DE814490C - Electronic amplifier - Google Patents

Description

(WiGBl. P. 175)

ISSUED SEPTEMBER 24, 1951

p 5002 / VIII c I 3i g D

has been named as the inventor

Electronic amplifier

The present invention relates to high frequency tube amplifiers, especially those of the traveling wave type, with a relatively long electron beam along an electric Wave transmission circuit is sent, in such close proximity that it is coupled with the same will.

The general object of the invention is to provide an improved electron beam type of amplifier to create as the wave progresses.

A related object of the invention is to provide improved bundling of the electron beam in traveling wave amplifiers of this type.

Another goal relates to reducing the unwanted noise components in the output of such devices.

Another goal is to create amplifiers that can use electron beams for large Have currents, the measure of noise reduction being applied.

Another aim is to provide simple means of coupling between elements of the Amplifier tube in the external high frequency transmission circuit.

There are already various forms of high frequency amplifier tubes have been proposed by the traveling wave type, in which elongated elec-

electron beams and wave circles, which are coupled with one another, are used. In such By their very nature, devices have quite severe mechanical and electrical requirements. The length of the beam and the wave circle and the need to have a suitable coupling between Maintaining these two requires precise alignment of the pipe elements, and because of the Proximity of the ray and the circle it is important that

ίο the beam remains well focused. To also use effectively by transferring energy from the electron beam to the electric wave To obtain amplification, it is desirable to supply a high current carrying electron beam which is coupled as completely as possible with the electrical wave circuit. It is also it has been found that, especially in long radiant tubes, disturbing electrical noise in the output circuit can occur, apparently due to the tapping of positive ions along the electron beam can be traced back to where a potential reduction is created by the electric space charge. This makes it desirable to remove these ions from the electron stream and in this way prevent their accumulation to a disruptive extent.

The above-mentioned requirements are thereby taken into account and the associated ones Difficulties solved according to the invention in such a way that electrodes are provided which in generate electrical direct current transverse fields in the vicinity of the electron flow in order to concentrate the current and to deflect the positive ions and that tubular electron beams are applied which concentric with the coils forming the high frequency wave transmission path through the pipe run to obtain high beam current with close coupling to the coils, and that a direct connection between the coiled tubing and an outer coaxial or balanced Transmission line is created to ensure simple coupling means.

The invention, including its objects and advantages, is set forth in the following description icher explained, in conjunction with the drawing.

Fig. Ι shows a diagram of a traveling wave amplifier tube together with the associated circle, which are similar to earlier embodiments, to the extent that a stream of electrons is crowded is thrown along the axis of a single helix and as outer circles of the wave guide type Find application.

Figure 2 shows an embodiment of the invention with a single tapered helix, along the outer surface of which flows a tubular electron stream. An electrical screen surrounds the Electron flow, and the filament is directly connected to coaxial, outer circles.

Fig. 3 illustrates an embodiment in which two concentric coils that immediately are connected to balanced, outer circles, and a tubular, ger electron flow is concentric with and between the two filaments, which are on different DC potential are held, thrown.

