US2070319A - Apparatus for influencing the character of electron rays - Google Patents
Apparatus for influencing the character of electron rays Download PDFInfo
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- US2070319A US2070319A US615260A US61526032A US2070319A US 2070319 A US2070319 A US 2070319A US 615260 A US615260 A US 615260A US 61526032 A US61526032 A US 61526032A US 2070319 A US2070319 A US 2070319A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J29/00—Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
- H01J29/84—Traps for removing or diverting unwanted particles, e.g. negative ions, fringing electrons; Arrangements for velocity or mass selection
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J29/00—Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
- H01J29/46—Arrangements of electrodes and associated parts for generating or controlling the ray or beam, e.g. electron-optical arrangement
- H01J29/58—Arrangements for focusing or reflecting ray or beam
- H01J29/62—Electrostatic lenses
- H01J29/622—Electrostatic lenses producing fields exhibiting symmetry of revolution
- H01J29/624—Electrostatic lenses producing fields exhibiting symmetry of revolution co-operating with or closely associated to an electron gun
Definitions
- My invention relates to improvements in apparatus for influencing the character of electron rays.
- the present invention relates to an arrangement by the means of which not so much the path of the electron ray beam as its character with respect to its concentration or density can be influenced.
- electrostatically controlled diaphragms disposed substantially in symmetrical arrangement by way of surrounding the beam, by which diaphragms according to their position and electric charge the beam of electron rays is made convergent, divergent or parallel.
- FIG. 1 shows the general arrangement of .a cathode ray tube with means for deflecting the ray and for influencing its character.
- Figs. 2 to 6 show diagrammatically several ways for differently converging and diverging a cathode ray beam by means of diiferently arranged and charged diaphragms, and
- Figs. 7 to 10 show in transverse section several modifications of the diaphragm shape to attain special efiects.
- k represents the complete source of cathode rays, including the cathode and anode, not shown here in detail since the construction of such sources is well known in the art.
- the two pairs of deflecting plates (11, a: set at 90 to one another are arranged in the customary mannerin the tube so that the cathode ray beam passes between them on its way to the screen S.
- the direction of the beam can be controlled and it can trace in well known manner any kind of configuration on the screen.
- the charged diaphragms have, contrary to the known magnetic influence through stricture fields, the advantage of having very much smaller time constants for their action and are therefore capable of responding correctly as to quantity to exceedingly rapidly occurring influences.
- the width 01' the beam can be altered. It can be made narrower or broader and, therefore, its radial extension be diminished or increased.
- the homogeneity of the velocity of the electrons in the beam can also be increased.
- the electrostatic field of such a charged diaphragm is represented by its lines of force.
- the charge is, for example, assumed to be negative.
- the electrons of a cathode ray stream through the diaphragm they are repelled by it and have the tendency to move toward the axis. They are, therefore, deflected from their original paths, which were assumed to be parallel, toward the axis and caused to form a convergent beam terminating in a focal point 0, beyond which the beam becomes divergent.
- This arrangement may be used to define more sharply the spot of light on the screen of Fig. 1. It is thus also possible to increase the brightness of the spot of light, for the pencil point of electron rays can now be obtained not only by carving out, by means of a diaphragm, the parallel center part of a bundle of rays diverging from the cathode is in all directions, but also, by employing a diaphragm of the said kind with a suitably wide opening and a correctly chosen voltage and placing it relatively close to the oathode, the outwardly straying rays can be collected and made either parallel or convergent, as shown in Fi 3. By this means an exceedingly greater brightness of light is obtained on the screen and the cathode beam is much more efflciently utilized.
- the potential of the diaphragm is made positive instead of negative, the individual electrons of the beam will be drawn toward the diaphragm.
- the parallel beam then becomes a diverging beam as shown in Fig. 4.
- the negative diaphragm has the eifect of a convex lens in optics
- the positive diaphragm has the effect.of a diverging concave lens.
- said possibilities of influencing a bundle or beam of electron rays similarly to the way light rays are acted upon by optical lenses are made use of in the following manner to influence the bundle of rays in accordance with the phenomenon to be reproduced.
- a focal point For instance close to a focal point, an aperture diaphragm is placed which only permits rays of a certain velocity to pass.
- An arrangement of that kind is illustrated in Fig. 5.
- Fig. 5 As the deflection of each individual electron depends upon its velocity, only rays of the same velocity meet in the focal point 0.
