DE832921C - Tunable oscillation circuit for very high frequencies - Google Patents

Description

Tunable oscillation circuit for very high frequencies The present Invention refers to oscillation circuits, dlie over two switchable Have areas of very high frequencies tuned.

It is known. that the tuning of oscillation circles at very high frequencies causes difficulties when relatively large frequency bands are to be swept over. In the case of capacitive tuning, the spatial dimensions of the capacitor are limited by its inductance, and in the case of inductive tuning by means of a movable core, the tuning range is narrowed by using a material with a relatively low permeability for the purpose of limiting losses in the core got to.

The object of the invention is to provide a tuning circuit for very high frequencies to create that can be tuned over a wide frequency band, with one Simple switching device does not allow the self to induce a second frequency range even higher frequencies can be scraped over.

According to the invention, the oscillation circuit contains an inductance a helical coil, an axial return line and a ferromagnetic, A core that can be moved in the coil for inductive tuning and a switching device to short-circuit, the screw-shaped part of ind.ucbivity, through the simultaneous with the switching of the inductivity also m.ind, at least one of two resonant circuit condensers = to change the frequency range of the oscillating circuit will.

Since the present invention uses ferromagnetic iron cores for the purpose used for tuning, it must be mentioned that in the frequency range from 5o to 200 MHz the effective perineability of nuclear materials is about 6 Has, measured on a toroidal (ring-shaped) test piece. This U'ert diminishes in common constructions to about 2.5, if one considers the effective permeability measures in stretched single-layer coils with corresponding cylindrical cores.

The present invention can be more easily understood if the drawings are used that show embodiments of the inventive concept.

Fig. I shows a section through a variable inductance accordingly of the present invention: .Fig. Fig. 2 shows a side view of the inductivity; Fig. 3 and q. give the circuits of oscillation circles, sen for very high frequencies again, in which the inductance according to Feig. i and 2 is used; Fig. 5 testifies , the circuit of a tuning device according to the present invention: Fig. 6 shows the plan view of an embodiment of a voting unit that is used in the circuit of FIG. 3: FIG. 7 shows the side view of FIG Fig. (i, with some parts left out.

Fig. I shows a modified design of the variable Sedhstindu @ ction, as it is the subject of a proposal made elsewhere.

