DE1051994B - Ring-shaped electron tube - Google Patents

Description

The invention relates to an annular electron tube with a cathode around the cylindrical arranged, ring-shaped focus electrode, which focuses the electrons coming from the cathode, one the electron collecting anode and one arranged around the focus electrode, ring-shaped Control electrode, and aims to provide a tube in which the flow of electrons without use effectively controlled by grids.

According to the invention, there are two pairs of opposite, ring-shaped between the cathode and anode Plates provided, of which the one lying next to the cathode pair acts as a focus electrode to to bundle the electrons coming from the cathode in an essentially flat, radial fan, while the other pair acts as a control electrode to the electron fan on the way from the cathode to control the anode, and wherein both electrodes work together so that the of The electrons emitted by the cathode do not hit the control electrode.

In the drawings, embodiments of the invention are shown by way of example, namely is

Fig. 1 is a schematic view of the main features of the invention, which in radial section through the electrodes are shown, the shape of the electron fan being shown in dashed lines;

Figure 2 is a vertical section through the center line of a complete tube in accordance with the invention;

Fig. 3 is a horizontal sectional view taken along line 3-3 of Figs

Fig. 4 is a vertical section through part of the tubular casing according to a modified embodiment the outer anode.

As can be seen in particular from Fig. 1, the main features of the invention by a Cathode 5, which is arranged around the vertical tube axis, and a focus electrode 6, which is attached next to the cathode, and by a control electrode 7, which is outside the focus electrode is arranged, and formed by an anode 8, which is outside the control electrode. For reference purposes a center plane is indicated which is perpendicular to the tube axis.

The focus electrode, which has a pair of spaced apart annular plates next to the cathode, is used for this purpose. To direct electrons from the cathode in a substantially flat radial fan along said intermediate plane. The control electrode, which has a second pair of spaced apart ring plates, cooperates with the focus electrode to create an electrostatic field that prevents electrons from hitting the control electrode. On ring-shaped electron tube
Applicant:

Eitel-McCullough Inc.,
San Bruno, Calif. (V. St. A.)

Representative:

E. Maemecke, Berlin-Lichterfelde West, Ringstr. 10,
and Dr. W. Kühl, Hamburg 36, patent attorneys

Claimed priority:
V. St. v. America September 30, 1955

Donald H. Preist, Mill Valley, Calif. (V. St. A.),
has been named as the inventor

this creates a fan of such a shape as shown in Fig. 1 by the dashed lines which represent the top and bottom surfaces of the fan. Since the electrons from the The cathode cannot strike the control electrode, so the control electrode does not take any Electricity and therefore no harmful radiation caused by electron impact is generated. the Difficulties of grid heating and grid radiation do not arise.

The focus electrode is usually operated with a cathode voltage. On this condition the electrode represents a retardation field for the electrons and thus seeks the electron flow in to retain the area of the cathode.

A positive voltage is usually applied to the anode. But as long as the control electrode without If the voltage is positive compared to the cathode, the shielding effect of the control electrode prevents one Flow of electrons from the cathode to the anode. So even if there is anode voltage, the Compartments separated when the control electrode has cathode voltage.

When a positive voltage is applied to the control electrode, it causes the resultant Accelerating field a flow of electrons from the cathode to the anode, the current intensity of the voltage of the control electrode depends.

The tube thus works in a very simple manner from switching off to full anode current sharply separated characteristics, making the tube

809 768/410

is particularly suitable for high voltage circuits. Since the fan runs radially, a large currents can be handled.

As already mentioned, the focus electrode is usually operated with cathode voltage. So it is It should be emphasized that no negative bias on the focus electrode is necessary for the operation of the tube is. The focus electrode can, however, also be operated with negative voltage. If the If the focus electrode works with negative voltage, the current flow through the tube is reduced. this makes it possible to apply an additional modulation of the electron fan by changing the voltage to achieve the focus electrode.

As can be seen in particular from FIG. 2, the tube has a cathode 5, a focus electrode 6, a control electrode 7 and an anode 8 .