To go into the drawings in more detail, they all show the tubes and circles in broken lines Representation of the middle parts so that the elements are shown on a sufficiently large scale without the longitudinal dimensions exceeding the available drawing length. If typical If pipes were shown in their entire length at the scale used, they would take the twice the length of the available drawing area. In Fig. Ι is the evacuated shell of the booster tube, which can consist of glass or other suitable material, with the reference number 1 designated. The pipe and 8 <5 are located in this envelope Circle elements. The cathode is provided on the surface 3 with an emission layer, which by means of the Heating device 4 is heated. The electron beam shaping electrode 6 is shown with reference to FIG Cathode sized and arranged so that it carries the electrons on parallel orbits towards it aligns the electron collector 19. With 7 an electron accelerating electrode is designated, to which a grid 8 is assigned. The coil 10 made of conductive material forms the high frequency wave transmission path through the tube and is dimensioned so that the phase velocity of the shaft along the axis of the helix is substantially the same is the speed of the electron stream flowing along the axis. Support ceramic rods 11 the coil 10 and align the same precisely; at their ends they are in sections of the metal rings 13 and 14 fitted. The metal shell or screen 12 surrounding the coil 10 and between the sheath 1 and the rods is on a negative with respect to the coil voltage Potential held so that a field is created which penetrates the helix and strives to Concentrate the electron beam while keeping the positive ions between the turns of the To drive coils to the screen, where they are collected and neutralized. The ring 13 closes that Input end of the coil 10 and bridges the electrical wave from the input end of the coil to the input shaft guide 17. The ring 14 closes the output end of the helix 10 and ' bridges the electrical wave from the output end of the helix to the output shaft guide 18. The connector 15 between the input end of the helix 10 and the ring 13 couples the Input end of the helix to the input shaft guide 17. The connector 16 between the exit end of the helix 10 and the ring 14 couples the output end of the helix to the output shaft guide 18. 19 denotes an electron collector, which completes the path of the electron stream. The potential source 5 is used to to supply the cathode heating with energy, while the source 9 the potential differences between the cathode and the electron accelerator 7, the screen 12, the collector 19 and the

Wendel ίο delivers, namely by means of the illustrated Feeds, of which the feed 20 connects to the helix 10 via the ring 14 and the connecting link 16 produces. At 21 is compensation or waste material which has the ability to absorb radio frequency energy. This material is deposited on the ceramic rods, and only after them inwardly facing surface and not on the surfaces that are in contact with the shell 12, so that the coil 10 with the sheath due to a conduction through the compensation or loss material is not short-circuited. This loss material provides a certain attenuation of the high frequency wave in the wave transmission circuit along which the electron flow amplifies the wave energy, what is important in a wave amplifier of this type. The solenoid 24, which of any DC power source, e.g. B. a battery 25, can be fed, is used to create an axial, magnetic concentration field over the entire length of the electron stream. In this context Note that all of the conductive material used to build the tube must be non-magnetic.

When the embodiment of FIG. 1 just described is operated, the one to be reinforced occurs Wave through the wave guide part 17, is transmitted to the input end of the helix 10, namely through the coupling connector 15, which lies in the field of the wave guide, is then longitudinal the helix to the coupling connector 16 at the output end guided by the helix and transmitted through it to the output shaft guide 18. The from The electron current emanating from the cathode surface 3 flows along the axis of the filament to the collector 19. The helix forms a wave transmission path that is several wavelengths long (in one typically it corresponds to 40 wavelengths). The speed of the high frequency wave along the The axis of the helix is less than the speed along the helix wire; that depends on that The radius of the helix and the pitch of the winding; the axial speed is approximately the same the speed along the wire divided by the circumference of the helix in centimeters and the Number of turns per centimeter. Thus, the helix can be dimensioned so that the speed of the shaft along the axis of the helix and the speed of the electron flow that flows along this axis; such a speed is necessary to gain reinforcement to enable the shaft. The final setting of the electron flow velocity can be made by adjusting the electron acceleration voltage.

When the pipe is set up and put into operation, there is a mutual effect between the high frequency field of the filament and the electron flow, so that the input high frequency wave, applied to the filament 10 induces a similar wave in the electron stream, which increases along the current and high frequency energy from the current to the electrical Wave that travels along the helix to the output shaft guide 18. Thus the electric wave as it passes between the input guide 17 and the output guide 18 reinforced. To effectively achieve the required interaction between the high frequency field the filament and the electron flow, it is desirable that the beam concentration is well maintained so that the current passes close to the filament without excessive Number of electrons brushing the filament. To maintain beam focusing too support, the aforementioned jacket 12 is provided. This jacket lies within the pipe envelope. In a coaxial arrangement, it encloses the helix 10 and the path of the electron stream lying therein. The coil is separated from the jacket by means of the insulating support rods 11, which fit closely on the inside of the jacket and on the outside of the helix and the location secure the coil in the tube and against the flow of electrons. The jacket 12 is to the Voltage source 9 connected via feed 23 in such a way that its potential is below that of the helix 10 is held. As shown, the helix 10 is higher at one point Potential of the source 9 connected, through the feed 20, the ring 14 and the connector 16. Due to the voltage difference between jacket 12 and filament 10, in near the helical conductor, between the turns and inside the helix, an electrical one Field created, which has the tendency to concentrate the electron flow and on this Way a scattering of the beam and an excessive accumulation of electrons by the To prevent helical conductors.

