DE506174C - Method for setting the characteristics of electrical oscillating circuits - Google Patents

Description

Method for setting the characteristics of electrical oscillating circuits With wireless messaging, it is often necessary to receive a certain wave at the same time two or more circles on one or more To coordinate frequencies,! Which are determined beforehand and depend on the wavelength of the Depend on the station. Most of the time, this tuning is done using variable capacitors made, which are independent of each other and included in these circles. The setting of the receiver requires as many special manipulations as Circles are to be timed, e.g. B. two for many simple circuits with only two Voting circles.

In this case, when trying to simplify the setting, to arrange a device with a single drive member by moving the movable ones or rotatable parts of the capacitors mechanically with one another without special measures connects, so are mostly only for one or two positions of these parts for the conditions set by the recipient are met.

Two simple examples, illustrated by curves, are intended to illustrate this explain in more detail. Let us first consider a resonance receiver with two tunable ones Circles: that of the receiving frame and one connected to the anode of an amplifier tube Circles. Assume that the moving parts of the two tuning condensers are mechanically connected to each other, and two curves are plotted (see Fig. i) by plotting the sections a of a single quadrant as the abscissa, which is used to mark the position of the moving parts, and as ordinates the associated frequencies f1 and f. "of the tunable circuits.: m in general becomes one, if one lets a experience a continuous unidirectional change, also for f, and f2 receive continuous unidirectional changes, for example in the manner of curves z and 2 of Fig. R.

In order for the resonance receiver to be set, the two must be tunable Circles have the same frequencies, and this: will only be for a single condition Position a, of the two moving parts must be fulfilled, namely in the position in which f, and f, assume the common value f, and only at such a transmission frequency f such a device allows reception.

Let us now consider a finite frequency change receiver, e.g. B. with a superheterodyne circuit, which also manages with two tunable circuits: that of the receiving frame and <lein of the heterodyne circuit for generating the local electrical oscillations. Aigeno, mmen, the moving parts of the two tuning capacitors of these circles are mechanically connected to each other and contact two curves plotted (see. Fig. 2) by again sections as Abz.isse the waste are a single quadrant of the applied for the labeling the positions of the individual movable parts connected to one another and, as ordinates, the frequencies f 1 (curve i) of the frame circle and f2 (curve 2) of the heterodyne circle. The condition for adjusting the reception is to adjust the frequencies f 1 and f 1 so that their difference F has a predetermined fixed value which is nothing other than the frequency F which has been chosen for the amplification at the middle frequency is. If one plots two curves which represent the changes in f2 + F (curve 21) and f2 - F (curve 22) as a function of a, one can see that the condition set up for the tuning of the receiver is fulfilled if f, ,, ; - F = f, or if f 2 - F - f, and .one can find two positions a, and ä, of the variable a, which respectively fulfill these conditions. Accordingly, one can receive with such a receiver on two corresponding frequencies f and f ' , and exclusively on these.

In either case, the presence of only stirs a single position a (Fig. i) or only two positions a, and a2 (Fig. 2) for the vote, therefore, that it was consequently assumed that the two frequencies f, and f, both decrease continuously with the variable a. If you oppose it now represents that for one of the two circles with progressive and constant change a periodic change is superimposed on the frequency as a function of a, see above it is clear that the implications will be different.

In the case of the tuning receiver (Fig. 3) one will have to replace curve i in Fig. I (in Fig. 3, by the way, with broken lines) by curve 3 in order to show the changes in the frequency of the frame circle as a function of a, and this curve 3, instead of having only one point of intersection with curve 2, rather intersects it at a whole number of points. This method of controlling the electrical consists in superimposing a periodic change on the progressive and constant change in frequency, which is a function of a. For this purpose, it has already been proposed, by the way, to allow the two curves to intersect at a plurality of points. There are therefore numerous positions a1, aa ;;. . .. of the mechanically interconnected moving parts, in which the condition for the tuning of the receiver is satisfied, and the receiver will allow reception on all relevant frequencies f, f ', f "....

One notices immediately that the number of points of intersection of the two curves 3 and 2, the larger the higher within the range of possible fluctuations of curve 3 is the number of periods.

