DE750714C - Tube arrangement for fanning (generating, receiving, amplifying) ultra-short electrical waves - Google Patents

Description

The invention relates to a tube arrangement for fanning (generating, receiving, Amplification) of ultra-short electrical waves, in which a frequency-determining structure Is used. In particular, the invention relates to such arrangements in Braking field switching. The frequency-determining structure can be completely within the Tube.

According to the invention, the device is made so that the frequency-determining Structure consists of a concentric double line formed by solid tubes, only at the point of the electron transition serving as an electrode system (Grid anode) is formed and at the ends of such reduced wave, Has resistance that radiation loss is practically avoided. Furthermore can on that

ao one end the concentric double line " Lead over the piece in question reduced wave resistance to the radiator.

To further explain the concept of the invention, the figure shows an embodiment of the invention, specifically for an electron tube in a braking field circuit. A wire cathode / C is stretched out in the middle, which is surrounded by the cylindrical grid tube G, which is designed as a grid for the passage of the electrons in the middle. In order not to disturb the formation of the high-frequency field between the inner and outer conductors as far as possible, the grid expediently consists of wires parallel to the axis of the system. The whole thing is enclosed by the cylindrical brake electrode Λ. The diameters of the grid and anode tubes determine the wave resistance of the system. The distance between the tubes is denoted _{by s 0.} At the left end,

"i The patent seeker stated that the inventor was:

Dr. Ing.Walter Dällenbach in Bisingen, Hohens.

The wave resistance decreases from the span node to a very small value corresponding to the small distance S ₁ , as a result of which the voltages are only very small here and practically no energy is radiated from this end. The length of the power line section with conductor spacing ^ ₁ is // 4. The distance s ₂ on the right side of the actual generator is chosen so that the most favorable energy transfer to the radiator mounted there is achieved.

The length of the power line piece

with the conductor spacing S ₂ is also // 4. The embodiment described also allows one or more additional generator systems, all of length λ / ζ, to be arranged on the left side of the Lecher system shown in the figure, which are coupled by short, tubular power lines, the electrical length of which is /./4 . The length of the last piece of the system on the right, which establishes the connection with the radiator, is set in such a way that optimal excitation of the radiator occurs.

Arrangements for fanning ultra-short electric waves by means of electron tubes, where a frequency-determining structure consisting of a concentric Lecher line Is used, have already become known, but is in the known arrangement the concentric double line at one end or at both ends as an electrode system, namely as a grid and anode, formed by the electron flow serving for the stimulation. Consequently, the concentric double line is adjacent to the Point of the electron transition, that is, a very strong point or maximum alternating field, to the outside area. From the opening of the concentric A double line can therefore emerge at one or both ends to a considerable extent of radiation loss. Furthermore can considerable loss of radiation is caused by the fact that electric field lines (stray field) at the end of the double line reach over to the outer surface of the outer conductor and they stimulate to resonate and radiate. By reaching into the electrical

This is how the stray field can be seen from the end of the concentric double line into the interior of the inner conductor is the line structure between the inner conductor and the cathode to vibrate are excited, which, apart from the withdrawal of energy, an unwanted disturbing control of the electron flow on their Paths between cathode and grid can result.

Furthermore, test arrangements in braking field circuit have already become known at those using tubes with cylindrical

three electrodes, concentrically surrounding the filament, hit the device is that the frequency-determining resonance system of grid and anode and on These electrodes consist of double-wire cables connected on both sides and on both sides with the help of block capacitors is completed by voltage nodes. At this known experimental set-up, the shortest wave is to be generated in that the both block capacitors as close as possible to the ends of the grid and anode will. At the ends of the frequency-determining structure there is the transition to the voltage nodes only through the two block capacitors connected via wires is achieved, there are still alternating fields that cause radiation loss. Furthermore, the resonator is bounded by two cylinders, one of which is from the full-walled anode and the other consists of the grid over its entire axial length. Loss radiation "can therefore pass through this latter cylinder through the space between the grid and cathode" exit to the outside.

Furthermore, ultra-short-wave rolls (in Brake field circuit j became known, in which the frequency-determining structure is used by a wire loop short-circuited mesh coil. In other known embodiments The grid coil is of this type not through a special wire bracket, but through block capacitors through the the anode or brake electrode concentrically surrounding the lattice coil short-circuited. The space between the anode and the lattice helix is due to the spaces between the Turns of the lattice coil through on the · οο entire axial length 'of the same with the space between the grid and cathode in connection. Some of the magnetic field lines run circularly around the wire of the lattice helix. On the other hand, considerable Part of the magnetic field lines run inside the lattice coil like a solenoid (essentially in an axial direction Direction). They occur at both ends of the lattice helix, where as a result of the existing Current also the magnetic field is very strong, from the open space at the ends between the lattice coil and the cathode and cause considerable radiation. Of the At the ends of the lattice coil, high-frequency current also flows onto the outer surface of the the cylinder forming the anode and excites it to emit radiation.

