DE632614C - Multi-system pipes with built-in coupling element - Google Patents

Description

The invention relates to the development of a multiple tube according to patent 631 239, in which several electrode systems (e.g. three) with the groups of coupling elements (ζ. B. two) are combined in one tube.

As is well known, the multi-system tubes have achieved the task of truly aperiodic amplification over a very large frequency range. With the multiple tubes built up to now, low-frequency, medium-frequency and high-frequency voltages can be ^{amplified evenly up to a frequency of about 3 ° e of} the so-called cut-off frequency. This was made possible by the fact that the harmful capacitances were substantially reduced by shortening the connecting lines between the electrodes by installing the entire circuit in a vacuum space.

The invention provides a further

Shortening of the connecting lines achieved and thus a new frequency range for uniform reinforcement tapped. Of course, an even amplification of the low-frequency, medium-frequency and high-frequency currents generated. According to the invention, a shortening of the circuit wires and a Reduction in the number of melts achieved by the fact that those in the multi-system tube arranged coupling elements in a _ special container made of glass are.

Embodiments of the invention are explained in the figures.

Fig. Ι shows the coupling elements a, b, c in the usual combination with the connections to the Anödet, the anode battery B and the cathode K or the grid G of the following tube installed in a common glass vessel. This vessel can be evacuated or filled with gas. This' installation of the coupling elements in a carrier vessel has a number of advantages, e.g. B. considerable space savings, elimination of two pumping processes, reduction of the six lead-through wires to four and

*) The patent seeker stated that the inventors were:

Dr. Siegmund Loewe in Berlin-Steglitz and Bruno Wienecke in Berlin-Mahlsdorf '.

thus considerable cheaper production. -

Fig. 2 is a side view of the diagram shown in Fig. I. illustrated embodiment. For the Melting the so assembled

elements in the glass vessel, expediently the two ends of the glass tube '* squeezed around the lead-through wires with a suitable device. This simple and equally flawless method can not be applied as for the implementation of a single wire, such a pinch un- "^'1 O is relatively wide for the separately built-in glass vessels coupling elements.

The horizontal section shown in Fig. 3 shows that the coupling elements are expediently arranged to save space in the corner points of an equilateral triangle. This arrangement is particularly recommended when the cross-section of the glass vessel is a circle. But it is also possible to give the glass vessel a different cross section, for example an ellipse. ^a 5 In such a case, the coupling elements are also expediently arranged somewhat differently.

Fig. 4 shows how the connecting lines can be shortened further within the glass vessel. If the connections to the cathode K and the grid G are interchanged with one another, the two connections of the capacitor h to the resistors α and c above can be made. The invention is in no way limited to the embodiment shown in FIGS. If the coupling elements are particularly small, one-sided fastening in the carrier material is sufficient. Fig. 5 shows such an embodiment. Here the coupling elements are built into a glass vessel in a similar way to the electrodes of a single-system tube. A special foot d is provided in which all four lead-through wires are melted.

The coupling elements according to the invention can also be used independently of the use Manufactured in multiple tubes as a switching element are used to interconnect several individual ones Tubes, for example as resistance amplifiers. Compared to the interconnection of single tubes customary use of individual elements result in multiple advantages, for example that the The position of the circuit elements in relation to one another is constantly constant, and so are the secondary capacities are not subject to any change between the individual coupling elements. The arrangement of capacitors in an atmosphere of chemically inert gases (in particular those gases that are chemically ineffective against the dielectric and the other contents of the tube ■ to the temperatures under consideration) is , not limited to the interconnection. Elements, but can also be used ■ are if capacitors are housed in a glass vessel in groups of several are. One of the numerous advantages is the ability to use higher loads, especially when using solid dielectrics, e.g. B. Mica wound capacitors (um a good temperature equalization between the parts of the capacitors that heat up and the outer shell, for example the glass shell).

The optimal pressure that is given to such gas fillings depends on whether the relevant switching elements are to be installed in multiple tubes or other vacuum vessels or whether they are to be used for interconnecting single tubes, i.e. under atmospheric pressure. In the last-mentioned case, it is easily possible to use a gas filling that is more than ι atm even in the event of temperature increases. Owns pressure. In the case of such capacitors being arranged in a vacuum, on the other hand, when dimensioning the pressure, it should be noted that the entire pressure is considered to be excess pressure; therefore, in such cases, the gas pressure must be kept correspondingly lower. In such cases it will often not be possible to go over 200 mm of gas pressure; 100 to 200 mm have proven to be advantageous. At such nitrogen pressures, the pressure of the gas filling is generally so high that the permissible one. Operating voltage an ionization does not yet occur. On the other hand, then the still low enough that when the permissible heating of the capacitor and possibly with built-in resistors not so considerable overpressure in _t inside arises that even if some in multiple tubes for attaching a vacuum (a burst of the glass vessel is to be feared ) this internal pressure is not opposed by any external pressure.

The gas fillings are nitrogen, neon, helium and hydrogen.

Claims (1)

Patent claims: i. Multi-system pipe with built-in coupling element, the individual parts of which (e.g. Anode resistor, grid block capacitor and grid lead resistor) to one mechanical unit are connected, according to claims 5 to 8 of patent 631 239, characterized in that the Capacitor as well as the resistors against each other immovable in a common, arranged inside the multiple tube arranged container made of glass are. .;. ";" '"· 2. Multi-system tube according to claim i, characterized in that the container ^ with chemically inert, heat-dissipating Gas is filled. 3. Multi-system tube according to claim 1 and 2, characterized in that the '' V-coupling elements on the melting > · .- place the supply lines through the container V wall are attached. 1 sheet of drawings