DE1541397A1 - Frequency tuning device - Google Patents

Description

Frequency tuning device. The present invention relates to a frequency tuning device consisting of a plurality of tuning elements, in particular on a frequency tuning device, in which the individual tuning elements from the "slug" - or "plunger" type.

One purpose of the present invention is to design a frequency tuning device which is composed of individual tuning elements and which can be manufactured mechanically easily and economically.

The invention is also aimed at a tuning device of The type described above provide simple automatic means to provide the AlD deviations with the tuning pistons which slide back and forth in the tubular waveguide sleeve, balance.

Another object of the invention is to provide suitable support elements provided for the main drive shaft of a tuning device so that the drive shaft is free of dead threads.

Furthermore, the invention proposes improved means for the rotation stop the main drive shaft in the extreme position of the desired range, to prevent damage to the rotating mechanism.

Furthermore, the invention shows a tuning device in which the The tolerance of the resonance frequency of each individual tuning element is extremely low lies. Furthermore, the invention describes a frequency tuning device with which With the help of the main drive shaft, the frequency is steadily dependent on the angle of rotation can be monitored e.g. by the fact that the frequency is linearly dependent on the angle of rotation.

Furthermore, it is achieved by the invention that the voting device has desired electrical properties: z-.B. the resonance frequency is linear depending on the angle of rotation of the main drive shaft, the value of the inductance is related to the capacity of each capacity Inductance range constant at all resonance frequencies. The invention also describes a tuning device with reduced microphone currents, as they occur as a result of vibrations during the Operation occur.

The frequency tuning device also has simple tuning elements, to set the desired capacitance or inductance.

The present invention also describes an improved inductance tuning element, used in the above frequency tuning apparatus.

Furthermore, a tuning device is achieved by the invention, which has a considerably smaller size than commonly used plate capacitors with air dielectric.

Around. The invention proposes to achieve all of the advantages mentioned a frequency tuning device vorg consisting of a closed cylindrical Housing with a specially selected cross-section, with a longitudinal axis, a Front and rear wall and between the front and rear wall one in the housing rigid arranged partition.

The tuning device according to the invention also includes a number longitudinally arranged reactance tubes attached to the Partition wall on their Are attached to the rear. Some or all of the tubes can have a capacitive effect. They consist of a dielectric material that is coated on both sides with an electrical conductive covering is covered. Some or all of the tubes can be inductive, They consist of an insulating material that has coil turns on the inside is covered.

A further embodiment of the invention consists in the fact that a drive shaft is arranged in the axial direction, which is mounted in brackets in the partition wall and front wall and protrudes through them. A rotary knob is attached to the end of the drive shaft that protrudes from the front wall. Furthermore, a vertical, non-rotatable plate which is displaceable in the social direction is arranged between the partition wall and the front wall. This plate is coupled to the drive shaft and moves in the axial direction in accordance with the rotations of the drive shaft. - Rigid wires are attached to the plate. These protrude backwards from this. Each individual wire is adjustable for the purpose of tuning. The wires protrude into the tubes and are suitably flexible and elastic in the transaversal direction. A piston-shaped attachment piece. is attached to the end of each wire. If the tube works like a capacitor, the attachment piece is designed as an electrically conductive hollow piston. If the tube acts like an inductance, the extension piece is in the form of a flat disc, which is in sliding contact with the coil windings arranged on the inside. The electrically conductive coatings and coil windings are designed so that the capacitance or inductance of the individual reactance elements can be changed in the desired manner by means of the ial movements of the bulb-shaped attachments. The various reactance signals can be contacted with external electrical circuits in such a way that the desired reactance is established in each case.