The jacket 12, which is held at a lower potential than the coil 10, also has the Creating a concentration effect on the electron flow still another important task: The created electric field structure, which radially directed components transverse to the direction of the electron beam has the tendency to get positive ions out of the beam and between to drive out the turns of the coil to the mantle, where they are collected. That leads to Preventing the accumulation of ions in the electron stream to such an extent that Noise vibrations can occur. In this way, noise flow at the outlet of the pipe, which emerges from the electron beam is reduced.

FIG. 2 illustrates an embodiment of the invention which fundamentally differs from FIG. 1 in that that the electron flow is tubular and generally along the outside of the filament instead of along the Helical axis, as in Fig. 1, is thrown. There are however, there are still other differences in the structure and the circular configuration according to FIG. 2.

In Fig. 2 there is the evacuated 1 * 5 marked 3i Sheath of the tube made of non-magnetic, conductive

Material, ζ. Β. Copper, bronze, aluminum or molybdenum. It is vacuum tight and the required leads are inserted through glass or ceramic insulating fuses as shown at 37, 44 and $ 2 . The seals 37 are attached to metal eyes 36. 32 denotes the ring-shaped cathode which has a groove for receiving the emission layer 33, which can be heated by means of the heating device 34. The heating device 34 is fed by the battery 5. The cathode 32 with its emission layer 33 forms a tubular electron beam which lies between the helix 40 and the screen 56, as shown by the broken lines extending to the right from the cathode. The electrons contained in the beam are captured by the conductive sheath 31 at the exit end of the tube, but a special collector electrode can also be provided if so desired. The coil is wound on a support member 39, which can consist of ceramic or similar insulating material. The helix is wound over most of its length so that it gives an axial wave velocity which is approximately equal to the velocity of the electron flow, as has been discussed in connection with FIG. 1; however, the ends can decrease in diameter, as the drawing shows, and if desired the pitch of the winding can also be smaller in order to create an impedance match with respect to the coaxial lines at the input and output. As will be understood, alternative input and output shaft guides can be used in the coupling shown in FIG. 1 in place of the coaxial conductors and tapered helix shown in FIG. Compensating or lost material 41 is applied to the insulating support member 39 near the center of the helix. The same causes high frequency attenuation in the wave transmission circuit to prevent backward transmission and feedback and to facilitate matching of the input and output impedances. 42, 43 and 44 designate the inner conductor, the outer conductor or the insulating seal consisting of ceramic or glass of the coaxial, vacuum-tight inlet lead to the helix. 45 and 46 denote the coaxial signal input line. 47 is a high frequency choke to create a high impedance connection between the coil and the battery 49. 48 is a bypass capacitor. 50, 51 and 52 denote the inner conductor, the outer conductor and the insulating seal, made of ceramic or glass, of the coaxial, vacuum-tight output lead from the helix. 58 and 59 denote the coaxial signal output line. A voltage accelerating the electron flow is supplied by the battery 49, which is connected to the conductive sheath 31 of the tube and from here through the choke 47 to the coil 40, as already mentioned above. The battery 49 also supplies voltage to the screen 56 via line 57; this tension can be either above or below that of the coil. The solenoid 24, which is powered by any suitable direct current source, e.g. B. from the battery 25, serves to generate an axial, magnetic concentration field over the entire length of the electron stream. The tubular screen 56 made of non-magnetic, conductive material surrounds the electron stream and is held at a potential which is different from that of the filament surrounded by the electron stream. Thus, an electric field is created between the helix and the screen, which runs transversely to the direction of the electron flow and acts in such a way that it leads positive ions away from the current. When the screen 56 is positive with respect to the helix 40, the ions coming from the electron stream are collected on the helix, while when the screen 56 is negative with respect to the helix 40, the ions are collected on the screen. In this way, the accumulation of ions in the beam is prevented and the noise current at the output of the device is reduced, as in the embodiment according to FIG.

