DE1798317U - COLD CATHODE SWITCH TUBE WITH SLOT DISPLAY SYSTEM. - Google Patents

Description

Cold cathode bellows tube with an ocli'tz screen system ------------------------------------------------, - - 1-1 ,, ", 4 1-" O. ti, 1- r ö bre ii. One: 3e- The C. Itizathojp- The 'find-' concerns Xaltathode thermostats. A be- of their The reduction in their applicability consists in the following: egg to Gi, 33 Z, -ii the ir, Deletion time denotes the limited-t the riaxi- jelet '.'. 'earthR ann. This line \ '; in the following ala indest- Designated deletion time. The-. indectiöcciiscit crowns the maximum times switching frequency, d <h. the number of controlled ignition genes that coincide with such a tube in an oectimmun unity is permissible. The maximum switching frequency of cold method interrupters or current gates in the previously usual The construction method for the low-voltage technology is about 1 ms on average under normal operating conditions.

It is already known the maximum switching frequency of gas-filled To increase switching tubes that the purging gas of the tube the deionization time degrading additives are added. This z. B. from the Geiger-Müller counter tubes known additives, such as hydrogen alcohol or other organic compounds, however, they have the disadvantage that they are in a switching tube with the stronger discharges lead to constant changes because the additives are either absorbed or decomposed or even chemically change the cathode surface.

It is also known to reduce the extinguishing time in that when a hollow cathode, for. B. in the manner of a hollow disk, formed cathode in which the discharge burns essentially inside, the inactive parts of the cathode and any additional surfaces galvanically connected to the cathode as capture or recombination surfaces for the remaining charge carriers at least on the surface a material with a high work function. By this known measure it is z. B. succeeded in the Extinguishing time of cold cathode interrupters on average to about 200 off to shorten. The extinguishing time by means that remain constant) practically does not affect the functioning of the tube in the ignited state influence, to shorten it even further, is the task of o This is achieved with a cold cathode switching tube for high switching frequency with a cathode whose im The surface lying in the area of the discharge path is more active is as the parts lying outside the discharge path and one arranged between the cathode and anode, as a diaphragm - De formed electrode with essentially perpendicular to the Discharge direction more extensive, the discharge space in two A- =, Area dividing sub-spaces according to the resulting .. that the aperture for the formation of the main discharge is central a longitudinal slot (gap) of less than imm, in particular 0.1 mm wide and that of the cathode extending longitudinally parallel to the length of the slot, all points of the active part are at a distance of less than 1 mm from the slot opening.

With this measure, the slit diaphragm has a double effect on the discharge mechanism. On the one hand, it acts in a known manner as a recombination surface for the residual plasma during the deionization process, so that the deionization time and thus the minimum quenching time are shortened. So that as few secondary electrons as possible are released from it during this process, it is expedient to make it at least on its surface from a material with a high work function. Second, when the anode voltage is reapplied, most of the residual charge carriers fall on the panel wall? so that the one to rebuild one New discharge available dark current is reduced all the more, the smaller the aperture is. This results in a correspondingly strong reduction in the minimum cleaning time. The same effect can also be achieved with a pinhole diaphragm with a correspondingly small opening of, for example

Achieve a diameter of 0. mm. However, pinhole diaphragms have the disadvantage that they hinder the main discharge current much more, which leads to an increase in the operating voltage has the consequence.

The reduction in the erasing time by the diaphragm is even greater more effective, the shorter the discharge paths the charge carriers fi7 ger have to cover - this is achieved according to the inventor u advantageously with a narrow, ribbon-shaped, effective cathode surface, which is parallel to the diaphragm slot is arranged that all points are less than 1 mm away from this.

In appropriate investigations, neon out of 60 The same minimum extinguishing times for a perforated screen with 0.1 mm diameter up to 120 goals as measured for a slit diaphragm with an opening width of 0.1 x 6 mm and determined that the burning voltage in the case of the pinhole diaphragm with increasing amperage in currents increases above 1 mA and at 5 mA discharge current is already around 130 V, while, in contrast, the operating voltage when using a slit diaphragm in the entire current range from 1 to 20 mA den constant value of about 106 V maintained.

