DE2305041A1 - TROPICAL PIPE WITH CROSSED FIELDS - Google Patents

Description

PATENT LAWYERS 2 3 O 5 O A

DR.-PHJL. G. NICKEL ■ DR.-ING. J. DORNER

8 MONKS 15

LANDWEHRSTR. 35 POST BOX 104

TEL. (O81I) 55 5719

Munich, January 30, 1973 Attorney's files: 27 - Pat. 45

llaytheon Company, 141 Spring Street, Lexington, Massachusetts 02173, United States of America

Lauffeldröhre with crossed fields

The invention relates to running field tubes with crossed fields, in particular coaxial magnetrons and, in particular, a tuning device for such tubes.

From US Pat. No. 2,854,603 there is a coaxial magnetron with an internal resonance system comprising a number of spaced apart anode members supported on an anode wall has, which delimit resonance cavities between them, which surround a cathode, further with. an external resonance system, which has an outer wall which, together with said anode wall, delimits a coaxial resonance cavity, which can be excited to resonance in a certain frequency band is known.

The outer resonance cavity of coaxial magnetrons generally operates in an electric and magnetic vibrational state corresponding to a TE _Q .. circular wave. The electromagnetic energy is coupled out from alternating inner resonance cavities via slots in the common anode wall or partition wall to the outer resonance cavity.

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The internal resonance system generally works in the 7Γ state and the coupling slots are together with means for absorbing vibrational states due to the slot arrangement designed and dimensioned so that there is an effective coupling with respect to the desired oscillation states.

It is known to construct such tubes by means of an annular plate to tune, which is movable in the axial direction within the outer resonance cavity. So the voting body is formed effectively a movable end wall of the Hohlrauraresonators. If the tuning member is moved in the direction of the opposite end wall, the volume of the resonance cavity becomes changed. Tuning devices with such a movable ring plate and with devices for suppression of vibrational states due to the slot arrangement have been suggested elsewhere.

The relatively large mass of the known plate-like tuning organs prepares when performing quick tuning across the frequency band or fine tuning across one Part of the frequency band across difficulties. In addition, in systems in which a frequency movement through a rapid, quasi tremulating tuning movement of the tuning organ is required, auxiliary tuning equipment is required, for example in the form of vibrating tongues, such as those from the US patent 3,087,124 are known. One also has encircling Constructions suggested such as those of the US patent 3 379 925 can be found.

When considering the oscillation states in the coaxial resonance cavity, namely when examining the TE ^., - wave, is determine that the electrical currents are circumferential on or in the walls of the resonance cavity, while the magnetic fields in the transverse direction are parallel to the axis of the device are aligned. The difficulties with regard to the tuning movements due to their size and mass

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th preparatory Abs t imino rgane of the known tubes cause a Change of the distance between the upper and the lower end wall of the resonance cavity to a new orientation of the Field distributions of both the electrical and the magnetic " To achieve the field and thereby a change in the resonance frequency to create.

The invention is intended to solve the problem of improving the tuning devices and the Possibility for tremoling tuning or wobbles too create, with linear and reproducible tuning characteristics teristics should result. The masses of voting devices should be reduced in such a way that both fine-tuning and tremolating tuning are facilitated.

In solving this problem, the invention is based on a running field tube with crossed fields, with an internal resonance system, which a number of held on a common partition wall, at a distance 'from each other arranged anode members, the between them resonance cavities for generating Also limit hole frequency energy surrounding a cathode with an external resonance system, which has an outer wall, which together with said common partition wall a delimits coaxial resonance cavity, which can be excited to resonance in a certain frequency band and with devices for generating crossed electric and magnetic fields.

The above object is achieved according to the invention one to tune the resonance frequency of the resonance cavity by introducing an asymmetry in the geometry of the surrounding Walls in the area of maximum electric field strength Tuning device solved, which on a path transverse to the axis of the coaxial resonance cavity is movable.

