US2347797A

US2347797A - Electron discharge device

Info

Publication number: US2347797A
Application number: US421298A
Authority: US
Inventors: Posthumus Klaas; Penning Frans Michel; Dorgelo Eduard Gerardus; Verburg Cornelis
Original assignee: Individual
Current assignee: Individual
Priority date: 1940-07-19
Filing date: 1941-12-02
Publication date: 1944-05-02
Anticipated expiration: 1961-05-02
Also published as: FR875394A

Description

y 2, K. POSTHUMUS EI'AL 2,347,797

ELECTRON bISCI-IARGE DEVICE File d Dec. 2, 1941 EDI/4RD GERARDl/S DORG'ELO AND INVENTORS ,KLAAS POSTHUMUS FRANS MICHEL PENN/N :CURWEL/S VERBURG ATTORNEY Patented May 2, 1944 UNITED STATES PATENT OFFICE ELECTRON DISCHARGE DEVICE erty Custodian Application December 2, 1941, Serial No. 421,298

In the Netherlands July 19, 1940 Claims.

This invention relates to an electron discharge device utilizing an electron beam and suitable for use at very high frequencies, particularly to such a device in which the electrons in the beam are subjected to so-called velocity modulation and from which energy is abstracted by induction.

This invention relates to a device comprising a discharge tube in which the electrons are concentrated in a beam and traverse a control space which is bounded by two electrodes which will be referred to hereinafter as circumscribing electrodes. In the device to which the invention relates a speed or velocity control of the electrons can be brought about in the said space by means of an electrode, whereas the speed variations are converted outside the said space into variations in density.

According to the invention, the control space circumscribed by the circumscribing electrodes encloses two speed or velocity control electrodes to which are supplied control voltages of identical frequency but having a phase displacement of 180. I

The initial speed of the electrons and the length of the speed-control electrodes are preferably so chosen that the transit time of the electrons between two neighboring slits is a quarter of or half the oscillation period of the control voltages. v

The device according to the invention, in which the control space bounded by the circumscribing electrodes encloses two control electrodes, has the advantage that at a given length of the speed-control electrodes the same effect is obtained as is obtained by means of a device comprising one speed-control electrode in the control space but in which the control voltage is doubled.

In addition, the device according to the invention is very advantageous if a Lecher-Wire system comprising two parallel conductors is connected to the control electrodes in a symmetrical manner.

In order that the invention may be clearly understood and readily carried into effect it will now be described more fully with reference to the accompanying drawing, in which one form of construction of a device embodying it is illustrated.

The discharge tube shown in the figure comprises an exhausted glass bulb [0 containing a stem H at one of its ends and a stem l2 at the other end. The bulb accommodates means for generating an electron beam having a substantially constant intensity and electron speed. For this purpose use may be made of various means; the means illustrated in the drawing are to be regarded as an example only. In the present case the device for generating an electron beam comprises a heating filament l3, which is surrounded by a cathode 14, a control electrode l5 and an accelerating anode 16..

During the operation of the device the filament i3 is heated by current received from a battery l1 and the accelerating anode I6 is supplied with a suitable voltage which is positive relatively to the cathode and is derived from a source of voltage H3. The control electrode I5 is supplied with a preferably variable bias which is positive relatively to the cathode and may be furnished by a source of voltage l9.

At the other end of the tube is arranged an anode whose function is to collect the electrons emitted by the cathode and which will be referred to as the collecting electrode. On the cathode side of the collecting electrode is arranged a cylindrical electrode 2| which serves'respectively for collecting or repelling the secondary electrons emitted by the collecting electrode 20 and which is therefore given a potential, which is positive or'negative relatively to the collecting electrode and is derived from the source of voltage 22.

Preferably, a number of coils 4B are arranged for the obtainment of a sharp concentration of the electron beam.

The control space in which the speed of the cathode ray beam can be controlled is bounded by two

tubular electrodes

23 and 24 which sur-- round the path of the electron beam'and are referred to hereinafter as circumscribing electrodes. In the case illustrated these circumscribing electrodes are grounded and are given a high potential which ispositive relatively to the cathode and which is derived from a source of voltage 25.