After that suggestion, the tuning coil consists of a helical part and a coaxial straight return conductor. In addition, the coil contains a longitudinally slit: V> voice core. softer -in, the coil can be scraped in and out of the same. "Unfortunately, the inductance parts, coil and return line, are equally influenced. In the modified version according to FIG. e coil 2. One end of the coil is pressed firmly onto the pipe by means of the ring d. while, in addition, the coils are cemented firmly onto the pipe I. The other end 5 of the coil 2 can be secured by a rivet or a screw 6 can be fastened to the tube. A wire 7, which extends coaxially through the tube i, is bent at right angles at its one end 8 and is connected in metal with the coil 2. The protruding end R of this I ' Prahtes is also connected to a thick return line, e.g. in the form of a resilient leaf io, one end of which is held by means of a bolt or rivet ii. The free end of the spring io can be in direct contact with the end at 12 of the bobbin 2. where-.by the disk-shaped part of the coil is short-circuited. A movable ferromagnetic core 13 provided with an elongated slot 14 in FIG. 2 can be drawn into and out of the tube i, as a result of which the inductance of both clusters of the self-inductance link is changed. If the contact 12 of the spring io is open, the self-induction gl: ied a linear »part, -. the one in Reilie with the helical part 2 lies, and both parts are disconnected at the same time by means of the slide core gesti-mmt. This open position of the contact 12 corresponds to a certain range very high hrequenzen, as will later be 1>esc.liniel> en. Will on the other hand, the contact 12 is closed, so the helical part 2 shorted and it all that remains is a much smaller loading activity from the straight return conductor; and the spring io composed, and also by the same Core 13 can be matched. So let yourself two different initivity values with one Achieve device that is particularly suitable for very high frequencies. - 'volei' both through the 13ew, inclination and des- same core changed can turn. Fig. 2 shows the side view of the in P ig. i on average reproduced Sellnstiaduction. Contact 12 can by a \ 0ckenscheil> e (> the drum is be operated. which on axis 16 is to be spent. Fig. 3 schematically illustrates the reversing such a variable inductance in a simple resonance circuit. The suffer te: il- inductances L, and T_. mean the linear and helical 'for the in Fig. 1 and 2 dangestel @ lten Se11> stindiuktion. 1) ie conidens-ators Ci and C2 are parallel to the Sellstindiuktion, where- in 1Zesonanizlzreise "eli forms Nverden, the two different 1 # re <Iuenzl>: correspond to indern. counter io corresponds to the short-circuiting spring in the previous figures and operated at the same time another social contact,: o dai in the marked position 1> eid: ° capacitors pa @ raldel are switched on, while not on. capacitor Ci remains in the circle when the switch io @in dlie other position brought wind. Fig. I. shows a simplified arrangement in which the Capacitor C, parallel to the helical Partial inductance I_ is. In this case only a simple switch contact is required. to the Circle from one frequency range to deli their to switch. Here the con- densator C, as a. \ it \ good for the higher frequency range in addition to the switching contacts io. In the lower frequency range the waves Inductance of the linear part as a small Reactance. It is also used in certain others Cases the additional one formed by L i and U i Circle, which, seen in practical terms, is parallel to the Circle L., C, is located. undesired higher frequencies suppress. z. 13. the harmonics one: oscillator. In the practical example for the present Invention can follow deli values used will. The helical part is on a A tube of about 6 inni diameter wound, 38 m long with a copper tape 3 mm wide., Which is a self-induction of o, i2, cH including the inductance of the linear part results, the latter for wire 3 '/ 4 mm in diameter is calculated to be less than 0.03 "H. total circuit capacity v ( ) " 30 PF results in a Resonance frequency from 50 to 8o MIlz, depending on whether the core is pushed out or in. This means that the effective permeability of the core is 2.55 when the core changes both parts of the self-induction. If the helical partial inductance is short-circuited, the new tuning capacitance Cl = 10 pf, 'the resonance frequency is between 165 and 200 MHz, which corresponds to an inductance of L, = 0.05, uH and an effective permeability of 1.5. If such a circuit is used in the input or output of an electron tube, the capacitors C and C2 must be rebalanced to compensate for the tube capacitances.

Two different frequency bands, similar to the one mentioned above. will commonly used in television receivers. It's pretty easy to get the mood in the lower frequency band with a coil and a core of conventional design. However, the higher frequency @ hand causes considerable difficulty, since with a Coil with an iris two turns coordinated by a movable core is not very effective. This difficulty can be overcome by tuning by means of a resonance conductor be bridged, but in both cases there is a majority of coils and cores with a complicated switching mechanism required. If you take into account that at very high frequencies the feed lines and circular elements extremely must be kept short and concise. so it makes sense what difficulties oppose the use of a large number of coils.

The present invention overcomes these problems. the The simplicity of an arrangement with the new AI> tuning device can be seen from FIG. Here, 20-2o represents a dipole that is connected to the coupling turn via a rapid feed line 2 i is connected. In the low frequency range, the coupling is mainly Lich inductive, but capacitive in the higher frequency range. The first matched Circle 23 is according to Fi '. 3 or I 'iig. 4 and contains all the essentials Elements, namely a single inductance 22, 27 corresponding to parts 2 and 7 of FIG Inductance in 1 # ig. i, and capacitors Cl and, C9 and a switch contact to. The circle 23 lies on the control grid of a pentode tube 24. A similar circle 25 is an exit of the same tube. To get a sufficiently wide frequency band A third circle will achieve, as is required in television receivers 26 similar llauart coupled with .drin voting circle 25. Small coupling conic capacitors 28 couple the third and the second circuit to form a band filter. the end the drawing can be seen that the lower capacitor 28 as a coupling member works when the switches are open, which corresponds to the low frequency band. The third tuning circle 26 is connected to the one grid 29 of a 1) ol> 1> eltriodle 29-30. This tube works as an input tube and mixer, in whose output the intermediate frequency transformer 33 lies. The triode part3o belongs to a Colpitt oscillator with the voltage divider 31, two adjustable capacitances Cl and C2 for two frequency ranges and one Inductance 27 of the same type as previously mentioned.