The dimensions of the in TE ₍₎ . .-Vibrational state excited,

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coaxial resonance cavity are thus maximal near the area electric field strength changed.

In one embodiment, mechanical devices are used for generation a reciprocating movement of tuning members in the form of a split ring provided, of which at least an end is held. The deformation of the annular Tuning organ causes an asymmetry in the geometry of the resonance cavity, whereby the essentially round resonance cavity is effectively deformed in the state of maximum deflection becomes that a slightly elliptical shape comes into effect. The conductive tuning organs arranged within the resonance cavity change the path of electrical currents. In a practical embodiment, one is the outer resonance cavity surrounding, annular wall provided a groove or groove in which the tuning member is housed. the The depth of the groove limits the movement or deflection of the tuning element. After the stream no components in the transverse direction across the groove or groove containing the split ring tuners is not a deterioration to observe the electrical efficiency. With a Tuning device, which has a double-actuated, split ring, can have a tuning range in different frequency bands up to 200 MHz can be achieved. A multiplication of the tuning devices can double the tuning range enable. Practical tests also showed the linearity and reproducibility of the tuning characteristics over one considerable part of the tuning range. A coupling with a mechanism for tremolous tuning, for example with an eccentric drive and power transmission devices actuated by a high-speed motor a frequency movement when using corresponding tubes in transmission systems.

Appropriate refinements of the Lauffeldröhre proposed here otherwise form the subject of the attached claims.

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Some exemplary embodiments are explained in more detail below with reference to the drawing. They represent:

Figure 1 is a schematic, perspective sectional view of a coaxial magnetron with the features of the invention,

a front view of an inventive Magnetrons,

a side view of that shown in FIG Tube,

a diagram of a tuning characteristic of a running field tube according to the invention,

a sectional view corresponding to the plane 5-5 indicated in Figure 3 »

a sectional view corresponding to the in Figure 5 indicated sectional plane 6-6,

a sectional view corresponding to the sectional plane 7-7 indicated in FIG.

a vertical sectional view corresponding to the sectional plane 8-8 indicated in FIG. 3,

a side view corresponding to the viewing direction indicated in Figure 8 from the line 9-9 off,

FIG. 10 shows a side view of another embodiment of the actuating devices for the voting devices and

FIG. 11 shows a schematic partial illustration of another embodiment, drawn in section.

The coaxial magnetron 10 shown in Figures 2 and 3 contains an inner and an outer resonance system which are located within a housing 12. A mechanically operated one Tuning device 14 with a motor driven

figure 2 figure 3 figure figure 5 figure 6th figure 7th figure 8th figure 9

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Apparatus for actuating the tuning elements contains a gear housing 16 and a connection IB for reading the frequency. A cathode holder 20 protrudes coaxially from the housing 12, cooling fins or cooling fins 22 surround the housing 12 and an output waveguide flange 24 is also provided in order to couple the electromagnetic energy to a consumer. The devices 28 for generating the magnetic field contain essentially C-shaped permanent magnets 50 and j2, which bear against inner pole pieces, which cannot be seen in FIGS. The magnetic field is aligned parallel to the axis of the tube, while the electric field is perpendicular to it, so that there is an interaction area with crossed electric and magnetic fields in a space between the cathode and anode of the tube. The embodiment shown here contains a mechanical actuating device 34 for the tuning organs, a mechanical coupling device being provided to convert the movement that prevails on the drive 14 and in the gear housing 16 into a reciprocating movement for the actuation of the tuning organs.

The basic structure of running field tubes according to the invention is shown schematically in FIG. 1, to which reference should now be made. The inner resonance system 38 contains a cathode 40 which is held centrally within an arrangement of anode members 42 distributed around the periphery and projecting radially inward from a common partition wall 44. A plurality of resonant cavities 46 are formed between the anode members. By means of slots 48 a coupling is provided from every second resonance cavity of the inner resonance system to the outer coaxial resonance cavity 50, which is delimited by the common partition wall 44 and an outer cylindrical wall 52 with respect to the radial direction. The contactors in each case every second resonance cavity of the inner resonance system cause a decoupling of the oscillation energy of the inner resonance system, which is excited in the "jT" mode.

