DE367438C - Discharge tubes for electrical vacuum discharges - Google Patents

Description

Discharge tubes for electrical vacuum discharges have already become known, in which each electron, as well as it from its previous metal or gas molecule has become free, is located in the discharge space. From this known arrangement The present one differs in that the ions or electrons do not arise in the main discharge space, but rather are generated in an adjoining room and influenced in whole or in part by an electrical or magnetic auxiliary field be that from the adjoining room ions or electrons in variable numbers into the Main discharge occur. So there are two spaces that have to be distinguished from each other, one of which serves for the maintenance and chief guidance of the river, in which also a great one Part of the ions and electrons is always newly formed. In contrast to those educated here Ions are from a second space outside this main space, which is however under the influence of the former, a controllable larger or smaller supply of these ions accomplished. This can for example take place in that channel rays or light rays or heat from the main discharge space in the second space etc. penetrate, which is, however, designed and switched in such a way that it is new there formed ions cannot easily migrate into the main space. The used The discharge is completely independent in that it is not foreign to the discharge Ion source used.

The ions which are to be influenced are those which are in the vicinity of the Cathode are free, in particular that which is caused by the channel rays of the discharge be generated. The device is made such that the to be influenced Auxiliary field captures the electrons immediately after their creation by the field

extends to the area in which the electrons are generated. The ions that are generated by the discharge itself can be admitted into the cathode dark space of the discharge in a controllable manner. In the case of a certain structural design of the cathode environment, the concentration of the canal rays and the starting point of the ίο cathode rays in an area near the cathode, which occurs automatically under low pressure, is used to generate all or a substantial part of the cathode rays at the location or in the vicinity of the auxiliary field permit. The auxiliary electrical field is generated between the parts that are considered to be parts of the cathode with regard to the potential differences in the discharge. A magnetic field can bring about that the place of origin of the electrons can be compressed to the place of the auxiliary field. When generating the auxiliary electrical field, an electrode can be used which is largely protected from the electron-releasing effect of the discharge, in particular from the impact of the canal rays, possibly by the shielding effect of other fixed parts. The electron-donating parts from which the electrons reach the auxiliary field, or their surfaces, consist of electropositive material or more electropositive material than the other surfaces located in the vicinity of the cathode and the auxiliary field. Those parts which essentially determine the magnetic field at the location of the discharge are expediently arranged in the interior of the discharge tube and can also serve as parts of the cathode at the same time. The cathode and all of the "discharge loading; tuning metal parts are 'designed rotationally symmetrical, the arrangement can be made also in such a manner that the lines of force in the determining, the discharge portion are parallel to the magnetic field of the figure axis of the <cathode.. also, the existing wholly or partly of iron outer can. cathode be covered, especially in the vicinity of the place where the channel rays enter with another, in particular \ non-magnetic metal, or the walls may be one on the origination _-: the location of the electron-supplying channel '- gap or the like of such material j manufactured represents or thus be covered, the location of the auxiliary field is expedient moved away from the immediate vicinity of the pole pieces which determine the discharge controlling magnetic field.... , while the insulating parts that fix the field electrodes against each other are as small as possible! To generate the magnet A permanent "magnet" can serve the field. The device generating the magnetic field can be arranged outside the tube. Furthermore, the parts directly determining the shape of the magnetic field inside the pipe can be made of permanently magnetic material. When the field magnet is arranged outside the tube, it is expediently of such a shape that the tube can be easily replaced. ! The mutual position of the tube socket and the outer magnetic poles can be chosen so that the tube is seated simultaneously with the pole pieces between the pole pieces of the magnet when it is inserted into the socket that conveys the supply lines. ! Of course, it can also be a fine adjustment! bar magnetic field can be used, the regulation being carried out by a magnetic j shunt. The voltage required to generate an auxiliary electrical field is expediently branched off from the battery serving as a power source. Of course, the devices for tubes with strong training and special utilization of the cathode rays, such as X-ray tubes, Braun tubes, can also be used for the purpose of achieving a variable hardness or intensity.

Several exemplary embodiments of such tubes are shown in the drawing.

Fig. Ι refers to a tube for higher vacua. It gives a schematic section through the area of the cathode. Use can be made here of the known fact that on disk-shaped or concave mirror-shaped cathodes, more generally with a rotationally symmetrical shape of the surrounding parts, under certain conditions the bundle of canal rays and the starting point of the cathode rays contract towards the center of the cathode. The center of the cathode K is pierced and thus allows all or part of the channel rays to enter. At a depth, which is to be chosen differently depending on the external conditions and the purpose, lies a material surface C, which is only hit by channel rays and emits electrons. The surface is expediently metallic and insulated from the disk-shaped or concave mirror-shaped »outer cathode« AK. Since it is generally kept at a potential that differs only slightly from that of the outer cathode in relation to the potential difference to the anode, it is appropriately referred to as "inner cathode" or "central cathode" C.

