EP0350357A1 - Superconductor device for electron injection into an electronic tube - Google Patents

Abstract

The subject of the present invention is a device for injecting electrons into an electron tube (1) which comprises: a superconducting bar (3) a first end (31) of which emerges into the tube (1), and electrical power-supply means (4). The bar (3) acts as a cathode. Two anodes, principal (6) and secondary (7), are disposed in the tube (1), respectively in the position where the electrons are collected and in the position where the first end (31) of the bar (3) emerges. The electrical power-supply means (4) ensure the application of two voltages, principal and secondary. Electrons are accelerated along the bar (3) by virtue of the two voltages, and acquire kinetic energy at least equal to the energy of extraction from the superconductor, and are thus ejected from the bar (3). <IMAGE>

Description

The subject of the present invention is a device for injecting electrons into an electron tube which takes advantage of the high speed that electrons accelerated by an electric field can acquire in a superconductive material. These electrons are in fact capable of acquiring kinetic energy at least equal to the energy, called extraction energy in the following, which is necessary for them to cross the potential barrier initially confining them in the material.

The operation of any electron tube is based on the existence inside the tube of an electron beam. Any electron tube must therefore be fitted with an electron injection device. The characteristics of the electron beam supplied, such as its intensity and directivity, are variable depending on the type of tube considered, however it is necessary in most cases to have an electron beam substantially parallel, narrow, and intense . These constraints are for example essential to equip a microwave tube, such as a traveling wave tube or a klystron, or a Crookes tube (X-ray emitter), or a cathode ray tube.

There are known electron injection devices intended to equip an electronic tube. A known frequently used device takes advantage of thermoelectronic emission, that is to say the emission of electrons by certain metals (referred to as thermoemissives in the following) when they are heated, the intensity of this emission being the higher the hotter these metals are. This known device generally comprises a heat conducting plate, one face of which is covered with a layer of a thermoemissive metal and is oriented towards the zone of the tube where the electrons must be injected. This plate constitutes a cathode and is heated by means of a filament in which an electric current flows. An anode is arranged in the tube. The current created by the electrons emitted by the heated cathode increases, at a given temperature and for a given emissive surface, with the potential difference applied between the cathode and the anode then reaches a saturation value which is all the greater as the temperature is high. This current is therefore limited by the very principle of operation of the known device.

Another known device operates on the same principle but has a different geometry: the plate is replaced by a hollow cylinder whose external surface is covered with a thermoemissive metal, and the filament is located in the hollow of the cylinder.

These two known devices, in addition to the principle limitation of the electronic current which they can supply, mentioned in the above, have two main drawbacks. On the one hand, they generate a divergent electron beam (the thermoelectronic emission being a substantially isotropic phenomenon, the directions of emission of the electrons ejected out of the thermoemissive metal are distributed in a cone of solid angle substantially equal to 2 ¶ steradian) and therefore need to be accompanied by devices for concentrating the directions of the emitted electrons, which increases the complexity of the means for injecting electrons into the tube. On the other hand, these known devices have a duration of use limited by a degradation of the layer of thermoemissive metal (the latter, brought to high temperature, tends to sublimate, that is to say to pass from solid state in gaseous state).

The device according to the invention is based on a principle different from that set out in the above; in fact, this device takes advantage of one of the properties of a superconductive material, namely the high mobility of the electrons in a superconductor. The device which is the subject of the invention in fact comprises a bar of a material superconductor of predetermined length, a first end of which opens into the tube and the second end of which is connected to electrical supply means so that the bar acts as a cathode. An anode, called main in the following, is located in the tube, the cathode and the main anode preferably being located at a first and at the second end of the tube, respectively. Electrons are accelerated along the bar and reach the first end of it with a kinetic energy greater than or substantially equal to the energy of extraction of the superconductive material. These electrons are then ejected from the first end of the bar and injected into the tube, in a direction substantially parallel to the axis of the bar. The treatment to which the electrons are then subjected depends on the type of electron tube considered. An anode, called secondary in the following, is placed in the part of the tube where the electrons are injected and is brought to a so-called secondary voltage. To initiate the injection phenomenon, the secondary voltage is brought to a starting value, high and independent of the main voltage. Then, it is brought to an operating value, lower and lower than the voltage at which the main anode is brought.

