DE720448C - Push-pull shortwave tubes with two discharge systems within one piston - Google Patents

Description

Push-pull shortwave tube with two discharge systems within one Pistons For reinforcing and fanning short waves below your meter Wavelength (ultra-short waves) are often used push-pull circuits. The invention- relates to a push-pull tube for shortwave, in which two electrode systems in: one Pistons are structurally combined in such a way that the requirements of short-wave operation are particularly largely fulfilled.

There are multi-system tubes known in which the cathode is radial Connect Absehirrnr walls, between which dife cold electrodes of the; against each other shielded electrode systems are arranged. There are also push-pull shortwave tubes known the one the two. Electrode systems contain a common screen grid; this screen grid carried a constant potential and thereby caused a effective reduction in anomalous reaction, but was unsuitable for the two Electrode systems effectively to, decouple.

To the shortcomings of the known. Arrangements. eliminate it in one Push-pull KuTzwellenröhre rides two discharge systems within one bulb, in which at least one grid of the one system with an equivalent grid of the other system is directly connected, according to the invention a solid metal plate provided, which electrostatically shields the two electrical ensysbexne from one another and to each of which an operational AC voltage-free grid of the two electrodes system @ e is connected directly and without induction.

This measure does not merely reduce the anode reaction within of the individual systems are effectively suppressed, but become the The two electrode systems are also shielded from one another so that they leave one another cannot interfere with what is happening with regard to the two electrode systems Eating alternating voltages oscillating in opposite phase is very important.

The marked arrangement should initially be on a tube with two Penthoid systems are explained. For operation with short shafts it is necessary that the voltages of the auxiliary electrodes, d. H. the screen grid and the brake grid, do not have any AC voltage components. It is also necessary: that both Electrode systems are well shielded from one another, d. H. that the fields of one Systems does not affect the ixn. other system have electrons flowing. An embodiment in which both requirements are met particularly well, Fig. i shows. Here are 1 (l and 92 two hot cathodes. G2 surrounded. are. This is followed by the screen grids SG1 and SG2, the braking grids BG, and BG2 and the Ariods Al and A2. According to the invention, the screen grids should now or the brake grilles are structurally combined with a shielding plate P in such a way that that P serves as a support for two similar grids. In Fig. I z. B. the cut-off plate P as a carrier of the braking grid BG, and BG ",. For a union" - ung the screen grid Basically, the same considerations apply to the shielding plate. By deal Connection of the auxiliary grid to this shielding plate is made. the structure is particularly stable, and the auxiliary grids are electrically connected to one another by the shortest route. Since the control grids @ work in push-pull, both brake grids run in opposite directions the same alternating currents, which arise from the inflation of the moving electrons. These Alternating currents of the two braking grids can be as short as possible over the shielding plate P. Equalize paths; they add up, and the resulting alternating current of the retarder grids becomes zero, so that the braking grid, even if it has a noticeable inductance are connected to earth, do not carry alternating voltages. If the brake grids were over one Line of noticeable length, e.g. B. outside the tube connected, this line would have There was some inductance, which combined a noticeable impedance at high frequencies surrender to tvvürde. A compensating alternating current between the grids would then become one Bring the grid against earth or cathode. To also the opposite equal screen grid alternating currents within the tube and thus to avoid an alternating voltage of the screen grid, this is the case with the one shown in Fig. i the arrangement shown necessary, the two screen grids by powerful, practical To connect induction-free and resistance-free brackets with each other.

Particularly favorable in terms of avoiding alternating screen grid voltages at the front behaves like the arrangement shown in Fig. This execution creates a structurally simple and electrically flawless grounding of the screen grids. The braking grids BG, and BG. are connected to two metallic plates P1 and P2. Under the intermediate layer in front of insulating strips J, such as. B. Glimmeer, is isolated from the shielding plates P1 and P2 placed the shielding plate P3 between them, which is connected by the shortest route to both screen grids SGl and SG. This creates a capacitive one between the grounded brake grids and the screen grids Short circuit. You then do not need a capacitive grounding of the screen grid outside the tube, due to the inevitable inductance of the Supply lines of the screen grid impedances would arise, the fluctuations of the screen grid potentials cause.

Claims (2)

PATENT CLAIMS: i. Push-pull shortwave tube with two discharge systems within a bulb, in which at least one grid of one system is directly connected to an equivalent grid of the other system, characterized by a solid metal plate, which electrostatically shields the two electrode systems from one another and to each of which an operational grid that is free from AC voltage of the two electrode systems is connected directly and without induction. 2. Push-pull shortwave tube riding two five-pole electrode systems and according to Screen grids connected to a screening plate (P3), characterized in that that the two brake grids are arranged on one of two on either side of the shielding plate insulated metal plates (Dl, P2) are connected.