The potential difference between the inner and outer cathode now leaves an electric field

in front of the surface of C, i.e. in a region in the vicinity of which electrons are generated in abundance. If the size ratios are chosen appropriately, taking into account in particular that part of the field of the discharge in front of the outer cathode that reaches into the opening of AK , potential differences of a few volts are sufficient to create sufficient fields. As a numerical example it is stated that in a test at a discharge voltage of tens of thousands of volts with a potential difference of 4 volts, at which C was positive to AK , the negative current of C could be completely suppressed. Since the electrons generated in this area can therefore be significantly influenced by very small fields in the ability to achieve the discharge themselves, but the entire character of the discharge largely depends on the number of electrons entering the cathode area, the result is a very strong influence of the potential difference applied in the auxiliary field on the total discharge. In particular, it is easy to change the discharge voltage or "hardness" of a tube operated with a high voltage source by applying a few volts to the field electrodes, for example doubling the parallel spark gap with the help of the low voltage source. Arrangements based on this principle can therefore be used appropriately where arbitrary variability of the hardness is desirable, for example in all methods that are based on the use of cathode rays, e.g. B. Braun tubes, X-ray tubes. In addition to the above, a number of other exemplary embodiments based on the same principle are conceivable.

In this and in general in all arrangements according to the inventive concept, it can be useful to choose the mainly electron-donating parts, i.e. the surface of C in the example just given, from material that is as electropositive or more electropositive than those whose electrons are not or less completely ins Auxiliary field arrive, in the example about the surface of the outer cathode.

It may also be useful in this and in general in all arrangements according to "the inventive concept, in particular those which are intended in the manner explained below for reinforcement and the like purposes, to lay a part of the parts generating the field, that it is not hit at all or as little as possible by the canal rays or the electron-releasing effect of the discharge. This arrangement has the purpose of reducing the current losses from these parts as much as possible An embodiment of this type of arrangement, which is based on the example already described, is shown in Fig. 2. The part of the outer cathode channel AK ' near the inner cathode is separated from the part near the surface , on the other hand, isolated and somewhat expanded on the other hand, since the canal rays are essentially run parallel to the channel axis, they are largely kept away from the walls of the rear part by the walls of the front channel part. A potential difference existing between the rear part AK ' and the affected surface (here C) nevertheless creates an electric field of the desired type in front of the affected surface, with which the electrons generated on it can be influenced.

An embodiment of the second type, in which by an external aid, namely a magnetic field, is achieved that a suitable discharge can be compared with can achieve lower terminal voltage is illustrated in Fig. 3 schematically. at Embodiments of this type can, in particular, also include comparatively high gas pressures, about tenths of a mm Hg and higher are used in the pipe, those for low Prints characteristic independent contraction of the place of origin of the cathode rays would no longer occur.

In the exemplary embodiment, the parts of the outer cathode are designed as poles at the same time, which essentially determine the magnetic field at the location of the discharge. The embodiment is essentially Sharing rotationally symmetrical; the drawing m.s represents a section through the imaging axis of these parts.

AK, AK are hollow cylinders made of soft iron, which are separated from one another by an annular gap 55. In the middle plane they are surrounded by a conductive ring AA , which serves as an anode. AK, AK -were made to the poles of a magnetic field in some way. Between them, as shown in Fig. 6, again especially ₅ , that is, magnetic lines of force run through the gap 55 and across in front of it. The discharge that occurs when a voltage of a few hundred volts is applied is largely or entirely restricted to the equatorial plane. Outwardly it is usually identified by a luminous ring,

which concentrically surrounds i'i 'or, under certain conditions, penetrates into 6 ", S". The designated purpose of concentrating the discharge in front of the influencing parts is achieved particularly extensively by means of the magnetic field. Your channel beams, for example, which are capable of releasing electrons when they hit solid bodies, will largely fly out of the discharge in the radial direction ίο towards the cathode, i.e. into gap 55 (arrows). If a part (here C) is attached to the inside of 5 "S, on which electrons are generated and in the vicinity of which a controllable electric or electromagnetic field can be generated, then again with the help of this field a powerful influence on the external discharge can be exerted, In the exemplary embodiment, AK itself serves to create an electric field, in that the walls of the gap 56 ″ are brought into the vicinity of the surface of C , so that a potential difference between AK and C creates a field at the point of origin which creates electrons.