The cathode 5 has a heating coil and a cylindrical radiation ring 10 which is covered with oxide and which is arranged between upper and lower metal plates 11 and 12. The cathode is supported by a cylindrical metal rim 14 which is connected to the lower plate 12 and advantageously extends out of the tube shell to form a connection point 141 for the cathode. A heating coil for the cathode is provided in the form of a wire coil 15 which is separated from the cathode ring by means of the insulating material 16 . The upper end of the wire 15 is connected to the upper cathode plate 11 , so that the cathode carrier 14 serves both as a connection point for the heating coil and for the cathode. The lower end of the wire 15 passes through an insulating plug 18 in the lower cathode plate 12 down to a metal pin 19. This pin 19 is housed concentrically within the cathode carrier 14 and separated therefrom by an annular plug 20 made of insulating material. The metal parts of the cathode as well as the various other metal parts mentioned below are preferably made of a material which has good electrical conductivity.

The focus electrode 6 has a pair of annular plates 22, 23 made of metal, which are at a distance from one another and which are arranged next to the opposite ends of the radiation ring 10 . A tubular metal support screen 24 extends downwardly from the lower plate 22 and protrudes outwardly from the tubular envelope to form a connection point 241 for the focus electrode. A shell-like shaped cap screen 25 and a tubular extension 251 made of metal extend over the upper ring plate 23 upwards. It can be seen that the tubular supporting screen 24 concentrically surrounds the cathode carrier 14 and is separated from it by an annular plug closure 26 made of insulating material. Means in the form of one or more vertical ribs, such as metal pins 27 (Fig. 3), are provided to connect the plates 22 and 23 together.

The control electrode 7 has a pair of annular plates 30 and 31 which are spaced apart from one another and which are made of metal and lie outside the electrode plates 22 and 23. A tubular support screen 32 made of metal extends from the top plate 31 to the top of the tube where it is soldered to a plug 33. Since the tube is intended for high voltages, a corona or glow ring 34 is soldered to the plug 33 in order to avoid spark formation. A

tubular, metallic rim portion 35 extends from the lower ring plate 30 downwards. The annular plates 30 and 31 are connected to one another by one or more vertical ribs such as metal bolts 36 (Fig. 3).

The anode 8 has a pair of metal rings 38, 39 which are brazed to one another at their outer ends and are designed so that a V-shaped, annular groove 40 is formed, which ίο opens towards the cathode.

The reason for the formation of such a grooved anode is to capture the electrons generated by the bombardment through the electron fan within the anode so that they cannot reach the positive control electrode. The anode rings 38., 39 are carried by an annular metal 'disc 42 which is soldered or otherwise attached to the upper anode ring 39 and clamped between the metal closure rings 43 and 44 which are welded together at their outer ends and which Form anode connection point. If the tube is used for high-voltage operation, there is the possibility of internal sparking between the control electrode, especially if the latter is switched off during switching operation. To reduce this possibility of sparking, the outer edges of the flanges 30, 31 and the inner edges of the rings 38 and 39 are preferably rounded, as shown in FIG.
The shell for the tube has a lower shell-shaped portion 47 made of insulating material, the closure ring 43 is melted into the upper edge. The bottom of this dish-shaped portion 47 has an opening which allows the insertion of the electrode support screen 24, while a locking ring 48 sealed into the edge of the opening and is soldered or fixed in another manner on the screen 24th The shell also has an inverted cup-shaped upper part 49 made of insulating material, wherein the locking ring 44 is fused in the lower edge. The upper part of the section 49 has an opening for the passage of a plug 33, and a locking ring 50 is melted into the edge of the opening and soldered to the plug 33 or fastened in some other way.