According to the invention, the control space bounded by the

electrodes

23 and 24 encloses, either within or without the bulb l0, two speedcontrol electrodes 26 and 21 which are supplied with control voltages of the same frequency having a relative phase displacement of Due to the potential variation in the control space relatively to the limiting potentials of this space-speed control or-in fact velocity modulation of the electron beam is obtained.

The electrons which at a given moment are enclosed in the control space between two electrodes, for example the electrodes 23 and 26, are

accelerated or delayed according as the voltage of the electrode into which the electron enters, for example the electrode 26, is positive or negative at that moment relatively to that of the electrode 23 which the electron leaves, while the same occurs with the electrons which are enclosed between the electrodes 26 and 21 or 2'! and 24. In the device according to the invention in which the electrodes are separated by two speed-control electrodes which are supplied with voltages having a phase displacement of 180, the speed or velocity modulation obtained is a maximum if the initial speed of the electrons and the axial length of the electrodes 26 and"?! are such that the transit time of the electrons between neighboring slits or gaps in the control space is 1r, wherein 27l' is equal to the oscillation period of the control oscillation. In this case, theelectrons which enter into the control space at the electrode 23 will leave the control space at the electrode 26 about an entire cycle of the supplied control voltage later, whereas in the control space the passage from the electrode 26 to the electrode 27 ensues approximately within half a period. An electron which enters into the electrode 26 at a moment when this electrode has the maxi mum positive voltage, for example a voltage E, relatively to the

circumscribing electrodes

23 and 24 will therefore leave the electrode 2! at a moment when this electrode has the maximum negative voltage relatively to the circumscribing electrodes so that both on entering and on leaving the control space the electron is accelerated under the influence of the control voltage E. In addition, the passage from the electrode 26 to the electrode 21 ensues for the relevant electron at the moment when there exists a voltage 2E between the electrodes 26 and 21, the electrode 21 being positive relatively to the electrode 26, so that on passing from the electrode 26 to the electrode 2'! the electron is accelerated under the influence of the voltage 2E.

Similarly, an electron which enters the electrode 26 at the moment when the electrode 26 has a negative velocity E relatively to the electrode 23 will leave the electrode 21 at a moment when this electrode has a positive velocity E relatively to the electrode 24 with the result that this electron is retarded both on entering and on leaving the control space. In addition, the passage from the electrode 26 to the electrode 21 ensues at a moment when the electrode 26 has a positive voltage 2E relatively to the electrode 2! and on passing from the electrode 26 to the electrode 2'! the electron is retarded under the influenceof the voltage 2E.

The electrons which enter the control space at the above-mentioned moments are consequently accelerated or retarded respectively in succession on passing from one electrode to the next following under the influence of a voltage E, 2E and E, which has the same eifect as though, under the influence of a voltage 4E, an acceleration or retardation respectively were brought about once.

Owing to this, an electron beam which passes into the electrode 24 will be constituted by electrons having a higher and electrons having a lower speed than the initial speed of the electrons in the beam.

The electrodes 26 and 21 are supplied with control voltages having a relative phase displacement of 180 by inserting an oscillatory circuit between the electrodes 26 and 21 and feeding a control voltage to this circuit. Preferably, the

middle point of each of the electrodes is connected to one of the conductors of a Lecher-line system 23 comprising two parallel conductors and whose middle point may be grounded through a high frequency choke coil while its length is so regulated by means of a bridge 29 that the circuit formed by the Lecher conductors and the electrodes 26 and 21 is tuned to the frequency of the control oscillation.

The speed variations are converted into variations in intensity outside the control space in a so-called overtaking or drift space, said space being formed by the space enclosed by the electrode 26. In this field free space the accelerated electrons after some time will have overtaken the retarded electrons so that in the beam are produced density variations or in fact intensity variations, which latter are dependent on the speed variations present and thus on the amplitude of the control voltage which is supplied in counter phase to the electrodes 26 and 21.

For the purpose of deriving energy from the beam that is varied in intensity, the electron beam is passed through a space between the two

electrodes

24 and 34 and which, internally or externally of the tube l6, preferably encloses two electrodes 36 and 31.