In this type of embodiment, too, as in the case illustrated in Fig. 2, the field can be generated with the help of special parts which are protected from the electron-generating effect of the discharge. For this purpose, the innermost part of 5 "ν9 is again isolated from AK and widened somewhat. The most important parts of such an embodiment are shown in Fig. 4. AK ', AK' in turn denote the protected field electrode.

In the exemplary embodiment in FIG. 3, C is designed as a cylinder which is held by an insulating intermediate layer at a point that is more outwardly located, for example in the area T, T of the outer cathodes AK, AK \. In order to keep the capacitance of C to AK as low as possible, what are used for amplifiers and the like purposes '. can be of importance, expedient! Supports the smallest possible expansion ^! turns; approximately three pins each in the planes T and T guided through the outer electrodes at equal angular intervals. The latter embodiment allows at the same time, if the pins are provided with a thread, a careful centering of C _{1 in} that the screw heads expediently remain accessible from the outside. It can be useful; be to let wear existing carrier, then j to the parts of the cathode with certainty to fix against one another, suitably arranged on each side of AK, two such groups of three supporting ^pins: the total cathode of an entirely of glass.

The shape of C and the fixing of the parts to one another can, however, also be selected in any other way.

It may be useful to have the outer cathode in the vicinity of 55 from other Material as iron, especially to be made from non-magnetic material, too to cover only their surface with such material, and also the walls of 55 made of such material. In Fig. 3 its expansion is strong solid lines indicated.

The field electrode opposite C is expediently further inward than the inner edge of the cylinders AK, AK. It can thereby be achieved that where the electric field, generally the auxiliary field, has to decide on the movement of the electrons, the magnetic field intended to influence the main discharge is already comparatively weak. In general, even if no special auxiliary electrode AK ' is used, an excessive amount of the magnetic field at this point must be avoided, so that the electrons that are created here at the back are not completely thrown back by the magnetic field and are prevented from leaving their area of origin at all, which means the possibility of influencing the discharge with them is naturally cut off. The arrangement of the protected auxiliary electrode shown in Fig. 4 corresponds to this consideration, while the same is achieved in the form shown in Fig. 3 in that the inner walls of 55 extend over the inner edge of AK, AK .

The magnetic field can be generated in any way, in particular also by using a permanent magnet. A special auxiliary battery, which is always required with glow electrode tubes, can be saved. The source of the magnetic field can be inside or outside the discharge tube. It can either attack the soft iron pole pieces AK, AK or the parts corresponding to AK, AK can themselves be made of permanent magnetic material. nu

A magnet acting from outside the discharge tube is expediently arranged in such a way that that the discharge tube by simply inserting it into a socket that holds the supply lines mediated, between the poles the pole pieces' of the magnet comes, so that when changing tubes the correct one Sitting in the socket at the same time guarantees the correct position in relation to the magnetic field. Furthermore, the magnet is placed in such a way that that it does not need to be moved when changing the tubes, but rather

867438

which the tube can easily perform the movements necessary for removal from and for insertion into the socket. It is advisable to be able to regulate the magnetic field as finely as desired during operation. This is expediently done by means of a magnetic shunt that is finely adjustable. In Fig. 5 an embodiment of a permanent magnet acting outside the pipe is illustrated. N, S are the legs of the magnet, Qa a transverse bar made of magnetic material, one end of which rests on one of the magnet legs and the other can be brought closer to the other magnet leg in a manner that can be regulated by the screw R. R is expediently made of non-magnetic material. The position of the pipe in front of or behind the plane of the drawing is indicated by dotted details of the main parts. F is his version.

The dependence of the characteristic quantities of the discharge, especially the Amperage from the auxiliary field is a constant one with a suitable arrangement and setting, in such a way that that the slightest field changes already cause changes in the discharge current. Furthermore, it is easy to reach that the dependence is linear. The one when a potential difference is maintained A current of a few volts between the field electrodes can also flow when the outer cathode itself acts as the one field electrode, in relation to the Main stream will be vanishing. In a randomly selected case, this amounts to Ratio 1: iooo, 'this order of magnitude is always readily achievable, but even higher can be achieved at will.

These conditions make it possible to supply small amounts of electricity cause significant changes in the discharge, in particular the current strength.