In the case of the subject matter of the invention, on the other hand, the frequency-determining structure is not one short-circuited lattice coil, but a concentric double wire with the one for the

concentric ■ Lecher line typical, clear course of the electrical and magnetic Field :. If a grid is provided, the inner conductor is the concentric one Double line formed as a grid only on part of its axial length, while it is also solid on both sides of the grid. The electromagnetic field the structure that determines the frequency is' practically exclusively on the inside (Middle) in a tension belly and its immediate vicinity from the electron flow fanned cavity localized by the outer conductor and the inner conductor of the concentric double line (Lecher line) is limited and outwards to the both ends are terminated in voltage nodes, which is achieved by reducing the wave impedance are formed. There are therefore disadvantageous radiation loss avoided, which the inherent attenuation of the frequency-determining Would enlarge structure in an undesirable manner and, as already mentioned, also in those known arrangements occur in which a concentric double line is the frequency-determining structure is used, but this at one end or at both ends as an electrode system (Grid anode) is formed and with the there at the point of the electron transition . existing tension belly adjoins the outside space. With the subject matter of the invention has the electric alternating field at the ends of the field space bounded by the outer conductor and inner conductor only a much smaller value than at the point of the electron transition or a practically zero value, namely this is achieved by reducing the Characteristic impedance at the two ends of the concentric double line. An extensive metallic shielding of the field space of the concentric double line is therefore also achieved, which is is located between the parts of reduced wave resistance at the ends. The bigger one The part of the concentric double line that has wave resistance goes to his Metallic ends in the reduced wave resistance owning parts over. Therefore it is also known compared to the one mentioned Attempts to generate the shortest wavelength arrangement used the diffuse radiation considerably further. This is also done by the fact that in the subject matter of the invention, as far as the inner conductor is designed as a grid, the grid is only over part of the axial length of the Inner conductor extends and this is fully walled in the rest.

The ohmic conduction losses of the frequency-determining structure are also part of the subject matter of the invention advantageously kept small, since the oscillating current flows over extensive (full-walled) metal surfaces can. This applies in particular to those points of the double line where the oscillating current assumes considerable values, d. H. towards the ends or the current bellies, with in other words on both sides of the transition of the stimulating electron flow, which takes place in a tension belly and on both sides of the same.

Due to the practically all-round metallic closure of the resonator to the outside by 'the structure that determines the frequency, so to speak, due to its construction towards the outside is practically completely metal-shielded, disturbances, especially unwanted ones Changes in wavelength, switched off by external influences, which also makes an excellent Frequency constancy is guaranteed.

Since the concentric double line at one end over the piece of reduced wave resistance ('distance S _2. ) Serves as a concentric energy line leading to the radiator, the coupling between the ultrashort wave generator and the radiator can be set to an optimal value through its dimensioning Connection between the frequency-determining structure and the radiator take place again while avoiding stray fields or radiation loss. While the useful radiation reaches the radiator from the frequency-determining structure, the frequency-determining structure is closed at its other end (distance S ₁ ) in such a way that practically no energy radiation, neither useful radiation nor 1 °° loss of radiation, is caused from this end.

The subject of the invention is also characterized by the fact that there is a risk of multiple waviness is largely switched off.

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Claims (2)

Patent claims: 1. Tube arrangement for fanning (generating, receiving, amplifying) ultra-short electric waves, in which a frequency-determining Structure is used, characterized in that the frequency-determining structure consists of a from solid pipes formed concentric double line, which only at the point of the electron transition serving as an electrode system (Grid anode) is formed and at the ends such reduced characteristic impedance shows that radiation loss is practically avoided. 2. Tube arrangement according to claim 1, characterized in that on the one The end of the concentric double line leads over the piece of reduced wave resistance (distance s ₂ ) to the radiator. To distinguish the subject of the application from the state of the art, the granting procedure the following publications have been considered: German patents ..... No. 502 807, 520-061, 527791; Austrian patent .. Xr.
French - .. - British USA. Magazine f. Physics (1930J ₃ vol. 65
Proceedings of the IRE (1932J ₃ and 1340. 87849; 733154; 128983; 730246; , P.726; P. 1332 .. 1 sheet of drawings atfUJN. OKDMJCKT IH ftf! » AREA BLU CKiKtl