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speaking of a TE ... wave.

A plate 54 is axially displaceable within the outer resonance cavity 50 in order to be able to tune the magnetron over a wide frequency band. Mechanical actuators, for example stud bolts ^l } 6, are connected to a suitable drive via a yoke 5 &. A tuning element in the form of a split ring 60 is located within a groove 62 which is provided at a point near the center of the outer cylindrical wall 52 in an area in which the electric field strength has the greatest value ring-shaped tuning element 60 causes an introduction of conductor material into the resonance cavity and thereby a change in the path of the electrical currents, which, as already noted above with respect to the TE. wave, run in the circumferential direction along the wall 52 of the outer coaxial resonance cavity 50. The depth of the Groove 62 determines the deflection or the maximum path of movement of the tuning element. A rapid deformation of the cross-sectional shape of the outer wall of the resonance cavity in the area considered here causes a tremolous tuning over a considerable part of the frequency band, so that a frequency movement or wobble for use in corresponding systems is possible.

Figure h clearly shows that a linear tuning characteristic is achieved. The displacement or the movement path of the ring-shaped tuning element is plotted over a range from zero mm to 5.56 mm (θ to IkO mil). Corresponding to the measured points of the frequencies, a straight line 64 was drawn, which spans a frequency range of up to 80 MHz for devices operating in the X-band. In other versions of the i ', ri i nduriK, sicti also produced linear tuning characteristics over an area of up to 200 MHz in other frequency bands. lv.i rd a motor drive for wobble or tremulating tuning Vd ruoncJcit, which is described below and which is coupled with the voting organs admonished at η, whereby the rotary

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number up to 12000 rpm, so there are frequency movements over the entire tuning range with a frequency of 200 deflections per second.

Details of a practical embodiment of the type shown in Figures 2 and 3 are given below with reference

^ would be explained on FIGS. 5 to 9. The housing 12 is

completed by annular end walls 66 and 68 which adjoin the outer cylindrical wall 52 tightly. the

■ Anode members 42 are on the common partition or anode wall 44 and protrude radially inward from this, so that they have the previously mentioned resonance spaces between them 46 of the internal resonance system.

The cathode 40 is axially attached to the cylindrical cathode holder 20, which in turn is attached to an inner magnetic Pole piece 72 is attached and has a tubular extension 70. Electrical lines for feeding the cathode heater 74 as well as high-voltage lines are through the cathode holder 20 passed and connected to corresponding anode or cathode parts. The aforementioned magnet system 28 with the permanent magnets 30 and 32 lies on the inner one Pole piece 72 as well as pole piece connection pieces 76.

The external resonance system contains, as already mentioned, the coaxial resonance cavity 50, which by the common Partition wall or anode wall 44 and the outer cylindrical wall is delimited. Slots 48 in the anode wall 44 cause a Coupling and linking of energies between the inner and the outer resonance system. Energies according to so-called degenerate vibrational states are suppressed by an annular loss body 78 located within the end wall 66 is located. There is also an annular loss body 80 in the end wall 68 in the region of a throttle-like one Energy seal with an effective seal path of a quarter wavelength. The outer coaxial resonance cavity

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230504Ί 3

50 can be connected to a consumer via an iris 84 and a transformer section and via the flange 24 of an output waveguide arrangement. An evacuation port 86 in the cylindrical outer wall ? 2 and a mounting plate 88 and mounting screws 90 and 92 complete the external structure of the coaxial magnetron.

An axially displaceable ring plate 9k for broadband frequency tuning is actuated by means of a tuning mechanism 14 using a worm gear 96 via stud bolts 98, a deformable bellows arrangement 100 being provided between the tuning mechanism and a movable holder 102. In addition, near the ends of the slots 46, in a manner proposed elsewhere, an absorption device 104 for suppressing vibration states corresponding to the coupling slots can be displaced in the axial direction.