Embodiments in which it is ensured in the manner just described or in some other way that continuous currents can be achieved with comparatively low voltages can expediently be used as amplifier tubes, rectifier tubes, detector tubes or generator tubes. In principle, of course, any suitable arrangement according to the concept of the invention is capable of this type of use, even if it operates with higher voltages. The circuits to be complied with can be the same as those developed for glow electrode tubes, in that the outer cathode is expediently used instead of the glow cathode. If no further intermediate electrode - for example a field electrode protected from duct radiation, such as AK ' in the exemplary embodiments illustrated in Figs. 2 and 4 - is provided, the central cathode takes the place of the intermediate electrode (mesh, grid, sieve) of the hot cathode tubes in the circuit . If there is a special auxiliary electrode, this or, depending on the circumstances, also the central cathode can take the place of the intermediate electrode of the circuit. If the special auxiliary electrode is used in this way, it can also be designed inside the tube in such a way that the electron-supplying point is metallically connected to the outer cathode. If necessary, these parts can then be constructed as a mechanically coherent metal body.

For example, if a pipe is to be used for reinforcement without a special intermediate electrode, the given fluctuating current is expediently fed to C and AK , whereupon the main current of the discharge flowing through A and AK fluctuates to a greater extent with a suitable choice of gas pressure and state of discharge. The device which reduces the fluctuations, for example a telephone if necessary, is expediently located in the feed line to the anode. The current to be amplified can be introduced with the aid of a transformer and the increased fluctuation can be removed with the aid of a transformer; however, circuits in which one or both transformers are avoided can be very useful. In amplifier Like circuits, it can be useful, for example to increase the sensitivity or to avoid background noise, to be able to apply a constant auxiliary field of controllable size xoo at the location of the action on the electrons. The potential difference required for this, for which amounts of the order of magnitude of half a volt have usually resulted up to now, are expediently branched off from the battery itself, which is used as a power source.

A simpler case is shown again to explain the circuit and function (Fig. 7). The battery causes an independent discharge between A and AK , the negative glowing light of which is indicated by the dashed lines in front of the cathode AK. The channel jets produced here flying at AK and because AK granted to them for the most part passage, C. on the lying behind rear cathode Here slow electrons are 'therefore cleared (indicated by small arrows), the dominant depending on the direction and size of the front C Field in turn exit through AK and bring the discharge between AK and A to a stronger development or to C-

are thrown back and remain ineffective for the main discharge. The current to be amplified is at a, b the transfer; mator I supplied, the secondary coil between ', see C and AK is. Any stream swan | The change in a, b thus causes a potential fluctuation between C and AK and thus an increased current fluctuation between A and AK ; or in the circle of B. This current fluctuation acts on the listening telephone T via the transformer II located in the circle of B. In general, as mentioned, a constant auxiliary field is expediently maintained between C and AK. The figure shows the case already mentioned, in which C is not connected to AK directly, but via a more positive point on the main battery.

AK can also be designed as a hot cathode.

The advantages of the arrangements according to the concept of the invention are initially in the already mentioned possibility, the auxiliary sbatterie always necessary for heating with hot cathodes to be omitted and the resulting simplification, which is particularly important in the case of transportable arrangements falls. Among other things, the elimination of the glowing electrode is an advantage in itself. Of the particular advantages that they have in amplifier and the like stated that, as already mentioned, they work very advantageously without transformers capacity, which in turn is important for the simplicity of the arrangement. Also can a very clear and uncolored reproduction can be achieved. Besides this and others it has mainly working arrangements with a constant electron source, such as a hot cathode the fundamental peculiarity, based in the nature of the method, that the intensity of the discharge has an effect on the productivity the electron source acts back. While in the case of pure electron tubes, for example, the change in the current intensity caused by the Admission of a certain number of electrons is effected, never beyond that of this directly can go beyond the amount of electricity transported, the increase in the discharge intensity can in turn be that of increase the total electron production dependent on the discharge by roughly the number of the canal rays arising from the discharge increases, and analogously one can A reduction in the number of electrons allowed means a reduction in the overall generation of electrons to draw on. Thus a multiple back and forth effect appears solely through the essence of what is used Process possible. Accordingly, with the corresponding to the inventive idea Arrangements z. B. achieve very strong reinforcements.