A more specific subject of the invention is a device for injecting electrons into an electronic tube, characterized in that it comprises:
- a bar of predetermined length, made of a superconductive material, a first end of which opens into the injection part of the tube;
- Power supply means, ensuring the application of a main voltage between the second end of the bar, the latter playing the role of a cathode, and a main anode located in the receiving part of the tube;
- means for initiating the electron injection phenomenon; electrons being accelerated by the electric field applied between the cathode and the anode along the rod, thereby acquiring a kinetic energy at least equal to the energy of extraction of the material constituting the bar, and thus being ejected out of the bar, by the first end of the latter and injected into said part of the tube.

The device obtained overcomes the drawbacks of known devices. Indeed, the intensity of the electron beam generated is not limited in any way by the principle of creation of this beam; the directions of emission of the electrons are all substantially parallel to the axis of the bar; the temperature of the cathode being lower than the critical temperature of the superconductive material, and this cathode comprising no thin surface deposit, the device does not wear out like the known devices.

• -la figure 1, une coupe d'un premier mode de réalisation du dispositif selon l'invention ;
• -la figure 2, une coupe d'un second mode de réalisation du dispositif selon l'invention ;
• -la figure 3, une coupe d'un troisième mode de réalisation du dispositif selon l'invention ;
• -la figure 4, une coupe d'un quatrième mode de réalisation du dispositif selon l'invention ;
• - la figure 5, une coupe d'un cinquième mode de réalisation du dispositif selon l'invention.

Special features and different embodiments of the invention will appear during the description which follows, with the aid of the appended figures, which represent:

• FIG. 1, a section of a first embodiment of the device according to the invention;
• FIG. 2, a section of a second embodiment of the device according to the invention;
• FIG. 3, a section of a third embodiment of the device according to the invention;
• FIG. 4, a section of a fourth embodiment of the device according to the invention;
• - Figure 5, a section of a fifth embodiment of the device according to the invention.

In these figures, on the one hand the proportions of the different elements are not observed, and on the other hand the same references relate to the same elements.

The following description will be given by way of example in the case where the material constituting the bar is not superconductive at ambient temperature, and becomes superconductive when it is cooled to the temperature of liquid nitrogen. However, the use of a superconductive material having a very different critical temperature falls within the scope of the invention.

In these various figures, a device according to the invention equips an electronic tube 1 abstractly separated into three parts:
- A part 11, where the electrons are injected, called injection in what follows;
a part 12, where the electrons are treated, known as the treatment in the following (such treatment of the electrons depending on the type of tube considered);
- A part 13, where the electrons are collected after treatment, called reception in the following.

The processing part 12 having a very precise geometry which depends on the type of tube considered, is very schematically represented by a rectangle. The injection 11 and receiving 13 parts are delimited by walls 2 of the tube 1, which are for example made of ceramic.

FIG. 1 illustrates a first embodiment of the device according to the invention which comprises:
a thin bar 3, also called a rod in the following, made of a first material which is superconductive, playing the role of a cathode, and of which a first end 31 opens into the injection part 11 of the tube 1;
-an anode (called main) 6, located in the receiving part 13 of the tube 1;
- An anode (called secondary) 7, located in the injection part 11 of the tube 1;
electrical supply means 4, ensuring the application of two independent voltages, qualified respectively as main and secondary, applied respectively between the main anode and the secondary anode on the one hand, and the cathode constituted by the rod 3 on the other hand.

The rod 3 is electrically connected to the supply means 4 via a part 8, so as not to deteriorate the superconductivity of the rod 3 by heating during the passage of an intense electric current; this piece 8 further provides a mechanical rigidity function of the rod 3. For example, this part 8 is made of a second material, which is electrically conductive (such as copper) and has the shape of a bar , whose transverse dimensions are greater than those of the rod 3; the rod 3 is embedded over substantially its entire length, and on the side of its second end 32 in this part 8, so that only the first end 31 of this rod 3 protrudes from the part 8.