The embodiment according to FIG. 2 serves to amplify the electrical waves during the migration along the helix, in the same way as in the embodiment of FIG Case is.

The embodiment according to FIG. 3, similar to that according to FIG. 2, uses a hollow electron stream. However, the current lies between two coaxial coils, which together form the electrical Form wave transmission circuit, and not between a helix and a screen, as in Fig. 2 is shown.

In Fig. 3, 61 denotes a vacuum-tight, evacuated glass envelope. The ring cathode 62 with a Emission layer 63 is used to generate a tubular current flowing between the two coaxial spirals 66 and 67 to the collector 80. The cathode is by means of a heating device 64, which receives its energy from the battery 5. The outer coil 66 abuts and is supported by the inner surface of the sheath 61. The inner coil 67 is wound on the ceramic carrier 72, which at the ends by means of the pins 81 and 82 will be carried. The balanced signal input line 68, 69 is immediately at the input ends of the two coils 66 and 67, and the balanced output line 70, 71 directly to the exit ends of the two coils. Compensatory or loss material 73 is on the inner surface of the sheath 61 applied near the center of the coil 66, and other waste material 74 is applied to the ceramic carrier 72 near the center of the coil 67. This waste material provides the desired high frequency attenuation in the wave transmission circuit. A voltage accelerating the electron flow is taken from the battery 78, which via the choke coils 75 and 76 to the

Coils 66 and 67 is connected and to the klektron collector 80. "]"] denotes a high-frequency bypass capacitor. The two coils are held at different direct current potentials; j-ecle of them may have the higher potential, as indicated by the tap connection to the battery 78. If the coils have different potentials, a radial electric field is created transversely to the direction of the electron flow, to be precise in the region of the electron flow between the two coils. This field tends to drive any positive ions in the current towards the lower potential filament where they will be collected; this prevents accumulation in the stream to the extent that spurious oscillations occur. The from a DC power source, e.g. B. the battery 2 ^ fed solenoid 24 forms an axial, magnetic concentration field along the path of the electron flow.

The coils are wound so that they separately have approximately the same phase velocity as has been explained in connection with Fig. 1 and the phase velocities approximately equal to that Are the speed of the electron flow. For this reason, since the diameter of the Spirals are different, the distance between the turns can be completely different, even if they are also the For the sake of simplicity, they have been shown approximately the same size in FIG. As with the embodiments of FIGS. 1 and 2, the radio frequency wave receives under these conditions from the electron current energy and becomes with the migration Reinforced along the coils.

All slow electromagnetic waves have both longitudinal and transverse ones electric field components. At times, either the longitudinal or the transverse field become zero along a line or plane parallel to the direction of propagation. For example there is for the slow mode of propagation no transverse field on the axis of a helical conductive sheet metal. Always have to run in each direction perpendicular to the direction of propagation Both longitudinal and transverse field components exist on the plane.

When a very strong, longitudinal magnetic field in connection with a traveling wave tube is used, the movements of the electrons can be so reduced that they are only from are of little importance. In the case of weak bundling fields, however, the transverse movement of the electrons be important for reinforcement. The transverse fields can move the electrons sideways force and in this way the longitudinal fields acting on it in such a way change so that they draw energy from the electron stream. This is in close analogy to that Effect of the longitudinal fields in the displacement of electrons forwards or backwards in the area of a stronger or weaker longitudinal field.