The tuning element in the form of a split ring 106 is located within a circumferential groove 108 which is provided in the cylindrical outer wall 52. In FIG close. The Abstimmbewegung mitmach Components that are shown in the left part of Figure 8 in the rest position, while they are in the illustration on the right side in a Abstimmstellung and are designated with the suffix "a ^M.

The tuning element 106 contains the parts 105 and 107 of a ring which are each firmly connected to the wall of the groove 108 at one end near the window or the connecting flange 24. The respective other ends 105 ^f and 107 are connected to an actuating mechanism 34 by way of reciprocating plates 110 which run through an opening 112 in the cylindrical outer wall 52 of the resonance cavity. Intermediate pieces 109 made of insulating material, for example made of a dielectric or

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made of ceramic, cause electrical insulation of the king parts from the actuation mechanism. In FIG. 5, the right-hand part shows the tuning element in a position completely within the groove IUb, with no disturbance of the electrical currents occurring in the walls of the resonance cavity. The left part of the Durste i Lung shows the tuning ring in the outermost tuning position in which it protrudes into the resonance cavity 50. As previously mentioned, the point of maximum electric field strength lies approximately in the middle of the cylindrical outer wall 52. The board designated by 10a in FIG. 5 has therefore assumed the inner limit position due to a corresponding movement of the actuating mechanism. After the parts of the protected iU.iges 106, which are held at one end, are deformed, they assume a slightly elliptical shape and therefore give the resonance cavity, which is essentially round in the central region, a corresponding cross-sectional shape. In a practical embodiment, the split tuning ring was made from metal, for example from an alloy with 10% tantalum and 90 % tungsten. A copper plating enables. Maintaining good electrical properties of the resonance cavity. Each of the parts of the tuning ring had a width of about 1.27 mm and a height of about 2.5 ^ mm for a tube operating in the X-band.

In housings 116, which are opposite each other at an angle of 180, there are damping devices 114 for the annular tuning elements, the damping devices 11 ^ each containing two rows of dielectric pins 118 attached to opposite sides of a tab or tab 120 are present. It can be seen from FIG. 6 that the dielectric pins 118 comprise the flag-like projections 120 and thereby dampen unwanted vibrations, so that there is good stability in a radial plane if a trinolating Vote or a wobble vote is carried out.

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The reciprocating boards 110 are operated via an operating mechanism moved with cam-actuated rocker arms 122, which will be discussed below in connection with FIG. Each of the rocker arms 122 is attached to a bearing journal 124 via a bearing ball arrangement 12b with attachment to a housing plate 128 stored. The reciprocating swiveling movements of the Rocker arms 122 cause lever arms 130 and 132, respectively Swivel movements around the journal 124. The lever arms Ij) O and J jj2 each carry actuating rollers 134 and 136, respectively. with which they are opposed to the actuating surfaces or bearing surfaces Components of the actuation mechanism are in contact.

A transmission device 13b each contains a sleeve 140, each of which carries a piston-like sliding piece 142 with a sole-litz-like recess 143 at its inner end, in the soft latter the respective board 110 to be moved back and forth is accommodated. The sleeves 140 are each provided with a screwed-in counter bearing 144, which can be adjusted so that that the desired stroke of the actuating device results. Line inner counter-bearing surface 146 lies on the respective Actuating roller 136 of the rocker arm 122. Slots 148 in the Sleeves 140 allow the rocker arms 132 to move freely. The sliding pieces or heads 142 are for example by means of Screws 150 attached to the inner end of the sleeves 140. A pederbe The load on the actuating devices is caused by the vacuum density Bellows arrangement 152, which on the one hand with the respective) Head or sliding piece 142 and on the other hand with a sleeve-like Insert 154 has a connection that is located within a housing 15 <> is located. Slots 157 in the hoop-like insert J 54 again allow the tilting arms to move freely 132.