- focal points For each velocity occurring in a non-homogeneous beam of electrons, a different focal point is obtained. For example, for a beam having a range of velocities from 121 to in, focal points are. obtained which according to Fig. 5 are located between 01 and 02.
- an aperture diaphragm be, without a charge or with the potential zero, is placed, only rays having the definite velocity u will focus at the point 0 and be able to pass through the aperture, whereas the others will strike against this aperture diaphragm and be excluded by it, either before or after they have focused as shown in dash lines.
- the charge thereby imparted to the aperture diaphragm can easily be led away.
- Behind the diaphragm a homogeneous beam of substantially uniform velocity is obtained. If this beam is now deflected from its direction in space by deflecting plates a1 and as such as are shown in Fig.
- the spot of light will in its movements always retain the same sharpness owing to the deflecting fields being able to deflect all parts of the beam at the same angle of deflection, depending upon their field strength and upon the uniform velocity of the rays.
- the velocity of the beam passing through the aperture diaphragm b: can be varied at will. It can, therefore, easily be adjusted to a value, at which the velocities occurring in the beam can be utilized to best advantage. Should it be desired to make the beam leaving the diaphragm b: in a diverging form parallel again, all that is required is to place a second negatively charged convergence diaphragm in at the same distance as In from the focal point 0, and to impart to it the same potential, as In.
- the charge on diaphragm b3 must therefore be adjustable and controllable simultaneously with that on diaphragm in.
- the intensity of the beam may be varied.
- the beam coming from the left has an approximately homogeneous velocity, then itwill only be able to pass through the opening of the aperture diaphragm be when the controlling diaphragm in has a quite definite voltage.
- the voltage At every other voltage of the diaphragm b1, large portions of the beam will strike against the aperture diaphragm itself and cannot pass through its opening. It is, therefore, possible by controlling the voltage, to vary to a great extent the intensity of the beam passing through the diaphragm.
- the change in intensity of the beam passing through it can be made completely or approximately proportional to the variation of the voltage of the diaphragm bi.
- the intensity of the beam can, therefore, be controlled in a simple manner and for any desired velocity.
- the intensity of the impression of the light on the luminous screen is not exactly proportional to the intensity of the beam, and as the eflect on the eye or on the photographic plate or on any other receiver is not proportional to the light intensity of the luminous screen, all these relations can be taken into account in choosing the shape of the diaphragm o, in order to obtain a proportional or other functional relation between the last impression and the controlling voltage of the diaphragm In.
- Fig. 6 is illustrated a manner in which the various effects of the electrostatic diaphragms may be combined.
- a divergent beam is emitted, which passes through the suitably charged diaphragm b1 by which it is made almost parallel.
- the properly charged diaphragm b2 concentrates the beam and throws through the opening in the uncharged aperture diaphragm b3 only the rays having the desired velocity.
- Under certain conditions 171 and b: can be joined into one.
- a homogeneous divergent beam is projected through diaphragm D4. which may carry a.
- the charged diaphragm be concentrates on to the luminous screen s the divergent beam coming from be.
- the diaphragm be may be controlled in dependence on D4, in order again to concentrate on the luminous screen s also the rays partly screened off and having a diiferent focal point outside of be.
- the simplest form is that of the disk-diaphragm according to Fig. '7 with a round opening.
- Another shape is represented by a circular ring, as in Fig. 8, also producing an axially symmetrical field, which is proportional to the distance from the axis.
- the course of the field can be varied in the effective deflecting zone.
- a similar variation is also obtained by means of a combination of a circular ring with a surrounding differently charged casing, as in Fig. 10.
- a device for influencing the individual rays of a beam of electrically charged rays of a given diameter comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being substantially larger than the beam diameter to permit the passage of the entire beam, said diaphragm adapted to be electrically charged at a suitable negative potential with respect to said source and being spaced therefrom for converging the rays of the beam, a second apertured diaphragm spaced entirely independent irom the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays converged by the first diaphragm, which focus in the aperture of the second diaphragm, where
- a device for influencing the individual rays of. a beam of electrically charged rays of a given diameter comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed synifi'etrlcally to the tube axis, said aperture being substantially larger than the beam diameter to permit the passage or the entire beam, said diaphragm being spaced from said source and adapted to be negatively charged with respect to said source for converging the rays of the beam, a second apertured diaphragm spaced entirely independent from the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays converged by the first diaphragm, which focus in the aperture of the second diaphragm, where
- a device for influencing the individual rays of a beam of electrically charged rays of a given diameter comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sufllciently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for diiierently deflecting some of the beam rays with respect to others, said diaphragm being composed of a plurality of concentric elements, spaced from one another to permit their charge at difierent potentials.