In addition, must the diaphragm always have such a large surface area or extend so close to the vessel wall? that ignition cannot take place around the outside of the diaphragm. The effect of the diaphragm on the minimum extinction time can be varied by the level of the voltage between the diaphragm and cathode during the extinction time; it must always be below the operating voltage. The minimum quenching time is the shorter the more this voltage is below the burning voltage of the diaphragm-cathode. The main discharge path is ignited most advantageously by igniting an initial discharge between the diaphragm cathode, with the diaphragm acting as a starter. The short discharge paths result in a low ignition voltage. For a high switching capacity that is desired in many cases However, power is as high as possible above the operating voltage 2 Lying ignition voltage required. The appropriate approach order offers the advantage that when using a preload The aperture-cathode voltage approximates the anode-cathode ignition voltage increases by the amount of this bias. In contrast to the known starter arrangements, this effect arises from the fact that the large-area screen divides the discharge space between anode and cathode into two areas which are largely electrostatically shielded from one another. With a narrow aperture, the anode-cathode penetration is therefore particularly small. Is it therefore possible to use higher operating voltages for the anode-cathode for the main line? if the slit diaphragm used as a starter is positively biased towards the cathode Because of the very small anode-cathode penetration, it is advisable to use neon, helium or a mixture of these gases as filling gas in order to achieve good control sensitivity (transfer). Based on the schematically shown in Figures 1 and 2 AM = Exemplary embodiments of the invention are to be explained in more detail to the In the figure 1, the elongated cathode 1 is made of pure tall, such as tantalum or molybdenum, trough-shaped or trough-shaped so that a particularly activated part and an outer, less active part, in particular artificially deactivated by a coating, are created inside the channel. The cross-sectional dimensions are less than 1 mm. In front of the open end of the cathode, the diaphragm 2 is arranged with an extensive surface with a very narrow slot 3, approximately cathode length, in such a way that it practically divides the actual discharge space. Immediately behind this, a rod-shaped anode 4 is provided in the slot plane. A likewise rod-shaped auxiliary anode 5 is arranged on the end of the cathode facing away from the diaphragm, the continuously burning discharge path of which towards the cathode serves only for sufficient pre-ionization to generate strobe electrons.

Another technical embodiment is shown in FIG in which the same reference numerals as in FIG. 1 are used for the corresponding parts are. In this case, the cathode 1 consists of two approximately square ones of the same size Sheets, each bent at an edge at right angles and bent with these Parts are connected to one another by interposing a web 6 in such a way that a metal trough with an approximately rectangular cross-section is created in which the bridge itself forms the bottom and thus belongs to the active part of the cathode. In contrast to Inner surface of the cathode, the outer part is deactivated in a known manner.

The chosen shape of the cathode allows a particularly good mechanical Achieve stability with a relatively simple manufacturing process. In front of the cathode are analogously to FIG. 1, initially the diaphragm 2 with a narrow slot 3 and a Rod-shaped anode 4 arranged in the slot plane.

For the local pixelation of an auxiliary discharge used for pre-ionization has the cathode on the side facing away from the diaphragm opposite the auxiliary anode 5 also has an inner shape.

The embodiment of the cathode is not limited to the two examples shown, but rather all other shapes can be used for the present purpose, which have an active part limited in the form of a band and which is in the immediate vicinity of the aperture can arrange slot. Azides 5 Patent Claims 2 figures

Claims (4)

r tcnans --- Patent claims 1. Cold cathode interrupter for high switching frequency with a Cathode, the one lying in the area of the discharge path The surface is more active than the parts lying outside the discharge path and an electrode designed as a diaphragm arranged between the cathode and anode with an area extending essentially perpendicular to the direction of discharge and dividing the discharge space into two sub-spaces, characterized in that the diaphragm for the formation of the main discharge is central has a longitudinal slot gap of less than 1 'mm, in particular 0 71 mm: width and that of the cathode, which extends longitudinally parallel to the slot length, all points of the active part are less than 1 mm from the slot opening. 2. cold cathode interrupter according to claim 1, characterized in that that the diaphragm, at least on its surface, is made of a material with a high work function consists. 3. cold cathode interrupter according to claim 1, characterized in that that the inactive parts of the cathode are deactivated. 4. Cold cathode interrupter according to Claim41 and 3, characterized in that the cathode is shaped like a trough or trough and consists of pure metal. 50 cold cathode interrupter according to one or more of the preceding claims, characterized in that an auxiliary anode, which is used only for pre-ionization, is located on the side of the cathode facing away from the anode. is in order.