The device of Figure 1 further comprises cooling means ensuring the maintenance of the material constituting the rod 3 in a superconductive state. This material is cooled by means of part 8, the material constituting this part 8 also being a heat conductor. This part 8 is in fact immersed in a tank 5, filled with liquid nitrogen 24, and enclosing in a sealed manner for example by means of a solder the two ends of the part 8 at two orifices 20 and 21 (respectively qualified as second and third in the following), the rod 3 projecting as little as possible out of the tank 5 through the third orifice 21: the tank 5 is in fact rigidly and tightly fixed to the walls 2 of the tube 1 so that the third orifice 21 opens into the injection part 11 of the tube 1. For example, the walls 2 of the tube 1 are made of ceramic and the tank 5 is made of Kovar, which allows such fixing to be carried out by soldering. The tank 5 is also connected to a liquid nitrogen tank by means of a pipe 23 and open to the open air at the level of an orifice 9 (described first in the following): in a manner known by l '' skilled in the art, liquid nitrogen 24 permanently feeds the tank 5 and evaporates continuously through the first orifice 9. The part 8 is long enough for the rod 3 to remain at low temperature although the part 8 is in contact with the outside of the tank. Finally, thermal insulation means 22, known in themselves, substantially completely surround the tank 5 and at least partially the injection part 11 of the tube 1: these means 22, in particular, reduce heat loss and protect users.

During operation, the electrons supplied by the supply means 4, and having reached the part 8, are accelerated towards the injection part 11 of the tube 1. They pass into the superconductive rod 3 at its second end 32 , and therefore are accelerated over the entire length of the rod 3. This length is predetermined so that electrons having been accelerated by the electric field corresponding to the voltages created by the electrical supply means 4, have acquired a kinetic energy at least equal to the energy of extraction of the material constituting the rod 3. This ensures the injection into the tube of substantially all the electrons accelerated all along the rod 3. The electron beam obtained is therefore intense . It is also substantially parallel and directed in the direction of the rod 3. Finally, its transverse dimensions are substantially delimited by those of the rod 3. The electrons injected into the injection part 11, of the tube 1 remain grouped thanks to a shape suitable, known per se to those skilled in the art, for the secondary anode. They are then guided to the main anode 6 (the secondary voltage being smaller than the main voltage after initiation of the injection phenomenon) and pass through the processing part 12 of the tube 1, before being collected in the receiving part 13 of the tube.

The operation described in the previous paragraph is preceded by a start-up phase during which the secondary voltage is much higher than during operation where it can be zero. Indeed, electrons initially located in the rod 3 are accelerated towards the first end 31 of this rod 3, thanks to the voltages applied by the electrical supply means 4, but this acceleration only occurs over a distance less than the length of the rod 3. Such electrons are not injected into the tube, remain confined in the first end 31 of the rod 3, and therefore repel the electrons from the supply means 4 which are themselves capable of being injected into the tube. The secondary voltage is therefore brought to a so-called start-up value in what follows, sufficient to initiate the phenomenon of ejection of electrons from the rod 3 by tearing off the electrons accumulated at its first end 31 which obstruct the ejection of electrons from the supply means 4. Once the phenomenon of injectlon has started, the secondary voltage is reduced to a value, called operating in what follows, lower than the starting value. The start-up value of the secondary voltage is independent of the value of the main voltage (which is the same during the initiation of the injection phenomenon and during operation). On the other hand, the operating value of the secondary voltage is lower than the value of the main voltage, so that electrons injected into the injection part 11 of the tube 1 are guided to the treatment part 12, then collected in the part receiving 13 of this tube, as has been explained in the foregoing.

Naturally, one can imagine other means of initiating the phenomenon than the use of a secondary anode without departing from the scope of the invention.

Due to the respective transverse dimensions of the part 8 and of the rod 3, and because of the electrical conductivity of this part 8, a very small fraction of the electrons supplied by the supply means 4 remain in the part 8 (without passing in the superconductive rod 3) up to the part of this part 8 situated on the side of the injection part 11 of the tube 1. Such electrons, called residual electrons in the following, having been displaced in a non-superconductive material do not have a sufficiently high energy to be injected into the tube: they are accumulated in said part of the part 8, where they risk creating a field electric opposing the acceleration of electrons from the second to the first end of the rod 3.