- a device for influencing the individual rays of a beam of electrically charged rays of a given diameter comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sumciently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for difierently deflecting some of the beam rays with respect to others, said diaphragm being composed of a plurality of concentric elements located in one plane and spaced from one another to permit their charge at difierent potentials.
- a device for influencing the individual rays of a beam of electrically charged rays of a given diameter comprising a-tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sufficiently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for differently deflecting some of the beam rays with respect to others, said diaphragm being composed of two concentric elements having different size apertures, one element surrounding the other, said elements being spaced apart from one another to permit their charge at different potentials.
Description
Feb. 9, 1937. R. RUDENBERG APPARATUS FOR INFLUENCING THE CHARACTER OF ELECTRON RAYS 2 Sheets-Sheet 1 Filed June 5, 1932 Feb. 9, 1937. R. RUDENBERG APPARATUS FOR INFLUENCING THE CHARACTER OF ELECTRON RAYS 2 sheets-sheet 2 Filed June 3, 1932 til Patented Feb. 9, 1937 I UNITED STATES PATENT OFFICE APPARATUS FOR INFLUENCING THE CHARACTER OF ELECTRON RAYS Reinhold Riidenberg,
Berlin- Grunewald, Ger- 7 Claims.
My invention relates to improvements in apparatus for influencing the character of electron rays.
It is known to be possible to control by means of electrical and magnetic fields the course in space of electron rays, as produced and employed, for example, in cathode ray tubes by using lateral deflecting plates placed in different positions relatively to one another, and which deflect the rays in two difierent directions and through the control of which, therefore, any kind of figure can be traced on a screen.
The present invention relates to an arrangement by the means of which not so much the path of the electron ray beam as its character with respect to its concentration or density can be influenced. For this purpose according to the invention electrostatically controlled diaphragms, disposed substantially in symmetrical arrangement by way of surrounding the beam, by which diaphragms according to their position and electric charge the beam of electron rays is made convergent, divergent or parallel.
My invention is illustrated in the accompanying drawings in which Fig. 1 shows the general arrangement of .a cathode ray tube with means for deflecting the ray and for influencing its character.
Figs. 2 to 6 show diagrammatically several ways for differently converging and diverging a cathode ray beam by means of diiferently arranged and charged diaphragms, and
Figs. 7 to 10 show in transverse section several modifications of the diaphragm shape to attain special efiects.
Referring to Fig. 1, k represents the complete source of cathode rays, including the cathode and anode, not shown here in detail since the construction of such sources is well known in the art. The two pairs of deflecting plates (11, a: set at 90 to one another are arranged in the customary mannerin the tube so that the cathode ray beam passes between them on its way to the screen S. When varying charges are applied to these two pairs of plates the direction of the beam can be controlled and it can trace in well known manner any kind of configuration on the screen.
The locations of the aforementioned diaphragms constituting the subject matter of the present invention are indicated by hi and ha.
The charged diaphragms have, contrary to the known magnetic influence through stricture fields, the advantage of having very much smaller time constants for their action and are therefore capable of responding correctly as to quantity to exceedingly rapidly occurring influences. Through the variable convergence or divergence of the individual paths of the electron beam brought about by the diaphragms, the width 01' the beam can be altered. It can be made narrower or broader and, therefore, its radial extension be diminished or increased. The homogeneity of the velocity of the electrons in the beam can also be increased. By such means, on the one hand, much more clearly defined light spots than hitherto obtainable can be produced on the screen s, and, on the other hand, the light spots can be blurred to a certain degree. It is furthermore possible to regulate the intensity of the beam and the light within wide limits and one is able to control all these operations with practically any desired speed from the outside through the application of variable voltages.