The essential characteristic of the present invention is that the wires can be somewhat flexible, so that deviations of the wires or of the general structure with regard to the right arrangement in relation to the tubes during the axial displacement of the plate are compensated for. This achieves the desired tight installation of the piston-shaped anaate piece in the tube. Furthermore, a reduction in the air space is achieved, the microphone currents are weakened and at the same time the need to manufacture the parts which the flask-shaped attachments extremely precisely is reduced. It is extremely important to use the described type, dead threads on the drive shaft to avoid. Even with other devices , the Prevention of dead threads can be important. An advantageous embodiment of the invention consists in that the drive shaft has threads with a rectangular cross-section and an outer circumferential surface .. A drive flange is attached to the plate, which carries the wires with the piston-shaped extensions. Another splash is attached to the adjusting shaft. These puddles are longer than the width of the thread groove.

The paddles and not rotatable with each other by springs or the like tied together. The springs urge the pool in the opposite direction. Holding devices are attached to the flanges. These protrude into the threads and are located in them sliding on. The spring forces cause the holding device to engage with friction the threads. This avoids that the drive shaft with respect to of the drive flange has dead threads.

Further features and advantages of the invention are shown in the figures illustrated using exemplary embodiments of the invention.

FIG. 1 shows, in a perspective view, a tuning device according to the invention.

Figure 2 shows a tuning device without the enclosing housing walls.

FIG. 3 shows a section along the line 3-3 in FIG. 1. FIG. 4 shows a section along the line 4-4 in FIG. 3. FIG. 5 shows a section along the line 5-5 in FIG. 3. FIG. 6 shows a section along the line 6-6 in FIG. 3. FIG. 7 shows, on an enlarged scale, a capacitively acting tuning element.

Figure 8 shows the drive shaft device.

FIG. 9 shows the section along the line 9-9 in FIG. 8. FIG. 10 shows the view at the level of the line 10-10 in FIG .

FIG. 11 shows a special embodiment of the invention. The figures show in detail the elongated housing 10 with the side walls 11. The housing has a triangular cross-section with rounded corners. Of course, other housing shapes are also conceivable. The housing 10 can be made of metal or another material a rear wall 15 ( Fig. 3). This can be formed in one piece with the side walls 11. The housing has a front closing wall 14 which rests on the front edges of the side walls 11. This has a recessed circumferential wall on the Ihicksdite Edge 14 a. On which the side walls 11 rest. The front wall 14 is tightly fastened by suitable means to the side walls 11. The interior of the housing is protected against external influences, for example dust.

The balancing device also has a partition wall 179 which is arranged within the side walls 11 between the walls 14 and 15 .

The partition 17 has an opening 17 a in the middle. The rear part 17 b of the same has an enlarged diameter. A hollow cylindrical body 18 extending in the axial direction is arranged in the space 20 between the partition 17 and the rear wall 15 . This body 18 is inserted into the opening part 17 b and is located on the edge between the opening parts 17 a and 17 b . The body 18 has a strong rear wall 18 a. Together with the body 18 , a number of reactance tubes 30 and 31 are arranged in the space 20. Nine tubes are drawn in the figures; this number can of course be changed. Either only designated 30 or only 31 designated tubes are used. The figure shows eight tubes 30 and one tube 31 ..

Each of the tubes 30 and 31 are made of a suitable dielectric material such as glass. Of course, the tube 31, which forms part of an inductance, can also consist of any desired insulating material. The front part of each tube 30 and 31 is inserted into a suitable opening 22 in the partition wall 17 (FIG. 3). The tube 30 or 31 is held within the opening 22 by a retaining ring which protrudes into a circumferential recess in the partition wall 17. In other words, the bracket by means of which the tube is attached lies within the partition. Each tube 30 and 31 extends rearward away from the partition wall 17 until just before the rear wall 15.

Each Induktivitätsröhre 31 has in the interior a metallic coil 32. The successive turns of the coil 32 are in recesses 32 a of the tube wall, approximately half of the coil wire diameter, embedded. The degree of offset of the individual turns is selected according to the desired inductance curve of the device. The figure shows the increasing distance between successive coil turns. At the rear of the tube 31 , a conductive layer 23 is applied to the inner wall, which is in contact with the end turn 32. The layer 23 covers the entire rear end of the tube; a layer 23 a is also applied all around on the outside of the tube.