The type shown in Fig. 3 with double helix supports both a longitudinal wave, wherein the electric field midway between the coils is essentially longitudinal as well as transverse Wave, with the electric field midway between the coils essentially in the transverse direction runs. The two waves have slightly different phase velocities. Each of the Waves can be used to create a reinforcement. If z. B. the transverse wave is to be used, the electron velocity should be substantially equal to the phase velocity of the cross shaft, and the coupling at the ends of the helix should be made be designed so that there is an effective coupling with respect to the transverse shaft. This setting can be realized by changing the pitch of one of the coils close to the end by Wire length is added or removed. If z. B. the coupling is initially good for the Excitation of a longitudinal wave becomes the addition or subtraction of about one half the space wavelength of wire at the end of each helix provides the coupling for the transverse Design the wave cheaply.

It is desirable that the speed differences between the longitudinal and the transverse Wave can be made as big as possible so that the desired wave is clearly defined by setting the electron speed can be chosen. For a given distance the Coils, the difference in wave speed will be greater when the coils are in are wrapped in opposite directions as if they were wrapped in the same direction; for this reason the coils should be wound in opposite directions.

Claims (11)

PATENT CLAIMS: 1. Traveling wave amplifier tube containing a cathode and an electron collector in an evacuated vessel, Means for generating a stream of electrons along an elongated path between the cathode and the collector and a propagation circle for high-frequency, electrical ones along and near the path Has waves, characterized by an consisting of electrically conductive material, itself laterally spaced member along the path and circle and a source of DC potential which is connected to the circuit and to the link in such a way that the latter are held at substantially different DC potentials. 2. amplifier tube according to claim 1, characterized in that the electrically conductive Existing member of the material is formed by a hollow cylinder extending over the length of the Path extends and outside the circle of propagation for high frequency electrical Waves lies. 3. amplifier tube according to claim 2, characterized in that the propagation circuit for > High frequency electrical waves form a conductor I in the form of an elongated helix, 'with the electron beam in the longitudinal direction and runs inside the helix. 4. amplifier tube according to claim 2, characterized in that the propagation circuit for high-frequency electrical waves having a conductor in the form of an elongated helix and the means for generating a stream of electrons are such that they are tubular Generate electron current that is in the longitudinal direction, coaxial with and outside of the Helix, but runs inside the hollow cylinder. 5. amplifier tube according to claim i, characterized characterized in that the propagation circuit for high frequency electrical waves in the form a first elongated helix is held and which is made of electrically conductive material the standing link has a second elongated helix which is along the path and coaxial with and outside the first helix. 6. amplifier tube according to claim 5, characterized in that the electron flow “5 producing means are of such a nature that they generate a tubular electron beam that is longitudinally coaxial with and im Annular space runs between the two coils. 7. Amplifier tube according to one of the claims 3 to 6, characterized in that the elongated helix or the first elongated Helix tapers at both ends. 8. Amplifier tube according to one of the claims 2 or 3, characterized in that a plurality of insulating rods which the helix on Hold the hollow cylinder firmly and in a medium length at points facing away from the cylinder carry a precipitate of high frequency damping material. 9. Amplifier tube according to one of the claims 4 to 6, characterized in that the elongated helix or the first elongated Helix is wound on a holder made of insulating material, which in the region of its middle Length carries a precipitate of high-frequency damping material. 10. amplifier tube according to claim 6, characterized in that the second elongated Helix is supported on the inner surface of a hollow cylinder made of insulating material, which is in the Area of its middle length has a high-frequency damping precipitate. 11. Amplifier tube according to one of the claims 5, 6 or 10, characterized in that the conductors of the coils are located at their ends balanced transmission conductors are connected. 1 sheet of drawings Q 1532 9.