The electrodes 36 and 31 are interconnected by an oscillatory circuit 38 which is so proportioned that the circuit formed by the circuit 38 and the electrodes 36 and 3! is tuned to the frequency of the control oscillation or a harmonic thereof. In the given form of construction the oscillatory circuit is formed by a Lecher-line system comprising two conductors whose length can be adjusted by means of a bridge 39 and each of which is connected to the middle point of one of the electrodes 36 and 31 respectively. The electrical middle point of the circuit which is formed by the Lecher-line system and the electrodes 36 and 31 is preferably earthed via a high-frequency choke coil and .thus has the same potential as the circumscribing electrodes. On. passing through the space bounded by the

electrodes

24 and 34, the groups of electrons of variable density induce an alternating current in thecircuit which connects the electrodes 36 and 31 whose frequency corresponds to that of the control voltage supplied to the electrodes 26 and 21. Due to thisoscillations are generated in the oscillator circuit 38 having the same frequency or a harmonic frequency thereof; these oscillations bring about voltages having a phase difference of at the electrodes 36 and 3? and may be supplied to a load circuit. The induction-eifect is, a maximum if the dimension of the electrodes 36 and 31 in the direction of the beam is such that the transit time of the electrons between two neighboring slits or gaps is half a cycle.

Owing to the symmetrical construction of the

electrodes

23, 26, 27 and 24 which form the control space and of the

electrodes

24, 36, 3! and 34 which form the space from which oscillations can be derived, the device according to the invention is particularly suitable for the use of a Lecher-line system comprising two parallel conductors for supplying and deriving energy. Such a Lecherwire system has the advantage over the use of concentric conductors that leading Lecher wires through the tube wall is easily done.

If desired each of the control electrodes 26 and 2? or 36 and 3'1, respectively, may be connected to the corresponding conductors of two Lecherline systems diametrically arranged relatively to the control electrodes and in this, case the influence of the capacity which the control electrodes form relatively to the surroundings on each of the Lecher-line systems is half that of the capacity in the use of only one Lecher-line system.

Such a construction in which each of the

electrodes

26 and 21 or 36 and 31 respectively is provided with two diametrically arranged leadingin wires thus permits of increasing the natural frequency of the oscillatory system of which the electrodes form part.

In the form of construction described the length of the electrodes 26 and 21 was such thatthe transit time of the electrons along these electrodes is half an oscillation period and in this case the speed modulation obtained ensues under other words are so long that the spacing between neighboring slits is a quarter of the oscillation period of the control oscillation if the maximum amplitude of the control voltage supplied is 2E. As a matter of fact, with this choice of the length of the

electrodes

36 and 37 an electron that enters the control space at the moment at which there is no potential difference between the electrodes 23 and 26 will pass through the intermediate space between the electrodes 26 and 21' after a quarter of the oscillation period of the control oscillation and at this moment the electrode 21 has either a positive or a negative voltage of AE relatively to the electrode 26 so that the electron that entered the control space without being accelerated or retarded is accelerated or retarded, respectively, on passing from the electrode 26 to the electrode 21 under action of a voltage 4E. On the control space being left a quarter of the oscillation period later, again an acceleration does not occur, because at this moment there is no voltage drop between the electrodes 2'! and 24.

The electrodes 36 and 31 may be given a corresponding length.

The form of construction in which the length of the electrodes 26 and 21 is such that the transit time of the electrons between neighboring slits is a quarter of the oscillation period of the control oscillation offers the advantage that the capacity which the electrodes 25 and 21 form relatively to each other and to the surroundings is materially lower than in the other form of construction described so that this form of construction permits of obtaining oscillations of higher frequency. In addition, it may be observed that the more the length of the control electrodes increases the greater is the possibility that density variations occur even in the control space with the result that the speed control ensuing at the ends of the control space becomes less effective. Furthermore, it must be borne in mind that the length of the speed control electrode may have any value between the very favorable values indicated in the forms of construction described.

