubes and a tuning indicator tube, also with indirect heating, which is fed by a special heating winding of the transformer 6, is chosen as an example of the profit brought about by the application of the invention. With a normal DC operating voltage of 250 volts, the voltage shortly after switching on is around 420 volts. If, on the other hand, a temperature-dependent resistor is used according to the invention, there is practically no appreciable increase in voltage and the capacitors of the filter element do not need to be dimensioned for a higher test voltage. The same also applies to other blocking capacitors still present in the receiving device, which are also exposed to a higher voltage at the first moment in the usual switching.

If radio receivers are mentioned in the foregoing, the subject matter of the invention is in no way restricted to this; rather, it is just as important in other electron tube circuits, e.g. in oscilloscopes or other tube measuring circuits, furthermore in force amplifiers, transmission amplifiers, electrical test devices and the like.

Claims (6)

1. Mains connection device for alternating current with rectifier and filter means for electron tube circuits with indirectly heated tubes, characterized in that the filter resistor arrangement has a negative temperature coefficient. 2. Arrangement according to claim 1, characterized in that the screen resistor itself has a negative temperature coefficient. 3. Arrangement according to claim 1, characterized in that the screen resistor, which is formed in particular by a screen throttle, a resistor with a negative temperature coefficient is connected upstream. 4. Arrangement according to claim 2, characterized in that the resistor with the negative temperature coefficient is dimensioned so that the cold state approx. 10 kSt., In the warm state, however, has 1000 - 2000 ohms when the resistor is parallel to the filter capacitor approx. 20 kSt. amounts to. 5. Arrangement according to claim 3, characterized in that the resistor with the negative temperature coefficient is dimensioned so that it is approx. 10 kSt in the cold state kSt. amounts to. 6. Arrangement according to claim 3-5, characterized in that the resistor with the negative temperature coefficient is structurally connected to the screen resistor, in particular the screen throttle, to form a spatial unit.