Several solutions are possible in order to reduce the number of residual electrons thus accumulated. Figures 2 to 4 illustrate such solutions.

The second embodiment of the device which is the subject of the invention, illustrated by FIG. 2, differs from the first, illustrated by FIG. 1, in that the rod 3 is only embedded in the part 8 over part of its length ; in other words, the part 8 of FIG. 2 is shorter than that of FIG. 1; this part 8 is partially replaced by a sheath 40, made of an electrically insulating material, such as for example ceramic, surrounding the part of the rod 3 not embedded in the part 8, and rigidly fixed to the part 8. As for example, the part 8 is made of copper, and the sheath 40 is made of ceramic, which allows such fixing by brazing. The sheath, which is electrically insulating, forces the electrons to pass through the superconductive rod 3 at the level of the attachment of the part 8 to the sheath 40 so that these are accelerated over a distance at least equal to the length ( called minimum distance in the following) of the part of the rod 3 not embedded in the part 8. By imposing on this minimum distance to be greater than a predetermined value accessible to those skilled in the art, it is possible d 'Avoid the disadvantage of the device of Figure 1, set out in the foregoing. The transverse dimensions of the sleeve 40 are for example substantially identical to those of the part 8, but they could as well be smaller than that of this part 8. The rest of the description of FIG. 2 is similar to that of FIG. 1, except that the tank 5 encloses the sheath 40 instead of the part 8 at the third orifice 21.

The device illustrated in FIG. 3 differs from that illustrated in FIG. 1 in that the part 8 has a shoulder 41, the part of this part 8 located on the side of the injection part 11 of the tube 1 having transverse dimensions smaller than those of the rest of the part 8. The existence of such a shoulder 41 modifies the lines of the electric field in the part 8, in a manner known to man from art, which forces part of the residual electrons to pass through the rod 3 at this shoulder 41: by choosing the position of the shoulder 41, it is therefore possible to reduce the drawback of FIG. 1, cited in the above.

The device of Figure 4 differs from that of Figure 1 in that the rod 3 is surrounded by a sheath 42 made of an insulating material over substantially its entire length with the exception of its two ends 31 and 32; the rod 3 surrounded by this sheath 42 being embedded substantially over the entire length of the sheath 42 on the side of the second end 32 of the rod 3, so as to leave free the first end 31 of the rod 3. In the configuration of the FIG. 4, the tank 5 encloses a part of the part 8 at the third orifice 21 (while in the configuration of FIG. 3, the tank 5 encloses the sheath 40), which advantageously allows soldering between metals ( indeed, the part 8 is for example of copper and the tank for example of Kovar). The device of FIG. 4 operates in a similar fashion to that of FIG. 2, except that the electrons are accelerated over substantially the entire length of the rod 3.

FIG. 5 illustrates a fifth embodiment of the invention which differs from the first in that the rod 3 embedded in the part 8 is replaced by a bar 3 (of a superconductive material) whose transverse dimensions are only slightly smaller to those of the part 8, the bar being rigidly fixed to the part 8, by means known per se, such as for example by embedding its second end 32 (located on the side of the supply means 4). In the case of the device of FIG. 5, the tank directly encloses the superconducting bar 3 at the level of the third orifice 21. The device of FIG. 5 operates in the same way as that of FIG. 1, but does not have the disadvantage explained in the foregoing: all the electrons supplied by the supply means 4 pass from the part 8 into the superconducting bar 3 at the level of the attachment of the part 8 to the bar 3, and are therefore accelerated over substantially the entire length of the bar 3. The result obtained with the device of FIG. 5 differs from that of the device of FIG. 1 by the transverse dimensions of the electron beam injected into the tube, the number of electrons injected per unit of section of the beam being the same as for figure 1.

Devices operating on the same principle as those of Figures 1 to 5 and having different geometries are of course within the scope of the invention.