Claims (26)

Patent Claims: _g i. Discharge tube for electrical vacuum discharges, in particular for Generation, rectification, amplification and detection of electrical vibrations, Alternating currents and current fluctuations, characterized in that ions or electrons emitted by the discharge can even be generated in an adjoining room, in whole or in part by an electrical or magnetic auxiliary field are influenced in such a way that ions or electrons from the adjoining space are more variable Number to enter the main discharge (actual discharge). 2. Discharge tube according to claim r, characterized in that the used The discharge is completely independent in that it does not use any ion sources that are foreign to the discharge. 3. Discharge tube according to claim 1 and 2, characterized in that as the ions to be influenced those released at or in the vicinity of the cathode, in particular those caused by the channel rays the discharge generated electrons are used. 4. Discharge tube according to claim 1 to 3, characterized in that the to influencing auxiliary field detects the electrons immediately after their formation, by extending to the area where the electrons are created. 5. Discharge tube according to claim 1 to 4, characterized in that the Ions generated by the discharge itself are admitted into the cathode dark space of the discharge in a controllable manner will. 6. Discharge tube according to claim 1 to 5, characterized in that the with certain constructive implementation the cathode environment under low pressures automatically occurring concentration the channel rays and the starting point of the cathode rays in an area near the cathode serves to produce all or a substantial part of the cathode rays at the location or in the vicinity of the auxiliary field permit. 7. Discharge tube according to claim 1 to 6, characterized in that the auxiliary electrical field between parts in terms of potential differences are to be regarded as parts of the cathode in the discharge. 8. Discharge tube according to claim ι to 7, characterized by 'a magnetic field for crowding the place of origin of the electrons onto the place of the auxiliary field. - 9. Discharge tube according to claim 1 to 8, characterized in that when generating the auxiliary electrical field an electrode is used, which is before the electron-releasing effect of the discharge, in particular before the impact of the canal rays to a large extent, possibly through the shielding effect of others fixed parts, is protected. 10. Discharge tube according to claim 1 to 9, characterized in that the mainly electron-donating parts from which the electrons enter the auxiliary field get, or their surface made of electropositive material or electropositive Material than the other surfaces located on and in the vicinity of the cathode and the auxiliary field are. 11. Discharge tube according to claim 1 to 10, characterized in that those parts which the magnetic field essentially determine at the location of the discharge, are mounted inside the discharge tube. 12. Discharge tube according to claim 1 to 11, characterized in that those Parts that essentially make up the magnetic field at the point of discharge determine, at the same time serve as parts of the cathode. 13. Discharge tube according to claim 1 to 12, characterized in that the Cathode or all metal parts that determine the discharge are rotationally symmetrical are executed. 14. Discharge tube according to claim 1 to 13, characterized in that in the part of the magnetic field which determines the discharge, the lines of force of the imaging axis the cathode are parallel. 15. Discharge tube according to claim 1 to 14, characterized in that the Outer cathode consisting entirely or in part of iron with another, in particular non-magnetic metal is covered, especially in the vicinity of the place where the canal rays enter or that also the walls of a channel leading to the place of origin of the electrons, Gap or the like. Made of such a material or covered with it. 16. Discharge tube according to claim 1 to 15, characterized in that the location of the auxiliary field from the immediate Moved away near the pole pieces, which determine the magnetic field controlling the discharge. 17. Discharge tube according to claim 1 to 16, characterized in that the insulating parts, which fix the field electrodes against each other, of as little as possible Extension are chosen. 18. Discharge tube according to claim 1 to 17, characterized in that for A permanent magnet is used to generate the magnetic field. 19. Discharge tube according to claim 1 to 18, characterized in that the the magnetic field generating device is arranged outside the tube. 20. Discharge tube according to claim 1 to 19, characterized in that the the shape of the magnetic field inside the pipe directly determining parts of perhiament magnetic material are made. 21. Discharge tube according to claim 1 to 20, characterized in that the acting from outside the tube The field magnet leaves the tube free for the mobility that is used for replacement. 22. Discharge tube according to claim 1 to 21, characterized in that the mutual position of the pipe version and outer magnetic poles is chosen so that the pipe by inserting into the Socket that mediates the leads, at the same time with the pole pieces between the pole pieces of the magnet. 23. Discharge tube according to claim 1 to 22, characterized in that a finely adjustable magnetic field is used. 24. Discharge tube according to claim 1 to 23, characterized in that the The magnetic field is regulated by a magnetic shunt. 25. Circuit for the discharge tube according to claim 1 to 24, characterized in that that the voltage necessary to generate an auxiliary electrical field is branched off from the battery serving as a power source. 26. Application of features 1 to 25 to tubes with strong training and special utilization of cathode rays, such as X-ray tubes, Braun tubes, for the purpose of a variable To achieve hardness or intensity. For this purpose ι sheet of drawings.