In Fig. 2, the electrostatic field of such a charged diaphragm is represented by its lines of force. The charge is, for example, assumed to be negative. When the electrons of a cathode ray stream through the diaphragm, they are repelled by it and have the tendency to move toward the axis. They are, therefore, deflected from their original paths, which were assumed to be parallel, toward the axis and caused to form a convergent beam terminating in a focal point 0, beyond which the beam becomes divergent. As the radial component of the fleld strength of the diaphragm is zero in its axis and at first increases outwardly linearly, the individual electrons will be all the more deflected from their paths the greater their distance from the axis of the beam and of the diaphragm. Hereby all the rays are caused to meet in the same focal point 0. To obtain with sufiicient accuracy this proportionality of the radial field strength to the distance from the axis, it is advisable to make the diaphragm opening considerably larger than the diameter of the original beam.
This arrangement may be used to define more sharply the spot of light on the screen of Fig. 1. It is thus also possible to increase the brightness of the spot of light, for the pencil point of electron rays can now be obtained not only by carving out, by means of a diaphragm, the parallel center part of a bundle of rays diverging from the cathode is in all directions, but also, by employing a diaphragm of the said kind with a suitably wide opening and a correctly chosen voltage and placing it relatively close to the oathode, the outwardly straying rays can be collected and made either parallel or convergent, as shown in Fi 3. By this means an exceedingly greater brightness of light is obtained on the screen and the cathode beam is much more efflciently utilized.
If the potential of the diaphragm is made positive instead of negative, the individual electrons of the beam will be drawn toward the diaphragm. The parallel beam then becomes a diverging beam as shown in Fig. 4. Whilst the negative diaphragm has the eifect of a convex lens in optics, the positive diaphragm has the effect.of a diverging concave lens. By combining such diaphragms, all the instruments known in optics and involving converging and diverging light beams can be imitated for electron rays and "thereby a series of interesting and useful results be obtained. It is in this manner possible, for example, to build a microscope for use with direct or reflected electron rays, and with which a much greater magnification can be obtained than with our optical microscopes, limited in this respect by the wave length of light.
According to the invention, said possibilities of influencing a bundle or beam of electron rays similarly to the way light rays are acted upon by optical lenses, are made use of in the following manner to influence the bundle of rays in accordance with the phenomenon to be reproduced.
For instance close to a focal point, an aperture diaphragm is placed which only permits rays of a certain velocity to pass. An arrangement of that kind is illustrated in Fig. 5. As the deflection of each individual electron depends upon its velocity, only rays of the same velocity meet in the focal point 0. For each velocity occurring in a non-homogeneous beam of electrons, a different focal point is obtained. For example, for a beam having a range of velocities from 121 to in, focal points are. obtained which according to Fig. 5 are located between 01 and 02. If at a spot 0 within the said focal'range, an aperture diaphragm be, without a charge or with the potential zero, is placed, only rays having the definite velocity u will focus at the point 0 and be able to pass through the aperture, whereas the others will strike against this aperture diaphragm and be excluded by it, either before or after they have focused as shown in dash lines. The charge thereby imparted to the aperture diaphragm can easily be led away. Behind the diaphragm, a homogeneous beam of substantially uniform velocity is obtained. If this beam is now deflected from its direction in space by deflecting plates a1 and as such as are shown in Fig. 1 or by magnetic fields, the spot of light will in its movements always retain the same sharpness owing to the deflecting fields being able to deflect all parts of the beam at the same angle of deflection, depending upon their field strength and upon the uniform velocity of the rays.
By varying the negative strength of the controllable diaphragm b1, the velocity of the beam passing through the aperture diaphragm b: can be varied at will. It can, therefore, easily be adjusted to a value, at which the velocities occurring in the beam can be utilized to best advantage. Should it be desired to make the beam leaving the diaphragm b: in a diverging form parallel again, all that is required is to place a second negatively charged convergence diaphragm in at the same distance as In from the focal point 0, and to impart to it the same potential, as In. The charge on diaphragm b3 must therefore be adjustable and controllable simultaneously with that on diaphragm in.