Claims (16)

1. Device for injecting electrons into an electronic tube (1), characterized in that it comprises:
a rod (3) of predetermined length, made of a superconductive material, a first end (31) of which opens into the injection part (11) of the tube (1);
means of electrical supply (4), ensuring the application of a main voltage between the second end (32) of the bar (3), the latter playing the role of a cathode, and a main anode (6 ) located in the receiving part (13) of the tube (1);
means for initiating (7) the phenomenon of electron injection; electrons being accelerated by the electric field applied between the cathode and the anode along the rod (3), thus acquiring a kinetic energy at least equal to the energy of extraction of the material constituting the rod (3), and being thus ejected from the bar (3), by the first end (31) thereof and injected into said part (11) of the tube (1). 2. Device according to claim 1, characterized in that the priming means comprise a secondary anode (7) located in the injection part (11) of the tube (1), said electrical supply means (4) ensuring in addition the application of a secondary voltage between the cathode and this secondary anode (7), this secondary voltage being brought to a starting value, high and independent of the main voltage, to initiate the phenomenon of electron injection in the tube (1), then reduced to an operating value, lower and lower than the main voltage, during operation of the device. 3. Device according to one of claims 1 or 2, characterized in that it further comprises a part (8), made of an electrically conductive material, ensuring the electrical connection between the electrical supply means (4) and the bar (3), and reinforcing the mechanical rigidity of the bar (3). 4. Device according to one of the preceding claims, characterized in that it further comprises cooling means (5, 24), maintaining the material constituting the bar (3) in a superconductive state. 5. Device according to claim 4, characterized in that the cooling means (5, 24) comprise a tank (5), filled with a cooling fluid (24), open to the air by a first orifice (9 ) and connected to a fluid reservoir (24) by means of a pipe (23), comprising a second orifice (20) tightly enclosing the part of said part (8) which is located on the side of the supply means electric (4), and finally comprising a third orifice (21) surrounding said first end (31) of the bar (3) and opening into the injection part (11) of the tube (1), thus confining the fluid (24) in the tank (5), the fluid (24) immersing said part (8) and the bar (3), such immersion ensuring their cooling. 6. Device according to claim 5, characterized in that the cooling fluid (24) is liquid nitrogen. 7. Device according to one of claims 5 or 6, characterized in that it further comprises thermal insulation means (22) surrounding both substantially the entire tank (5), and at least a portion of the injection part (11) of the tube (1). 8. Device according to one of claims 3 to 7, characterized in that:
- the bar (3) is a rod;
said part (8) is elongated in the direction of the rod (3) and its transverse dimensions are greater than those of the rod (3),
the rod (3) being embedded, at least partially, on the side of its second end (32), in said part (8), the first end (31) of the rod (3) remaining free. 9. Device according to claim 8, characterized in that the rod (3) is embedded in said part (8) over substantially its entire length with the exception of its first end (31), the third orifice (21) enclosing sealing part of the part (8). 10. Device according to claim 9, characterized in that said part (8) has a shoulder (41), the part of said part (8) located on the side of the injection part (11) of the tube (1) having transverse dimensions smaller than those of the rest of said part (8). 11. Device according to claim 8, characterized in that the rod (3) is embedded in said part (8) only over a part of its length, the part of the rod (3) not embedded in said part (8 ) being surrounded by a sheath, (40) made of an electrically insulating material, and rigidly fixed to said part (8), the third orifice (21) tightly enclosing a part of the sheath (40). 12. Device according to claim 11, characterized in that the transverse dimensions of the sheath (40) are substantially the same as those of said part (8). 13. Device according to claim 11, characterized in that the transverse dimensions of the sheath (40) are lower than those of said part (8). 14. Device according to one of claims 3 to 7, characterized in that:
- the bar (3) is a rod;
- Said piece (8) is elongated in the direction of the rod (3) and its transverse dimensions are greater than that of the rod (3);
- The device further comprises a sheath (42) surrounding the rod (3) over substantially its entire length with the exception of its ends (31, 32);
the rod (3) and the sheath (42) being embedded, over substantially the entire length of the sheath (42) and on the side of the second end (32) of the rod (3), in said part (8), the first end (31) of the rod (3) remaining free. 15. Device according to one of claims 1 or 2, characterized in that it further comprises a part (8) made of an electrically conductive material, ensuring on the one hand the electrical connection between the supply means electric (4) and the bar (3) and secondly the fixing of the bar (3). 16. Device according to claim 15, characterized in that the second end (32) of the bar (3) is embedded in said part (8) and in that the third orifice (21) tightly encloses part of the bar ( 3).

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