The device according to the invention is not only adapted for amplifying a control oscillation which is supplied in counterphase to the speed control electrodes 26 and 2'5; it may also be used for generating oscillations and in this case the circuits 28 and 38 should be coupled together. In addition, the device according to the invention has been found to be highly advantageous for frequency-changing, for example mixing of ultrahigh frequency oscillations, and in this case use is preferably made of a device comprising at least two electrode systems for controlling the speed of the electrons, the said systems having respectively supplied to them control voltages of different frequencies.

For generating, amplifying or changing the frequency of oscillations of very high frequency the electrodes 26 and 21 or 3B and 31, respectively, are united for example to form a hollow body which is turned to the frequency of oscillations to be generated, amplified or changed in frequency.

While we have indicated the preferred embodiments of our invention of which we are now aware and have also indicated only one specific application for which our invention may be em ployed, it will be apparent that our invention is by no means limited to the exact forms illustrated or the use indicated, but that many variations may be made in the particular structure used and the purpose for which it is employed without departing from the scope of our invention as set forth in the appended claims.

What we claim as new is:

1. An electron discharge device including a cathode for supplying electrons and means for forming electrons from the cathode into a directed beam, a collector for said electrons, electrode means positioned between the beam vforming means and the collector providing a 'control space and other electrode means within said control space comprising a pair of hollow electrodes through which the beam is to be directed, said electrodes being adapted to have high frequency voltages applied thereto out of phase with each other for successively accelerating the electrons in the beam and means between the collector and said control space providing means for extracting energy from the beam.

2. An electron discharge device having a cathode for supplying electrons, means for form ing the electrons from the cathode into a directed beam and a collector for said electrons, means between said beam forming means and said collector providing a pair of spaces including a control space and a space for extracting energy from the beam of electrons, a' pair of control electrodes positioned adjacent each other within one of said control spaces and adapted to have high frequency voltages applied therebetween for successively accelerating the electrons in the beam directed through the control space and other electrode means in another of said spaces for extracting energy including a second pair of adjacent electrodes to be successively passed by the beam and adapted during operation of the device to have high frequency voltages applied to the second pair of electrodes for successively retarding electrons in the beam for extracting energy from the beam.

3. An electron discharge device having a cathode for supplying electrons, means for forming the electrons from the cathode into a directed beam and a collector for said electrons, means between said beam forming means and said collector providing a pair of spaces including a control space and a space for extracting energy from the beam of electrons, a pair of control electrodes positioned adjacent each other within one of the control spaces and adapted to have high frequency voltages applied therebetween for successively accelerating the electrons in the beam directed through the control space and electrode means in another of-said; spaces for extracting energy including a second.

pair of adjacent electrodes to be successively passed by the beam and adapted during opera, tion of the device to have high frequency voltages applied to the second pair of electrodes for successively retarding electrons in the beam for extracting energy from the beam, the electrode means defining said spaces including a member ing a pair of spaces and including a contro1 space and a space for extracting energy from said beam of electrons, said means comprising a plurality of tubular conducting members and a pair of control electrodes positioned adjacent each other in one of said spaces and adapted to have a high frequency voltage applied therebetween for successively accelerating the electrons in the beam directed through the space, and other electrode means in the other space for extracting energy from saidbeam including a second pair of adjacent electrodes to be successively passed by the beam and adapted during operation of the device to have high frequency voltages applied to the second pair of electrodes for successively retarding electrons in the beam.

5. An electron discharge device having a cathode for supplying a beam ofelectrons and a collector for receiving said electrons, means between said cathode and said collector providing a pair of spaces and including a control space and a space for extracting energy from said beam of electrons, said means comprising a plurality of tubular conducting members and a pair of tubular control electrodes positioned ad- J'acent each other in one of said spaces and adapted to have a high frequency voltage applied therebetween for successively accelerating the electrons in the beam directed through the space, and other electrode means in the other space for extracting energy from said beam including a second pair of adjacent tubular electrodes to be successively passed by the beam and adapted during operation of the d evice to.

have high frequency voltages applied to the sec- 0nd pair of electrodes for successively retarding electrons in the beam, means defining said.

spaces including a member for providing a fieldfree space between the control space and the energy extracting space.

KLAAS POSTHUMUS.

FRANS MICHEL PENNING. EDUARD GERARDUS DORGELO. CORNELIS VERBURG.