The inductances are tuned in synchronism by simultaneous Moving the cores 13, which is indicated by the dashed connecting line is. The switches io are also operated by a single operating handle. The circles must be magnetically and electrostatically shielded from each other, as illustrated by the dashed rectangles 32.

The circuit according to Fiig. 5 can be modified like this; that in place d the tunable input circuit 23 an input band filter is used, which each lets through an entire frequency range. Using suitable switching devices you can then switch from one to the other band filter input circuit.

The entire voting unit as shown and described in FIG. 5 can take the form of a simple unit that takes up little space as shown in Figs. 6 and 7. Given the shielding required it is advisable to mount this unit in a metal box. This box; 34 contains partition walls 32 inside, so as to provide the desired shielding between the To reach circles. In Fig.6 is a plan view of the box is shown, wherein the dashed lines represent the partitions. They're in the lid of the box Sockets 38 for the oath tubes, 24 and 29-3o let in. free coils can be arranged between the box walls, as shown in Fig. 7, the Walls are provided with openings through which the cores enter the coils can. The cores are adjustably attached to a bridge member 39, the movement of which a simultaneous equalization of all circles. As if from Fiig. 7 can be seen, are the coils, arranged in the immediate vicinity of the tube sockets, so that result in very short leads. The capacitors are right next to the coils Cl and C2 mounted, which are matched through the lid of the box can. Thus, all parts of each circle are in a separate compartment of the box. With the help of the switching mechanism 15, 16, which extends through the entire Length of the box, all trimming circles can be switched at the same time will. Various devices can be used to move the cores. The one shown in the picture consists of a screw 4o, one end of which is in the Box wall is supported, and the nut 41, which is firmly connected to the bridge member 39 is. Guide devices 43 are provided to prevent tilting during operation to prevent. The Direhbewegungunb the button 42 can be triggered with a device of the frequency range to which the device is tuned. the Switching device can either be operated by hand or can so be designed @ that at the end of the core movement, the switch is automatically closed or be opened.

Claims (3)

PATENT CLAIMS: i. Oscillating circuit, which can be tuned over two ranges of very high frequencies, characterized in that it has an inductance with a helical part (coil), an axial return line and a ferromagnetic core, which can be moved in the coil, for inductive tuning and a switching device for short-circuiting the contains helical part of the inductance, which is switched off or over at the same time with the Umschialtung, dier inductance also at least one of two resonant circuit capacitors for the purpose of changing the frequency range of the resonant circuit. 2. voting circuit according to claim i, characterized in that that one of the two capacitors between the free ends of the coil or return line so that it is parallel to the residual inductance when the coil is short-circuited. 3. tuning circuit according to claim i and 2, characterized in that when switched on of the coil, the second capacitor is also between the free ends of the coil or return line, while it is short-circuiting the coil by the changeover switch is disconnected from the circuit. . Voting circle mach claim 2, characterized in that d @ ate the second capacitor parallel to the helical part of the inductance is and wind short-circuited together with this by the changeover switch. 5th voting circle according to one of the preceding claims, characterized in that d @ aß an or 'Both capacitors are adjustable. 6. Voting group according to one of the preceding genes _ @ tisprüche, characterized in that the switching device for short-circuiting , the helical partial inductance contains a flat spring. the one with an end is connected to the helical coil and which is so geloxygenated when switching, that it makes contact with the other end of the coil. 7. The application of an additional number of voting circles, be it according to one of the preceding claims in Nfehrkreiseinl> catch, such that an adjusting member adjusts all movable cores simultaneously and a common actuating element is the schaulyen-shaped parts of all inductances shorts.