In a similar manner the intensity of the beam may be varied. Let us assume that, in Fig. 5. the beam coming from the left has an approximately homogeneous velocity, then itwill only be able to pass through the opening of the aperture diaphragm be when the controlling diaphragm in has a quite definite voltage. At every other voltage of the diaphragm b1, large portions of the beam will strike against the aperture diaphragm itself and cannot pass through its opening. It is, therefore, possible by controlling the voltage, to vary to a great extent the intensity of the beam passing through the diaphragm. By
choosing the proper kind of opening for dia-' phragm be, both with respect to size and shape, the change in intensity of the beam passing through it can be made completely or approximately proportional to the variation of the voltage of the diaphragm bi. The intensity of the beam can, therefore, be controlled in a simple manner and for any desired velocity. As the intensity of the impression of the light on the luminous screen is not exactly proportional to the intensity of the beam, and as the eflect on the eye or on the photographic plate or on any other receiver is not proportional to the light intensity of the luminous screen, all these relations can be taken into account in choosing the shape of the diaphragm o, in order to obtain a proportional or other functional relation between the last impression and the controlling voltage of the diaphragm In.
In Fig. 6 is illustrated a manner in which the various effects of the electrostatic diaphragms may be combined. From the cathode k, a divergent beam is emitted, which passes through the suitably charged diaphragm b1 by which it is made almost parallel. The properly charged diaphragm b2 concentrates the beam and throws through the opening in the uncharged aperture diaphragm b3 only the rays having the desired velocity. Under certain conditions 171 and b: can be joined into one. Thus, a homogeneous divergent beam is projected through diaphragm D4. which may carry a. pulsating charge, and thus the beam is passed to the diaphragm in through the opening of which only the rays pass which vary in intensity. The charged diaphragm be concentrates on to the luminous screen s the divergent beam coming from be. The diaphragm be may be controlled in dependence on D4, in order again to concentrate on the luminous screen s also the rays partly screened off and having a diiferent focal point outside of be. By means of the deflecting plates :11 and as, the homogeneous beam varying in its intensity can now be easily and accurately moved in the direction of the various coordinates.
Regarding the shape to be given to the electrostatic diaphragm, there are various possibilities producing differing results. The simplest form is that of the disk-diaphragm according to Fig. '7 with a round opening. Another shape is represented by a circular ring, as in Fig. 8, also producing an axially symmetrical field, which is proportional to the distance from the axis. By combining the ring with the disk-diaphragm, as in Fig. 9, the two being similarly or contrarily charged or only having a difference in voltage, the course of the field can be varied in the effective deflecting zone. A similar variation is also obtained by means of a combination of a circular ring with a surrounding differently charged casing, as in Fig. 10. To obtain a sharp lensor focus-effect, forms of electrodes or diaphragms with edges forming such curves are employed that their effect upon the electron beam passing through them only takes place within a narrowly limited zone, and that within that zone the radial field strength is as proportional as possible to the distance from the axis, whilst the axial field strength to the right and left of the diaphragm is symmetrical in its course, in order that the additional axial acceleration and retardation of the electrons cancel each other in their effect.
By means of the described arrangements, it is possible to obtain clear and sharp images on the luminous screen s, said images giving, when the fields of the diaphragms andthe deflecting fields are suitably adjusted and controlled, the impression of a stationary moving picture frame.
I claim as my invention:
1. A tube containing a source for producing a beam of electrically charged rays of a given diameter and normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to said tube axis, said aperture being substantially larger than the beam diameter to permit the passage of the entire beam, said diaphragm adapted to be electrically charged at a suitable negative potential with respect to said beam source and being spaced therefrom for converging some of the beam rays with respect to others, and a second apertured diaphragm, spaced entirely independent from the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays deflected by the first diaphragm, which focus in the aperture of the second diaphragm, whereby only rays of similar speed are permitted to pass through the second diaphragm.
2. A tube containing a source for producing a beam of electrically charged rays of a given beam diameter, and normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to said tube axis, said aperture being substantially larger than said beam diameter to permit the passage of the entire beam, said diaphragm adapted to'be electrically charged at a suitable negative potential with respect to said source and being spaced therefrom for converging the rays of the beam, a second apertured diaphragm spaced entirely independent from the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays converged by the first diaphragm, which focus in the aperture of the second diaphragm, whereby only rays of similar speed are permitted to pass through the second diaphragm, and a third apertured diaphragm having its aperture disposed in the tube axis and having a larger diameter than the beam, said third diaphragm being spaced in the beam direction from the second diaphragm to converge the diverging beam rays emanating from the aperture of said second diaphragm, when a charge negative with respect to said source is applied to said third diaphragm.
