DE675666C - Ion discharge tube with glow cathode, in which several independently controllable organs are arranged essentially in the same equipotential area of the electrostatic field existing between cathode and anode - Google Patents

Description

Ion discharge tube with hot cathode in which several are independent of each other controllable organs essentially in the same equipotential area of the between Cathode and anode existing electrostatic field are arranged The invention relates to ion discharge tubes with hot cathode, in which several are independent of each other controllable control organs symmetrical and in the same equipotential area of the between Cathode and anode existing electrostatic field are arranged.

Under ion discharge tubes should be with gases, vapors or a mixture of both filled grid-controlled rectifier tubes can be understood. Power converter Various types and relay circuits are used for these tubes.

Ion discharge tubes work, of some specific embodiments apart from, in general, 'discontinuous. That. Onset of the anode current takes place only after reaching an anode ignition voltage caused by the existing grid potential instead, the anode current, once present, cannot be continuously influenced like a high vacuum triangle, electrode tube, and the grid achieves its blocking effect only back when the anode current has reached the zero value again and the ionization the discharge path has disappeared again.

Instead of the anode current-grid voltage characteristic of the high vacuum tube is used to identify the ion discharge tube, the ignition characteristic, which the Anode ignition voltage as a function of the grid potential applied between cathode and grid, reproduces.

In the case of ion discharge tubes with two or more control grids, difficulties arise in technical practice as soon as it is a question of Manufacture tubes in which the above-mentioned ignition characteristic for two of these grids should be the same. It. is generally used with these tubes, to arrange the grids one behind the other in the discharge path, so that, for. B. that. one grid is the cathode, but the other grid is closer to the anode. In many Cases this is done in such a way that the grids are graded in size and are arranged concentrically so that the larger grid is the smaller surrounds.

A consequence of this grid arrangement is that the ignition characteristics for both grids not because of the different electrostatic conditions, are exactly the same. However, there are cases in which the ignition characteristics are affected nveier grids special value is placed, e.g. B. when two grids in one circuit alternately the same Function or if the relay tube should be influenced from two different sides in an equivalent way:

It is now also known in ionic ,. discharge redder several as a whole separates in the same level area: =. different, independent to provide mutually controllable control organs.

But lattice structures are used in a known manner for such tubes related to several control openings or shaft grids, this is how the Disadvantage that in the ignition of the tube 'irregularities arise because the electrostatic ratios of the various parts of the grid are different and so. the use of the discharge, depending on the circumstances, through a different part of the grille being affected.

This secondary mile is used for ion discharge tubes with hot cathodes, in which several independently controllable organs are essentially symmetrical and in the same equipotential area of that between cathode and anode Electrostatic field are arranged, according to the invention remedied in that the Control organs sector-shaped, equally sized, in a plane perpendicular to the axis and parts arranged around the axis of the electrostatic field with equal central angles one. represent plate-shaped or box-shaped bodies, which by radially extending, Slit-shaped spaces that do not allow the discharge to pass through are separated from one another and that for: the passage of the discharge on each control electrode in the vicinity the same as the axis, together forming the passage opening for the discharge are provided.

The invention is based on an embodiment shown in the drawing are explained in more detail. FIGS. I and 2 show a relay tube according to the invention in vertical or horizontal cut. The discharge vessel i of the tube is through formed a glass bulb and a little foot. On the in, the foot 2 melted Cathode supports 3, 4 is a hot cathode 5. The hot cathode 5 is from a can-shaped part formed by the control members 6 and 7, the underside of which is terminated by the screen connected to the cathode, from the anode g separated. The gap between the control elements 6 and 7 is so narrow that that the discharge of the relay tube does not go through with the normal anode voltage it can develop through it, but it is a central round shape opposite the anode öff - @ 'üung i i worked out half from organ 6 and half from organ 7, which allows the discharge to exit to the anode and whose size determines the ignition characteristic of the tube determined. The controls 6 and 7 are by means of the supports 12 and 13, the anode g is supported on the foot by means of the carrier 14. By the equivalent Arrangement of the controls 6 and 7 is achieved that the ignition characteristics of both Control organs largely coincide. The lower edges: the can parts 6 and 7 and the screen b are covered by the mica disk 15 on the underside. The discharge space of the relay tube is filled with argon with a pressure of 0.5 mm.

It. it was found in a test tube with a 0.25 mm wide gap io that it was impossible to make the tube respond with the normal anode alternating voltage of 170 volts; To enable the relay tube to work at the anode AC voltage of 170 volts.

Claims (1)

PATENT CLAIM Ion discharge tube with hot cathode in which several independently controllable organs essentially in the same equipotential area the electrostatic field between the cathode and anode are arranged, characterized in that the control organs are sector-shaped, equally sized, in a plane perpendicular to the axis and around the axis of the electrostatic field Represent parts with equal central angles of a plate or box-shaped body, the slot-shaped one that runs radially and does not allow the discharge to pass through Gaps are separated from each other, and that for the passage of the discharge at each control electrode in the vicinity of the axis the same, together the passage opening for the discharge forming recesses are provided.