DE1054593B - Tension grids for electrical discharge tubes, especially for electron tubes - Google Patents

Description

GERMAN

The invention relates to a tensioning grid for electrical discharge tubes, in particular for electron tubes, and furthermore the use of one or more such tension grids in the electrode structure.

For various reasons, efforts are made to determine the electrode spacing of electrical discharge tubes, especially of tubes that are operated at very high frequencies, as small as possible to keep. With the help of the known tension grids you can, for example, the distance of the first control grid from the cathode surface to a minimum. It causes difficulties though, too the distance between the individual grids, for example the distance between the control grid and Screen grid or the distance between control grid and anode, to be reduced below a certain level, when using tension grids. This is due to the presence of the clamps that are used in Tension grids are required to connect the spars carrying the lattice windings.

Smallest distances between control grid and screen grid are required, for example, when with low screen grid voltages or anode voltages, sufficiently high penetrations yourself want to achieve with close-meshed control grids. By using low screen grid voltages or anode voltages, the service life of such a tube is also improved and the overall power loss is improved degraded. As an indirect consequence of the lower tensions, z. B. with multi-grid tubes, Achieve a favorable current distribution and favorable noise properties, because now thinner Screen grid wires can be used.

The invention is based on the object of specifying a tension grid construction which makes it possible the distance between control grid and screen grid or between control grid and anode Reduce the minimum in order to be able to produce a tube with such a grid, the above-mentioned Has advantages.

In the case of a tensioning grid for electrical discharge tubes, in particular for electron tubes from the spars carrying the lattice windings and those defining the mutual spacing of the spars Ironing is therefore, according to the invention, one of the two brackets connecting the bars by means of a bridge replaced, which is arranged in the center plane laid by the spars and on the end faces of the spars is attached and which is not wider than the stile thickness.

The advantage of this design of a tension grid is that it is placed in the center plane Bridge when assembling the next following elec-

Tension grid
for electric discharge tubes,
especially for electron tubes

Applicant:
Telefunken G. mb H.,
BerKn NW 87, Sickingenstr. 71

Dr. Georg Marx, Ulm / Danube, has been named as the inventor

trode, so z. B. the screen grid or the anode, is not in the way, so that the following electrode may have a minimal distance from the mentioned first grid.

The difference between the tension grid training according to the invention compared to the previously known construction of tension grids can be readily seen from a comparison of those in the drawing in FIG Figs. 1 to 4 shown two constructions.

In FIG. 1, a tensioning grid of the previously known construction is seen from the front and in FIG. 2 shown in top view. Figures 3 and 4 illustrate a grille according to the invention.

The grid usually consists of two bars 2 and 3, which are assembled to form a frame with the help of the two clamping brackets 4 and 9. These two clamps are expediently connected to the two bars 2 and 3 by spot welding. The lattice windings 8 are then wound onto the bars 2 and 3 with the aid of a lattice winding wire under mechanical tension.

The clamps 4 and 9 have the shape shown in FIG. 1, so that the cathode 1 can be inserted between the grid windings 8 when the system is being installed.

As can be seen from Fig. 1, the next grid 7, to which the grid struts 5 and 6 belong, must be arranged at a distance from the grid windings 8 of the first grid given by the clamps 4 and 9 , because otherwise the grid 7 at the assembly of the system can not insert over the first grid 8 . It follows that the clamps 4 and 9 have the smallest possible distance

803 789/400

Claims (2)

between the two grids on top of each other. In the construction shown in FIGS. 3 and 4, one clamping bracket is now replaced by a bridge-like retaining member 10, which lies in the central plane laid by the two bars 2 and 3 and on the end faces of the two bars 2 and 3 is attached. From Fig. 3 it can be seen that now the distance between the grid turns 8 of the first and, for example, the corresponding turns 7 of the second grid can be significantly reduced, which brings the advantages described above with it. According to a further development of the invention, a tensioning grid, as shown in FIGS. 3 and 4, is to be used in an electrode structure in which the electrodes or their retaining struts are fastened between insulating disks. In contrast to the usual construction of an electrode structure, two insulating material disks are provided on one side, one of which contains a recess corresponding to the grid profile and the other of which is made in two parts and is used in particular to attach the cathode. When assembling a system with a tensioning grid with the features described above, according to the structure shown as an exemplary embodiment in FIG Brenner, the first control grid with the two struts 2 and 3, the screen grid with the two struts 5 and 6 and furthermore the remaining electrodes belonging to the system. Because of the design of the first control grid and in particular the bridge-like member 10 explained with reference to FIGS. 3 and 4, it is easily possible to insert the screen grid over the first control grid into the corresponding recesses in the insulating material disk 11, even if the distance between them both grids is extremely small. On the other end of the electrodes or the struts carrying the electrodes, the insulating material disk 13 is first placed, which, however, has a recess which corresponds to the cross-sectional profile of the first control grid. This recess is denoted by 16 in FIG. 5. With the help of this insulating disk 13, all electrodes of the structure with the exception of the cathode 1 are attached. For the purpose of securing the cathode, a second insulating material disk 12 is also provided, which is divided in the plane of the struts 5, 2, 3, 6 and has corresponding recesses for these struts as well as for the cathode. The two halves of this insulating disk 12 are expediently placed in such a way that the two disks 12 and 13 touch one another. All electrodes, including the cathode, are now attached, and the system with a very small distance between the cathode and the first control grid and between the first control grid and the screen grid can be installed in the tube piston. It should also be mentioned that means are provided which fix the two insulating disks 12 and 13 in their position relative to one another, for example the two retaining struts 14 and 15 shown in FIG is only to be assessed as an exemplary embodiment, because you can also use other fastening means for the cathode instead of the two-part insulating disk. It is also pointed out that in the case of a tube with more than two grids, the other grids, for example the screen grid, can be constructed in the manner described for the control grid, so that overall a tube system with extremely small electrode spacings can be obtained in this way can get. Patent claims: 1. Tension grids for electrical discharge tubes, in particular for electron tubes, consisting of the spars carrying the lattice windings and those defining the mutual spacing of the spars Ironing, characterized in that one of the two brackets connecting the bars is replaced by a bridge, which is arranged in the center plane laid by the spars and on is attached to the end faces of the spars and which is not wider than the spar thickness. 2. Use of a tensioning grid according to claim 1 in an electrical discharge tube, at which the electrodes or their retaining struts are attached between insulating disks, thereby characterized in that the electrode structure is carried out in such a way that the electrodes or electrode struts on the side of the system on which the front-mounted lattice bracket is located, in two Insulating disks are attached, one of which contains a recess corresponding to the grid profile and the other is designed in two parts and is used in particular to attach the cathode. 1 sheet of drawings & 809 789/400 3.59