3. A device for influencing the individual rays of a beam of electrically charged rays of a given diameter, comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being substantially larger than the beam diameter to permit the passage of the entire beam, said diaphragm adapted to be electrically charged at a suitable negative potential with respect to said source and being spaced therefrom for converging the rays of the beam, a second apertured diaphragm spaced entirely independent irom the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays converged by the first diaphragm, which focus in the aperture of the second diaphragm, whereby only rays of similar speed are permitted to pass through the second diaphragm, and a third apertured diaphragm having its aperture disposed in the tube axis and of a larger diameter than the beam diameter, said third diaphragm being spaced in the beam direction from the second diaphragm, and adapted to be charged at a suitable negative potential with respect to said source to converge the diverging beam rays emanating through said second diaphragm, said first and third diaphragm being equally spaced from the second diaphragm.
4. A device for influencing the individual rays of. a beam of electrically charged rays of a given diameter, comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed synifi'etrlcally to the tube axis, said aperture being substantially larger than the beam diameter to permit the passage or the entire beam, said diaphragm being spaced from said source and adapted to be negatively charged with respect to said source for converging the rays of the beam, a second apertured diaphragm spaced entirely independent from the first diaphragm in the direction of the beam travel, and having its aperture also disposed symmetrically to the tube axis, said second diaphragm aperture being of smaller diameter than the first diaphragm aperture to permit the passage only of those beam rays converged by the first diaphragm, which focus in the aperture of the second diaphragm, whereby only rays of, similar speed are permitted to pass through the second diaphragm, and a third apertured diaphragm having its aperture disposed in the tube axis and of a larger diameter than the beam diameter, said third diaphragm being spaced in the beam direction from the second diaphragm, and adapted to be polarized similar to said first diaphragm with respect to said source to converge the diverging beam rays emanating from said second diaphragm, a screen onto which the beam is projected, and suitably charged deflecting plates arranged on opposite sides of said beam for deflecting the entire beam from its normal direction, said plates being disposed between the screen and said diaphragms.
5. A device for influencing the individual rays of a beam of electrically charged rays of a given diameter, comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sufllciently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for diiierently deflecting some of the beam rays with respect to others, said diaphragm being composed of a plurality of concentric elements, spaced from one another to permit their charge at difierent potentials.
6. A device for influencing the individual rays of a beam of electrically charged rays of a given diameter, comprising a tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sumciently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for difierently deflecting some of the beam rays with respect to others, said diaphragm being composed of a plurality of concentric elements located in one plane and spaced from one another to permit their charge at difierent potentials.
'7. A device for influencing the individual rays of a beam of electrically charged rays of a given diameter, comprising a-tube containing a source for producing said beam in a direction normally extending substantially in line with a given tube axis, an apertured diaphragm in said tube having its aperture disposed symmetrically to the tube axis, said aperture being sufficiently large to permit the passage of the entire beam, said diaphragm adapted to be suitably polarized with respect to said source and being spaced therefrom for differently deflecting some of the beam rays with respect to others, said diaphragm being composed of two concentric elements having different size apertures, one element surrounding the other, said elements being spaced apart from one another to permit their charge at different potentials.
REINHOLD RUDENBERG.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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DE402781X | 1931-05-30 |
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US2070319A true US2070319A (en) | 1937-02-09 |
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US615260A Expired - Lifetime US2070319A (en) | 1931-05-30 | 1932-06-03 | Apparatus for influencing the character of electron rays |
