DE672510C - Magnetron tubes with cathode, several axially parallel anode segments and auxiliary electrodes - Google Patents

Description

Magnetron tube with cathode, several axially parallel anode segments and auxiliary electrodes. In the present invention, the magnetron tubes are used for generating, amplifying and receiving electrical vibrations. The structure of the discharge system, in particular the shape and placement of the electrodes, happens from a completely new point of view, taking into account the Orbits that the electrons move under the influence of a parallel to the system axis Hit the magnetic field. The purpose of the invention is to achieve a greater work gradient, to z. ß. to be able to get by with smaller control or modulation services.

It is known that magnetron tubes are circular, concentric to the cathode have anode segments that are similar to the auxiliary electrodes Provide shape in the spaces between the anode segments so that both Types of electrodes lie on a circular cylinder and thus the same from the cathode As are the anode segments (patent ..128 547, Fig. 5).

It is also known to use planar electrodes in magnetrons which lie on the sides of a rectangle (Patent .I28 54.7, Fig. 3). The arrangement is such that the anode segments (working electrodes) are further away from the cathode than the auxiliary electrodes, so that these are particularly absorb a considerable part of the emission current with positive bias and also the discharge process between the anode segments and the cathode sensitive to disturb. It also seems important to point out that these auxiliary electrodes only served to spatially close the discharge system, so no electrons can hit the vessel wall.

The magnetron tube according to the invention with cathode, several axially parallel thereto Anode segments and auxiliary electrodes is characterized in that the anode segments (Working electrodes) or their constant extensions in tangential direction, d. H. formed perpendicular to the radial and axial direction of the discharge system or are arranged that they have a fictitious circular cylinder concentric to the cathode only touch in one or a few places, but not or at least not completely coincide with this and that the auxiliary electrodes are outside this circular cylinder are arranged. To make the influence of the auxiliary electrodes as great as possible, arranges you can see them within the area which when looking at a perpendicular to the cathode guided cut on the one hand through the circle around the cathode and on the other hand through the anode segments or their constant tangential extensions limited with the novel arrangement can break the previously observed rule = the means that with multi-slot magnetrons no further Electrodes may be attached. In this special case, the auxiliary electrodes can still be attached within the discharge space without them even with positive Bias voltage absorb substantial currents. The physical justification of this fact can be found in the next section.

The magnetron arrangement according to the invention is preferably made such that that i. the anode segments (working electrodes) on the sides of a parallelepiped are arranged that y. the axially directed magnetic field and the operating voltages are chosen so that the electrons on their orbits around the centrally located cathode approximately tangent to the anode segments, and that 3. the auxiliary electrodes at the points of the discharge system are provided, which are free from the circling electrons or remain almost free.

Only the inside of the fictitious cylinder can be addressed as the discharge space, which must be imagined as the boundary of the orbit of the circling electrons. However, because the auxiliary electrodes move closer to the discharge area, the electrons are also more strongly influenced than usual by the auxiliary electrical fields. The control or modulation fields to be applied become smaller, ie the slope the characteristic has increased, the amplitude difference of the partial anode currents being under the influence of a control voltage Ust.

Examples of embodiments of the inventive concept are shown in FIGS shown.

In Fig. I the electrode system of a magnetron tube is in section shown. The anode segments A are arranged on the sides of a square. Of the Circle around the cathode K with the radius r "indicates the limit over which the electrons Do not step outside if the magnetic field and the operating voltage are suitably dimensioned can. The auxiliary electrodes H are arranged outside this circle and can thus do not consume any significant current even with positive bias. In fig. z is a similar tube as shown in Fig. i. The one behind the auxiliary electrodes lying anode segments are shortened to reduce the mutual capacitance. You can do without these parts of the anode: #segments, as they are due to the shielding. = Shielding due to the auxiliary electrodes H practically no particular influence on the discharge process exercise more. The auxiliary electrodes themselves can be of any shape.

In Fig. 3 is the section through a rectangular electrode system shown. The anode segments A lie on the long sides and the auxiliary electrodes H on the short sides of a rectangle.

The anode segments of the magnetron tube do not need flat surfaces To be formed, but can take any shape. The only important thing is that that the anode segments do not cling completely to the boundary cylinder around the cathode h, but move away from it in some places to make space for the attachment of the To create auxiliary electrodes.

In Fig. 4 an example is shown in which the anode segments that tangent to the circle around the cathode in its center line, although not evenly are, but are designed so that the lying on both sides of the point of contact Segment parts are mirror images of the same.

If you move the auxiliary electrodes out onto the anode surface, so one obtains, for example, the arrangement according to Fig. 5. The anode segments A are flat and approximately touch the circle around the cathode with one side edge. The auxiliary electrodes lie in the areas that the mirror-image additions to the anode segments form with the tangent point as a mirror edge.

You can now go a step further, anode segments and auxiliary electrodes make them equal and symmetrical about a diameter of the circle around the cathode place so that the Tangierungsstelle with the gap between the anode segment and the associated Auxiliary electrode collapses (Fig. 6). With this last arrangement it should be noted that that as a result of the flow direction of the electrons under the influence of a magnetic field in the selected direction, for example, the electrodes H are not electrically equivalent with the working electrodes A. Because the electrons are essentially in the middle pass over the side surface of the square, the gap S with the gap S 'is not equivalent to. A suitable choice of operating conditions is an unwanted control of the electron flow through the anode segments to the auxiliary electrodes prevent in such a way, for example, that the auxiliary electrodes have a direct voltage which is fo to 20 ° /, lower obtained as the anode segments.

The electronic decoupling of the anode segments from the control electrodes can still be achieved by asymmetrically shifting the column S with respect to the columns S 'support. With electronic coupling, the reaction of the alternating operating voltages should the electrodes on the path or the flow of electrons can be understood.