Each tube 30 has an inner glass tube 35 on which a conductive layer 36 is applied. The tube 35 and the layer 36 are directly enveloped by a further tubular layer 25, for example made of glass. The layer 36 is designed in accordance with the desired capacitance curve. According to FIG. 3 , the layer 36 is shaped in such a way that the radial extent of the layer is varied. It has the smallest extent in the vicinity of the partition wall 17, cLie Ausle # Gaung grows backwards until the Senicht covers the tube all around. Behind this point, the layer 36 is contacted with a conductive tape 38. This tape has a cylindrical shape and is disposed between layers 35 and 25 at the rear end of tube 30. At the rear of the tube, layer 38 also extends outwardly. It lies all around on the outside of the Schiclit 25 and forms a cylindrical outer band 38 b. The rear jihde of each tube 30 and 31 is closed by a metal cap 26 . This is in electrical contact with the outer cylindrical bands 38 b and 23 a. The cap 26 is attached to the outer cylindrical band 38 b or 23 a by contact means 2. Between the layers 38 and 23 and the inside of the cap 26 there is an insulating disk 3 which prevents an electrical short circuit between the piston 96 or the disk 97 and the cap 26. On the outside, the cap 26 has a connection element 40 which is connected to the metallic lead-through element 42 via a wire 41. The metallic lead-through element 42 is fastened in an opening 43 of the rear wall 15 by means of a seal 44. The lead-through element 42 is contacted in the desired manner in the circuit arrangement.

According to the invention, an axially arranged drive shaft 50 and brackets are provided therefor. In the middle of the wall 18 a there is an opening 18 c. The front part of the opening p is denoted by 18 b. has an enlarged diameter. A ball bearing 51 is in the voltage half Öff- 18 b secured. The ball bearing has an outer race 51 a and an inner race 51 b, which is attached to the rear end 50 a of the shaft 50. Suitable balls 52 are mounted between the races.

Further mountings and seals are located in the front wall 14. In the middle of the wall 14, a cylindrical extension 16 is built on. Approach 16 and wall 14 have a through hole 16 a. The rear end 16 b of the bore 16 a has an enlarged diameter .. A ball bearing 53 is mounted in the bore part 16 b .. The ball bearing has an outer race 53 a and an inner race 53 b which is attached to the shaft piece 50 b. Between the races, the balls 54 are the drives shaft part 50c protrudes nachArorne from the ball bearing 53 and extends out through the bore 16 a. The shaft portion 50 c has circumferential grooves, which are mounted in ringfö7T * I.ge seals 58th

The shaft part 50 d is located at the front of the shaft piece 50 c. A rotary knob 60 is fastened to the drive shaft part 50 d with the aid of a screw 61. The rear part of the rotary knob 60 is a cylindrical flange 60 a formed has a number of annular discs (3 and 5) are rotatably supported on the shoulder 16 [and rotate together with the Plansch 60 a. Each disc 63 has an approximately semi-circular opening 64, the ends of which form an angle of 2700 in FIG. 5 Longitudinally disposed Stud 65 5 are arranged respectively at the front of each disk 63 secured .. Two such pins 65 are shown in FIG offset by 600 from each other.

The Bolz.en each disc 65 extend forwardly from the discs 63 out, as shown in FIG. 3 The bolts 65 of the front disk 63 protrude into the groove 66 on the rear side of the rotary knob 60 and correspond to the semicircular slots 64. Likewise, bolts 67 on the front of the wall 14 protrude into the slots 64 of the rear disk 63.

The relative rotation of one disk to another is limited. This will then. achieved when the corresponding bolt 65 strikes the matching end of the semicircular slot 64.- In Figure 3 , six washers 63 are shown, with a slight change in one or more semicircular slots 64 or the groove 66, or with a slight change in the space of one or several pairs of bolts 65 or 67 , the entire range of rotation of the knob.60 1 440 0 or four revolutions. This range of rotation proves to be advantageous, but the invention is not restricted to it. In any case, the range of rotation of the shaft 50 is restricted by a secure holding mechanism. The number of disks and the extent of the semicircular slots can be varied in such a way as to achieve the desired range of rotation of the shaft 50 .