i-.inc IJetat, igung of the ring-shaped tuning organ takes place through a vertical shock on his rocker arms IjO close to the end of a bearing adjacent to the tunnel 134 ^ Il.uj | i (i IGO. The opposite end of the plunger 15b

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rests on an eccentric l62 which is driven by a motor X6k . In FIG. 7, the right-hand part shows the rest position in which the hanging parts of the tuning element are located completely within the groove 10B. The plunger 15b is pushed downwards and the bellows arrangement 152 is compressed. The left-hand part of FIG. 7 shows the outermost tuning position, the plunger 15b being displaced upwards and the bellows arrangement 152 expanded so that the reciprocating plates 110 come into a position in which the tuning element protrudes into the circular cavity resonator. All movable construction parts of the group of interest here, which are in the outermost tuning position in the left part of the illustration, are provided with the addition "a" to make the mode of operation clear. In the practical, in conjunction with FIG k mentioned embodiment, the full tuning range has been mm by a stroke of about 3.3 for each tuning cycle swept, where the ring portions of the Abstimmorganes moving in the transverse direction with respect to the axis of the resonant cavity,

The top view according to FIG. 9 shows the tuning device Ik , which is driven by a motor, with the eccentric bearings 162 and 163, which sit on the shaft I66 of a motor 104. All of the last-mentioned components are fastened on a plate Lös. The worm gear 96 for driving the tuning plate 9k for broadband tuning is arranged below the plate 168, as shown in the illustration by dashed lines. The total stroke of the plunger 15B for carrying out a coordination over the entire range was about 2.3 in a practical exemplary embodiment that after completion of a tuning cycle, the eccentric part 163 located further inside detects the plunger. The arrangement is completed by a resolver 170 which is actuated by the motor shaft 166 and a

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immediate reading of the fine tuning frequencies via a a considerable part of the voting range. Resolver with immediate frequency readability are currently readily available commercially. In Figure 9 is the position of the plunger 158 is shown in dashed lines to indicate the position with respect to the eccentric parts 162 and 163 seated on the shaft 166 to make clear.

FIG. 10 shows another embodiment of the facilities for the movement of the Abstisnmorganes shown in the form of the divided ring and will be described below. A yoke assembly 172 includes scissor-like lever arms 174 and 176, which are connected to one another via a bearing pin 178. On a shaft 182 driven by a motor 184 are located Eccentric parts 180. The movement of the eccentric parts IbO leads to a reciprocating movement of at the outer ends of the low fog 174 and 176 attached lugs 186 and 188. The Pivoting movements of the scissors-like lever arms 174 and 176 lead to a back and forth movement of the lever arm ends I90 and 192 and thus to a corresponding movement of the piston-like Actuators 19 ** and 196, which, for example, by a Bellows arrangement, are spring-loaded in a suitable manner and are coupled to actuate the parts of the tuning element with these.

Still another embodiment of the invention is shown in FIG. Within a groove 202 of the wall 204 of the resonant cavity there is a first tuning ring 200 of certain dimensions. Another tuning ring 206 is also in the groove 202 housed. By enlarging the tuning ring 206, the tuning range can be doubled. With a practical Embodiment could therefore be realized in the desired frequency band a tuning range up to 400 MHz, which is special It is useful if wobble tuning is to be provided for systems that require a certain frequency movement.

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Another possible use of the voting instructions described here consists of automatic temperature compensation in an operating frequency band. Generally used different metals with different coefficients of thermal expansion are used to build resonance cavities a change in the resonance frequencies due to thermal To reduce energy absorption. Becomes a suitable liquid Filled into the bellows arrangement mentioned, a thermal influence on the quality of the resonance cavity can thereby be effective be compensated that the liquid expands or contracts in the bellows arrangement and thereby the tuning organs moves into or out of the resonance cavity. This movement causes in the already described Way the introduction of an asymmetry in the wall surfaces carrying the electrical currents and thus a change in the resonance frequency of the resonance cavity.