In Fig. 7 the scheme of a magnetron circuit is using specified a tube according to the invention. The circuit can be used to generate, amplify and to receive electrical vibrations as relays etc. use. A External magnet N-S generates a constant magnetic field whose lines of force are parallel to the Cathode IL run. Anode voltage U "and magnetic field are chosen so that the Majority of the electrons only approximately touch the anode segments A on their orbits and that the places occupied by auxiliary electrodes H are free or almost free stay away from the electrons. The auxiliary electrodes H are preferably given a positive one Bias voltage, which will be less than the anode voltage. This auxiliary electrode voltage the external control voltage, modulation voltage, receiving voltage etc. can be superimposed will.

Practice has shown that it is desirable to use when receiving the magnetron to be able to regulate undamping and rectification independently of each other. This object is particularly advantageous when using a tube according to the invention Way to solve.

In the following lines, reference should again be made to Fig. 7. Instead of the microphone 111 z. B. a remote receiver T or a low frequency amplifier or an intermediate frequency amplifier when an intermediate frequency is formed. The high-frequency received voltages are superimposed on the anode segments A. The anode system A is mainly used for undamping. The rectification itself takes place practically only with the help of the auxiliary electrodes H. The separation of the two processes, which are not mutually dependent (de-attenuation or rectification), gives the possibility of selecting the most favorable operating points for both functions, which was previously hardly possible.

The operating conditions-magnetic field and bias of the auxiliary electrodes and / or anode segments - are preferably chosen so that the auxiliary electrodes in the absence of receiving voltages, only draw a small amount of current or no current at all. As soon as a receiving AC voltage is superimposed on the anode voltage, it increases Auxiliary electrode current approximately proportional to the received voltage, da the orbits of the electrons are bent at times of positive high-frequency half-waves (widened), so have larger diameters than when at rest.

A super-regenerative method is expediently used for reception. The anode voltage receives z. B. pushed an overheard pendulum frequency, so that the anode system with a suitable choice of the operating point between one insertion and exposure to vibrations oscillates. A rectifying effect is then shown in the auxiliary electrode circuit as described in the previous section is. However, this information is not intended to exclude the possibility of if necessary, to give the pendulum frequency to the auxiliary electrodes.

The idea of the invention is not limited to the examples presented here limited; the anode segments can have any shape if only in some places so far away from the cathode that between them and Electron-free areas remain on the cathode to accommodate auxiliary electrodes.

The individual auxiliary electrodes can also have different-phase high-frequency AC control voltages are supplied (transmitter amplifier). The modulation voltages do not have to be fed exclusively to the auxiliary electrodes, but can also find a combination modulation use in which the anode voltage and of the auxiliary electrode voltage, the modulation oscillations are in phase or out of phase are superimposed.

Claims (3)

PATEN TANSI'RÜCIII1: i. Magnetron tube with cathode, several to it axially parallel anode segments and auxiliary electrodes, characterized in that the anode segments (working electrodes) or their constant tangential extensions are designed so that they have a fictitious circular cylinder concentric to the cathode only affect one or a few places, but not or at least not completely coincide with this and that the auxiliary electrodes are outside this cylinder are arranged. 2. magnetron tube according to claim i, characterized in that the auxiliary electrodes are in the spaces that are on the one hand by the fictitious circular cylinder around the cathode and on the other hand through the anode segments or their continuous tangential extensions are limited. 3. magnetron tube according to claim i and 2, characterized in that the parts lying behind the auxiliary electrodes the anode segments are omitted. , 4. Tube according to claim 1 and 2, characterized in that that the anode segments are preferably flat and the circle around the cathode tangent in their center line, so that on both sides of the point of contact lying segment parts are mirror images of the same. 5. Tube according to claim i and 2, characterized in that the anode segments on the sides and preferably rod-shaped auxiliary electrodes approximately in the corners of a square, which is results in a section perpendicular to the cathode, are arranged. 6. Tube according to claim i and 2, characterized in that the anode segments on the long sides and the auxiliary electrodes on the short sides of a rectangle, which is located at a Section results perpendicular to the cathode, are arranged. 7. tube according to claim i, characterized in that the anode segments are preferably planar and approximately tangent to the circle around the cathode with one side edge and that the auxiliary electrodes lie in the areas that are the mirror-image additions to the anode segments with the point of tangency as a mirror edge (Fig. 5). B. tube according to claim i, characterized in that one each by an anode segment and an auxiliary electrode formed electrode pair in a surface and symmetrical to a diameter of the Circle around the cathode and that the Tangierungsstellen with the gaps between the electrodes of the individual electrode pairs coincide (Fig.6). G. Magnetron circuit for generating, amplifying, receiving electrical vibrations, etc. using of tubes according to claim i and following, characterized in that a constant Magnetic field whose lines of force run parallel to the axis of the electrode system, is added and that the operating voltage and magnetic field strength are chosen so that in the state of rest the majority of the electrons on their orbits the anode segments only approximate and that the places occupied by auxiliary electrodes. are, remain free or nearly free of electrons. ok Magnetron circuit according to claim 9, characterized in that at least one of the anode segments is capable of resonance System (resonant circuit) is connected and that the auxiliary electrodes have alternating voltages, that come from an external voltage source are pressed on. i i- magnetron receiving circuit according to claim 9 and io, in which the connected circuits are undamped is characterized in that the attenuation with the help of the anode segments (A) and the rectification with the aid of the auxiliary electrodes (H), preferably separately by choosing appropriate biases. 12. Receive circuit according to claim i i, characterized in that the operating conditions of the tube, so magnetic field or bias voltage of the auxiliary electrodes and / or anode segments so be chosen that in the absence of a high-frequency receiving voltage, the auxiliary electrodes Consume little or no current.