Furthermore, in connection with the invention, the plate 70 is arranged within the housing between the partition wall 17 and the front wall 14. It can be displaced in the axial direction and cannot be rotated. In order to hold the plate 70 , rods 71 are attached between the wall 14 and the partition wall 17. Each rod protrudes with one end 71 b which is provided with a thread into a threaded hole in the wall 14. The other end 71 b has a reduced diameter and a thread at the outermost end. It is inserted through an opening in the wall 17 and fastened with a screw 72 . this attached. The rods 71 not only serve as guides for the plate 70, but they hold the partition 17 in the right place.

The rods 71 protrude through the openings 74 in the plate 70 and are slidably supported in sleeves 73 . This ensures that the plate 70 can be displaced in the axial direction.

In connection with the invention, devices are advantageously provided in order to fasten the shaft 50 to the plate 70. Details are shown in Figures 89 9 and 10. FIG. The drive shaft 50 has a deep and wide thread 75 which has a rectangular cross section perpendicular to the axis of the shaft 50. The thread 75 extends from the shaft part 50 b to the shaft part 50 a. The plate 70 has a threaded hole 76 in the middle. A collar-shaped extension piece 77 is fastened with its threaded piece 77a having a reduced diameter in the threaded hole 76 on the rear side of the plate 70. The Aneatzstück 77 has a bore 77 b through which the shaft 50 protrudes with its outer periphery 75 a abliegendv.

Another extension piece 78 is arranged behind the collar-shaped extension piece 77 coaxially therewith.

It has a bore 78 a in which the shaft 50 is rotatably mounted. The extension pieces 77 and 78 are installed separately from one another in the axial direction. The two extension pieces 77 and 78 are non-rotatably connected to one another by resilient elements, the two extension pieces being pushed in opposite directions. The resilient elements can have the shape of a Metallischem.Bla, sebalg, through the cavity 79 a of which the shaft 75 a protrudes. The ends of the bellows are attached to the extension pieces 77 and 78 by suitable means. The bellows 79 is expandable so that the extension pieces 77 and 78 can be pushed apart. A suitable torque of the bellows prevents the two extension pieces 77 and 78 from rotating relative to one another.

The extension pieces 77 and 78 have parallel holes. A bolt 81 is inserted into each bore 80 and secured therein by suitable means. The inner ground of each bolt 81 is conical at the point 81 a and is fastened in the inner race 82 a of a ball bearing 82. The ball bearing 82 consists of an outer ring 82 b, the inner ring and the balls 83. Each ball bearing rests on the thread 75 . In addition, the extension pieces 77 and 78 have bores 80 b arranged diametrically to the bores 80.

The diameter of the outer ring 82 b is somewhat smaller than the width of the threaded groove 75. As is illustrated in FIG. 8 , the springs 79 press the rings 82 b from opposite sides against the thread. As soon as the shaft 50 rotates, the ball bearings rotate with it. The ring 82 b moves on in the threaded groove 75 and transports the extension piece 77 in the direction corresponding to the rotation of the shaft 50. The plate 70 moves in front of or around the collar-shaped end piece 77 is located backward in accordance with a result of the arrangement of a second lug 78 and the spring elements 79 of the ring 82 b so amGewinde 75 indicates that a dead thread is avoided with certainty. Rotation of the shaft 50 is immediately and accurately transmitted to the extension 77. Because of the ball bearings, an easy transmission of movement is guaranteed. The use of a rolling element is superior to the usual embodiment in which a rigid hump protrudes into the thread. Another advantage of the storage mechanism according to the invention is its long service life.