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Cited By (17)
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DE767059C (en) * | 1939-03-09 | 1951-08-16 | Siemens & Halske A G | electron microscope |
US2603550A (en) * | 1951-07-12 | 1952-07-15 | Philco Corp | Method of aligning cathode-ray tube assemblies |
US2627049A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Cathode-ray tube electrode |
US2627047A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Cathode-ray tube electrode |
US2627043A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Image-reproducing device |
US2658160A (en) * | 1951-11-23 | 1953-11-03 | Rauland Corp | Image-reproducing device |
US2673305A (en) * | 1951-05-31 | 1954-03-23 | Rauland Corp | Image-reproducing device |
DE764029C (en) * | 1938-11-05 | 1954-05-10 | Aeg | Electron-optical imaging device, in particular electron microscope, for imaging irradiated objects with the aid of an electric immersion objective |
US2719243A (en) * | 1951-07-03 | 1955-09-27 | Du Mont Allen B Lab Inc | Electrostatic electron lens |
US2760098A (en) * | 1951-05-08 | 1956-08-21 | Rca Corp | Electrostatic focused gun for cathode ray tube |
US2792515A (en) * | 1951-06-22 | 1957-05-14 | Thomas Electrics Inc | Cathode ray tube |
US3702950A (en) * | 1969-04-24 | 1972-11-14 | Matsushita Electronics Corp | Electrostatic focussing-type television picture tube utilizing a plurality of metal disks |
US3798478A (en) * | 1972-09-14 | 1974-03-19 | Gte Sylvania Inc | Multibeam cathode ray tube having a common beam limiting aperture therein |
US5159240A (en) * | 1991-12-09 | 1992-10-27 | Chunghwa Picture Tubes, Ltd. | Low voltage limiting aperture electron gun |
US5182492A (en) * | 1992-05-20 | 1993-01-26 | Chunghwa Picture Tubes, Ltd. | Electron beam shaping aperture in low voltage, field-free region of electron gun |
US5220239A (en) * | 1991-12-09 | 1993-06-15 | Chunghwa Picture Tubes, Ltd. | High density electron beam generated by low voltage limiting aperture gun |
US5223764A (en) * | 1991-12-09 | 1993-06-29 | Chunghwa Picture Tubes, Ltd. | Electron gun with low voltage limiting aperture main lens |
Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE1032418B (en) * | 1937-05-24 | 1958-06-19 | Loewe Opta Ag | Cathode ray tube |
US8894260B2 (en) | 2009-03-31 | 2014-11-25 | Sicpa Holding Sa | Annular light guide illuminator and optical scanner |
-
1932
- 1932-05-30 GB GB15328/32A patent/GB402781A/en not_active Expired
- 1932-05-30 FR FR737816D patent/FR737816A/en not_active Expired
- 1932-06-03 US US615260A patent/US2070319A/en not_active Expired - Lifetime
Cited By (17)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE764029C (en) * | 1938-11-05 | 1954-05-10 | Aeg | Electron-optical imaging device, in particular electron microscope, for imaging irradiated objects with the aid of an electric immersion objective |
DE767059C (en) * | 1939-03-09 | 1951-08-16 | Siemens & Halske A G | electron microscope |
US2760098A (en) * | 1951-05-08 | 1956-08-21 | Rca Corp | Electrostatic focused gun for cathode ray tube |
US2673305A (en) * | 1951-05-31 | 1954-03-23 | Rauland Corp | Image-reproducing device |
US2792515A (en) * | 1951-06-22 | 1957-05-14 | Thomas Electrics Inc | Cathode ray tube |
US2719243A (en) * | 1951-07-03 | 1955-09-27 | Du Mont Allen B Lab Inc | Electrostatic electron lens |
US2627043A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Image-reproducing device |
US2627047A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Cathode-ray tube electrode |
US2627049A (en) * | 1951-07-03 | 1953-01-27 | Rauland Corp | Cathode-ray tube electrode |
US2603550A (en) * | 1951-07-12 | 1952-07-15 | Philco Corp | Method of aligning cathode-ray tube assemblies |
US2658160A (en) * | 1951-11-23 | 1953-11-03 | Rauland Corp | Image-reproducing device |
US3702950A (en) * | 1969-04-24 | 1972-11-14 | Matsushita Electronics Corp | Electrostatic focussing-type television picture tube utilizing a plurality of metal disks |
US3798478A (en) * | 1972-09-14 | 1974-03-19 | Gte Sylvania Inc | Multibeam cathode ray tube having a common beam limiting aperture therein |
US5159240A (en) * | 1991-12-09 | 1992-10-27 | Chunghwa Picture Tubes, Ltd. | Low voltage limiting aperture electron gun |
US5220239A (en) * | 1991-12-09 | 1993-06-15 | Chunghwa Picture Tubes, Ltd. | High density electron beam generated by low voltage limiting aperture gun |
US5223764A (en) * | 1991-12-09 | 1993-06-29 | Chunghwa Picture Tubes, Ltd. | Electron gun with low voltage limiting aperture main lens |
US5182492A (en) * | 1992-05-20 | 1993-01-26 | Chunghwa Picture Tubes, Ltd. | Electron beam shaping aperture in low voltage, field-free region of electron gun |
Also Published As
Publication number | Publication date |
---|---|
FR737816A (en) | 1932-12-16 |
GB402781A (en) | 1933-11-30 |
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