By arranging the connection point for the anode 8 on the circumference of the sheath and the control and focus electrode connection points 33 and 24 at opposite ends of the sheath, a maximum of spacing and insulating space is created between the connection points, which is desirable for high-voltage work. ·

It is desirable to protect the cathode from the control electrode and anode, except in the line of the radial fan, in order to avoid stray fields which destroy the fan field formed by the focus and control electrodes. This is one of the reasons for creating a long, tubular part 24 and the complete canopy screen 25 on the ring plates 22 and 23 of the focus electrode 6. In the same way, one of the reasons for creating the long, tubular parts 32 and 35 on the Ring plates 31 and 30 of the control electrode are used to protect the anode from the cathode and the focus electrode. In addition, the tube-like parts 24, 32 and 34 and the cap screen 25 serve to prevent the shell from being bombarded by stray electrons, which can cause the insulating material to burst

Claims (9)

and what is particularly troublesome and disadvantageous with tubes that work with high voltages. Fig. 4 illustrates a modified embodiment of the invention, in which the anode 8 'protrudes outward from the tube shell and can thus be cooled more easily. If it is desired to maintain the size and spacing of the electrodes shown in FIG. 2 with the outer anode embodiment of FIG. 4, the diameters of shell sections 47 'and 49' can simply be smaller than the diameters of sections 47 and 49 of FIGS. 2 can be made. Similar to the illustration in FIG. 2, the anode plates 38 'and 39' in the embodiment of FIG. 4 are connected to the casing sections 47 'and 49' by locking rings 43 'and 44', respectively. Patent claims: 1. Annular electron tube with a ring-shaped one arranged around the cylindrical cathode Focus electrode and an annular control electrode arranged around the focus electrode and ring-shaped anode, characterized in that between the cathode (5) and anode (8) two pairs of opposite ring-shaped Plates (6, 7) are provided, one of which (6) lying next to the cathode pair as Focus electrode acts to turn the electrons coming from the cathode into an essentially to bundle flat, radial fans, while the other pair (7) acts as a control electrode to the To control electron fans on the way from the cathode to the anode, and with both electrodes work together in such a way that the electrons emitted by the cathode do not appear hit the control electrode (Fig. 1). 2. Annular electron tube according to claim 1, characterized in that the Support devices (24,25,32,35) for the focus and control electrodes at the same time shielding means which shield the cathode from the other parts of the tube (Fig. 2). 3. Annular electron tube according to claim 1, characterized in that the anode connection point (43, 44) on the circumference of the sheath made of insulating material and arranged around the tube axis, the control electrode connection point (33) are attached to one end of the sheath and the focus electrode connection point (241) to the other end of the sheath (Fig. 2). 4. Annular electron tube according to claims 1 to 3, characterized in that the Cathode connection point (141,19) is attached to the end of the sheath at which the focus electrode connection point is, and all connection points are coaxial (Fig. 2). 5. Annular electron tube according to claims 1 and 3, characterized in that a tubular extension (24) protrudes downward from the lower plate belonging to the focus electrode and a second tubular extension (251) from the upper plate belonging to the focus electrode protrudes above (Fig. 2). 6. Annular electron tube according to claim 3, characterized in that the anode at the anode connection point by a device (43, 44) and the focus electrode at its connection point by means (24, 251) which form screens around the cathode and that the control electrode at its connection point (33) is supported by a device (32, 35), which another screen around forms the cathode (Fig. 2). 7. Annular electron tube according to claim 3, characterized in that a tubular Carrying screen (24) on the lower plate of the focus electrode extends to the connection point, that a cap screen (25) is also provided on the top plate of the focus electrode and a tubular support screen (32) up to the connection point (33) of the upper Plate of the control electrode extends while a seated on the lower plate of the control electrode Screen (35) protrudes down to the lower end of the shell (Fig. 2). 8. Annular electron tube according to claim 7, characterized in that a Cathode support (14) is located within the tubular support (24) for the focus electrode extends downward (Fig. 2). 9. Annular electron tube according to one of the preceding claims 1 to 8, characterized in that that the anode (8) is designed as an annular V-groove which opens towards the cathode. Considered publications:
U.S. Patent Nos. 2,409,644, 2,414,843;
British Patent No. 503 852. 1 sheet of drawings ® 809 768/410 2.59