In FIG. 11 , only one extension piece 177 is shown which corresponds to the extension piece 77. Since the one corresponding to the extension piece 78 has the same shape, this is not shown. The extension piece 177 has a bore 180 which has a reduced diameter at the inner end 180 a. 182 A pair of inner and outer ball bearings 192 are coaxial stored in the bore 180 .. The ball bearing 182 rests on the paragraph which is formed by the bores 180 and 180 a. The ball bearing 182 has an outer ring 182 b1 which is fastened within the bore 180 , as well as an inner ring 182 a and balls 183 in between. In the same way, the outer ball bearing 192 consists of an outer ring 192 b, balls 193 and an inner ring 192 a.

#The rings 192 a and 182 a are attached to the shaft 181 . The inner half 181 a of the shaft 181 has an enlarged diameter which protrudes through the bore 180 a into the thread 75 of the shaft 50.

Of l "igur 11 corresponds to the movement mechanism the bearing radial elements shown in Figures 8-10. In each case transmitted rotatable about its own axis of rotation of the shaft 50 on the attachment piece. By spring forces, the radial members against the thread 75 to be pressed.

The plate 70 has a number of openings 90 ( FIG. 3) which are arranged according to the position of the tubes 30 and 31 . A socket gl, which has an internal thread, is inserted into each opening u, 0 and rp-gt backwards out of the plate 70 . A screw 92 with a slot 92 a is screwed into each socket 91. The wall 14 also has threaded bores 92 bg which are arranged corresponding to the screws 92. Each screw 92 c can be removed so that the slot 92 a of the screw 92 is accessible for adjustment purposes. As soon as the adjustment process has ended, the screw 92c can be screwed in again as a closure element. Wires 93 , which are longitudinally displaceable in the tubes 30, are fastened to the screws 92. Corresponding wires, which are also stored in screws, are arranged corresponding to the tubes 31 . The wires 93 and 94 are similar except in length and are so stable that they do not bend when the reactance elements are moved, as will be described in the following section. Furthermore, the wires 93 and 94 are so flexible that deviations during installation are compensated for, as will be shown in detail below.

Attached to each wire 93 is a hollow cylindrical piston 95 which is slidably disposed in the bore of the corresponding tube 30. As shown in FIG. 6 , the hollow cylindrical piston 95 has a longitudinal slot or incision 95 a over its entire length and consists of a resilient material. The piston 95 is compressed as soon as it is pushed into the tube 30. Due to its elasticity it lies close to the inner wall of the tube 30a "In the hollow cylindrical piston 95, a metallic separating plate 96 is arranged, which is fixed by soldering 96 a. The solder 96 a ends at points that are slightly removed from the incision 95 a so that the desired flexibility is retained. The wire 93 protrudes into the piston 95 and is fastened to the separating plate 96 in a suitable manner, for example by a rivet head 93 a or a weld.

The capacity depends on the shape of the lining 36 and the position of the hollow cylindrical piston 95 . Furthermore, the incision 95 a influences the steepness of the tuning curve. The shape of the lining 369 as shown in FIG. 3 makes it possible to vary the capacity properties of the arrangement by changing the position of the piston. The electrical properties are regulated as a function of the length of the piston 95 which lies opposite the lining 36.

The construction of the capacitance wall ( tube 30) makes it possible to produce a wall with a thickness of approximately 0.01 cm, with a thin layer with a large dielectric constant being arranged between the piston and the covering. This reduces the size of the tuning device compared to the conventional tuning devices with air dielectric. Each wire 94 is slightly longer than wire 93. The rear end of wire 94 protrudes into a circular wiper disk 97. The diameter of disk 97 is substantially equal to the diameter of the tube bore minus half the diameter of winding wire 32. As the disk moves longitudinally 97 this is guided by the winding wire and strokes along it. The wire 94 is designed to be correspondingly flexible.