In addition to the described material composition of the split ring forming the tuning element, in the implementation Many other metals, for example molybdenum, can be used in the invention, which have high superheating temperatures able to absorb. In the context of the invention, this offers itself A person skilled in the art therefore has a large number of further developments and possible modifications of the barrel tube described.

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Claims (1)

Claims 1. 'Lauffeldröhre with crossed fields, with an internal resonance system, which has a number of anode members supported on a common partition wall, spaced apart from one another, which delimit resonance cavities between them for generating high-reflective energy, which surround a cathode, and also have an external resonance system, which is an outer wall which, together with the aforementioned common partition, delimits a coaxial resonance cavity, which can be excited to resonance in a certain frequency band and with devices for generating crossed electric and magnetic fields, characterized by a coaxial resonance frequency of the resonance cavity (50) by introducing an asymmetry in the geometry of the surrounding walls (hk, 52) in the area of maximum! ' Tuning device (I6 or 200, 20b) serving electrical field strength, which can be moved on a path transverse to the axis (this is a coaxial resonance cavity. ii. l.aui I e d 1 tube according to claim 1, characterized in that the U) stimineinrichtung T _e ile (105, 107) includes a divided Riniiiis (106) coupled to at least one of its ends fixed nclin I t en si Yid. '■) . A barrel tube according to claim 2, characterized in that di (. Kins.lfii Ic (lü'j, 107) by means of actuating devices acting on their free ends (lO5 ' _} 1 <»/'; are movable to and fro . Ί. l.au 1 fe Id reih re nnch claim 2 or 3, characterized in that Ί ..) 5 iJ ι c iiiiu '. part 1 u (l '> 5, 1 "7) towards an exit point 1- - 15 - 3 0 9 fn? / 0 9 9 2 are spring-loaded (e.g. 152). 5. Lauffeldröhre according to claim h and / or claim 3, characterized in that the ring parts (105, 107) are supported at a location between the fixed ends and the free ends by means of a stabilizing and vibration damping device (ll6, 118). 6. running field tube according to one of claims 1 to 5 »characterized in that there is an axially movable tuning member (9 ² O) in the coaxial resonance cavity (5O). 7. running field tube according to one of claims 1 to 6, characterized in that that the tuning device (106 or 200, 206) or the ring parts (105, 107) are in a groove (108 or 202) located, which with respect to the axial length approximately in the middle on the circumference of the outer wall (52) of the coaxial resonance cavity (50) is provided. 8. Lauffeldröhre according to claim 7, characterized in that the inner resonance system and the outer resonance system are connected to each other via coupling slots (48) in the common partition (kk) between the inner and outer resonance system. 9. Lauffeldtube according to one of claims 1 to 8, characterized in that that in the coaxial resonance cavity (50) an oscillation state corresponding to the TE wave is excited. 10. Lauffeldtube according to one of claims 3 to 9 and / the claim 2, characterized in that the ring parts (105, 107) are made of a substantially rigid, heat-resistant, metallic Conductor material exist. 11. Lauffeldtube according to claim 10, characterized in that the ring parts (105, 107) made of a tantalum-tungsten alloy are. - 10 - 309832/0992 12. Lauffeldtube according to claim 7, characterized in that in the circumference of (202) the outer wall of the outer resonance cavity several tuning devices (200, 206j are provided. 13. Run free? Tube according to one of claims 2 to 12, characterized in that the ring parts - (lOf>, 107) by moving the
free ends (105% 107 ¹ ) can each be moved in the circumferential direction by means of an actuating mechanism, which sliding pieces (140, 142, lhk) engaging on the ring dividing ends, onto these
acting rocker arm (.122) as well as this with an eccentric drive (162, 163, 164, 166) coupling plunger (15b) contains. - 17 - 309832/0992