The operation of the arrangement is clear from the above. When turning the knob 60, the plate is displaced longitudinally according to the direction of rotation of the knob 70th The reactance elements 95 and 97 change their position. This changes the reactance of each individual inductance element and capacitance element. As soon as there are any deviations in the arrangement or occur during operation and during the longitudinal displacement of the plate 70 , so that the tubes 30 and 31 change their position relative to the wires, the wires then bend slightly and compensate for this deviation. Therefore, the plate 70 and the elements attached to it need not be constructed too precisely. Each individual stimulating element can be adjusted by turning the screw 92 after the screw 92 has been removed.

Any desired electrical property can be set. According to the drawings, when the position of the plate 70 is changed, the inductance is changed in the opposite direction to the capacitance. With a suitable shape of the coil 32 and the occupancy 36 , it is possible to keep a constant amount between capacitance and inductance, in other words to obtain the resonance frequency as a linear function of the rotation of the drive shaft. The present invention is not limited only to the arrangement shown. It is also possible to use the invention only when changing the capacitance or only when changing the inductance or with other combinations of capacitance and inductance as shown in the figures. Further reactance elements in a similar or different geometric arrangement can be installed and controlled via the plate 70. In a special application, the inductance can be kept constant and the capacitance can be changed. In any event, an important consideration is that the rigid wires 93 and 94 adjustably attached to the plate 70 be used so that the movable reactance elements can be controlled. In this case, the need for a precise installation of the acting parts is to be eliminated and a closed seat of the piston 95 in the tube 30 to reduce microphone currents is to be achieved. The special arrangement of the wiper disk 97 and the coil 32 are also advantageous. They enable the inductance to be set precisely, with the electrical contact not being impaired. The aspects of the present invention can also be applied in controllable composite resistors.

The invention can be applied to any voting device with a different cross-sectional structure different arrangement of the tuning elements and different combination of capacitance and Inductance elements are applied. The capacitance and inductance elements can be protected in any way, e.g. in groups be protected according to the contact with the rest of the circuit.

The above is a preferred embodiment of the invention shown. In addition, other designs are possible, which are also in the area present er-ending.

Claims (2)

Claims. ##) Frequency tuning device consisting of several tuning elementsg a drive mechanism and a lock for the drive mechanismg characterized in that a drive shaft 50 extending in the axial direction is arrangedg that the drive shaft 50 is in rotatable bearings. 51 and 53 is supported that the drive shaft is equipped with a thread 75 , that two collar-shaped separate extension pieces 77 and 78 are arranged around the drive shaft, that a resilient device 79 the two collar-shaped extension pieces 77 and 78 relative to each other non-rotatable these in opposite directions Direction pushes together that ball bearings 82 protrude into the thread 75 and are attached to the extension pieces 77 and 78 and that the ball bearings 82 are pressed against the thread 75 by the force of the resilient device 79. 2. Frequency tuning device according to claim 1, characterized in that the ends 50 a and 50 b of the drive shaft 50 supported in rotatable bearings 51 and 53 an »that the drive shaft has a thread 75 , that two collar-shaped separate extensions 77 and 78 can be moved axially and not are rotatably arranged that the two extension pieces have bores that the drive shaft 50 is rotatably guided through these Bohrungen.hindurch that a resilient device 79, the two collar-shaped extension pieces 77 and 78 relative to each other non-rotatable and connects these pressing in opposite directions with each other and that Ball bearings 82, which protrude into the thread 75, are fastened to the extension pieces and the ball bearings 82 are pressed against the thread 75 by the force of the resilient device 79. 3. Frequency tuning device according to claim 1 and / or 2, characterized in that a rotary knob 60 is attached to the drive shaft 50 , that a wall 14 is arranged separately from the rotary knob 60 , which has an opening through which the drive shaft is inserted that a number of discs 63 are rotatably arranged around the drive shaft between the rotary knob 60 and the wall 14, that each disc has an approximately three-quarters of a circle- shaped slot 64 and bolts 65 offset from one another on a circle, which perpendicular absteher4, that the bolts 65 and the slot 64 on a circle are arranged so that the bolts 65 of a disk 63 protrude into the slot 64 of the adjacent disk, that the knob 60 has a groove 66 corresponding to the slot 64 and the wall 14 recesses with bolts 67 , that the bolts 67 in the slot of the adjacent disk and the bolts of the front disc protrude into the groove 66 of the rotating head and that the bolts L slide in the slots are stored. 4. Frequency tuning device according to one or more of claims 1-3 characterized in that the drive shaft 50 is rotatably supported in ball bearings 51 and 53 , that a rotary knob 6U is attached to the drive shaft 50 , that between the rotary knob 60 and the wall 14 a number of discs 63 are rotatably mounted about the drive shaft 50 , that each disk 63 has three-quarter circular slots 64, that perpendicularly staggered bolts 65 protrude from the disks on a circle. That the bolts 65 and the three-quarter circular slot 64 are arranged on the same circle, that the bolts 65 of a disk in the slots 64 of the adjacent disk ragei4 that the knob has a three-quarter circular groove 66 and from the wall 14 perpendicular bolts 67 protrude and that the bolts of the front disk in the groove 66 and the bolts 67 in the slots 64 of the adjacent disc protrude. 5. frequency tuning device according to one or more of claims 1-4 characterized in that the dnden 50 a and 50 50 b of the drive shaft in rotatable bearings 51 and 53 are supported so that the drive shaft 50 has a thread 75, that the drive shaft 50 through the Bores - the collar-shaped extension pieces 77 and 78 are rotatably inserted, that a bellows 79 connects the collar-shaped extension pieces 77 and 78 to one another so that they cannot rotate in opposite directions, and that ball bearings 8'2, which protrude into the thread 75 , are connected to the extension pieces 77 and 78 are attached and that the ball bearings 82 are pressed against the thread 75 by the spring force of the bellows 79. # 6. Frequency tuning device according to claim 5, characterized in that the collar-shaped extensions 77 and 78 have bores 80 into which a bolt 81 is inserted, that the bolt 81 protrudes into the thread 75 , that the inner race 82 a of a ball bearing 82 is attached to the bolt 81 , daj3 imi the inner race 82 a balls 83 and an outer race 82 b are arranged and that the outer race 82 b is pressed against the thread 75. 7. Frequency tuning device according to claim 5, characterized in that the collar-shaped extension pieces 77 and 78 have bores 180 and 180 a and that in the bore 180 coaxial ball bearings 182 and 192 with the outer races 182 b and 192 b are attached that to the inner races 182 a and 192 like a shaft 181 is fixed, and that this extends with its shaft portion 181a into the thread 75 and is pressed against it. 8. Frequency tuning device with inductively effective tuning elements according to one or more of claims 1-7 characterized in that an inductively effective tuning element 30 consists of an elongated tube 30 made of insulating material that a spiral recess 32 a is embossed in the inner wall of the tube, that an electrically conductive one Coil 32 is embedded in the recess p that a conductive rotary 94, to which an electrically conductive wiper disk 97 is attached, protrudes into the tube bore that the wiper disk 97 has such a diameter that it rests against the coil wire 32 and the inner wall under friction that the width the wiper disk 97 is less than the expansion in the axial direction of half a coil turn that the wire 94 is stiff but so flexible that the disk 97 is displaceable along the coil 32 protruding slightly from the recess 32 a. 9. Frequency tuning device with inductively effective tuning elements according to one or more of claims 1-8 characterizedp that the tuning element consists of an Isolierstoffröh're 30 habeng that a spiral recess 32 a extends in the inner wall that a coil 32 is embedded in the recess 32 a The coil wire protrudes somewhat from the recess, a conductive wire 94 slidably displaceable in the axial direction protrudes into the tube 30 , a disk 97 is attached to this wire, a partition 17 is provided in which the tube 30 is attached, that the wire 94 is attached to an axially displaceable plate 70 that the diameter of the disc 97 is dimensioned such that it rests under friction on the coil wire and on the inner wall of the tube, that the width of the disc 97 is less than the axial extent of one half Coil turns such that the wire 94 is stiff, but has such elasticity that it can displace axially the disc is possible.