Incidentally, it goes without saying that if the number of the exact Adjustments corresponding to the intersections of curves 3 and 2 become very large, can be received on all other waves under practically sufficient conditions can, whose frequencies are between and close to those that are precisely tuned Settings correspond.

The same can be applied to the mode of operation of a receiver with a frequency change (Fig. 4). If the frequency f, of the frame circle, apart from the steadily and progressively decreasing change, is superimposed on curve i in Fig. 2 (dashed in Fig. 4) a periodically repeating fluctuation as a function of a in order to replace curve i, this gives a curve 3 which, instead of intersecting curves 21 and 2 = in only one point each like curve i, intersects them in a large number of points, where each intersection has a value of a (a ,, a, " ...., aZ, a2 ', aZ".... ) for which the receiver is precisely tuned. All waves that correspond to the ordinates of the intersection points can be received with such a device. These waves are the more numerous, the higher the number of fluctuations in curve 3 within the range of changes in a. In addition, as in the previous case, under practically sufficient conditions, you can still receive at any frequencies that lie between those that correspond to the exact settings, if the number of these settings is very large.

To the frequencies of the two circles for their change such laws to be able to impose, as shown by Fig. 3 and, 4, it is sufficient as Tuning capacitor of one of the two circuits to use an ordinary capacitor, the capacity of which increases steadily if the slats are placed in the fixed part of the rotatable part is advanced. When this capacitor circles on the frequency f2 belongs to, f .: will decrease steadily when you change the angle a, the the moving part forms with the fixed part of the capacitor s, steadily increases. As a capacitor of the other circuit with the frequency f, one would have to on the other hand, use one whose capacity is when the moving part rotates of the capacitor except for a change with constant main tendency fluctuations experiences that have periodic changes in the frequency f, in the wake, fluctuating around its mean value, which progressively decreases if one considers the angle a, which the Moving part forms with the fixed part of the capacitor, increasing steadily leaves.

There are three options for attaining a vote with given a single drive taking into account the above.

These three possibilities can be illustrated schematically by Figs. 5, 6 and 7 are marked.

All devices according to the scheme of A'bb.5 are through a single Actuating element lLT, which acts directly on organs C, which cause a change with a constant main tendency of the two capacities. These organs C act with a suitable, unchangeable translation Organ P a, which ensures the periodic change of one of the capacities.

Such devices according to the scheme of Fig. 5 are already known.

The invention essentially relates to the schemes in Fig. 6 and 7.

All devices according to the scheme of Fig. 6 are through a single Actuator M marked, which acts directly on the organ P, which a periodic change in one of the capacities is guaranteed. This organ P acts in turn on the organ with a suitable, unchangeable reduction C one that gives the two capacities their steady changes with constant Main trend imposed.

All devices according to the scheme in Fig. 7 are marked by a single actuator M, which simultaneously acts on the organ P and the Organ C acts with suitable reductions. Here is the reduction ratio for C greater than for P, so that one always has an increased number of periodic changes receives for the capacity, which must have fluctuations in the course of the complete Change in those of the capacities, which only change with the main tendency remaining the same change.

According to a modification of the inventive concept, the aforementioned Devices combined with a handling to be carried out first, the therein consists in regulating the electrical characteristics of a first device by this first device in relation to a second device with variable electrical characteristic shifts. The foregoing is not just a periodic one Change and change have been shown with a constant main tendency, but rather it is also apparent that the invention extends further to a practice of described type, regardless of the number of combined fluctuations.

Devices according to the invention are for example in Figs. 8.bis 12 of the drawing.

Figure 8 shows a schematic section through a device according to the invention -dar, the mode of operation of which corresponds to the general scheme of FIG.

Figs. G and io represent another device according to the invention whose mode of operation corresponds to the general scheme according to Fig. 7.

Figs. I i and 12 represent a further device according to the invention represent.

The device according to Fig. 8 works mainly according to the process, which was identified above with reference to the schematic Fig. 6. it consists of two variable main capacitors i and their moving parts i 'and 2' mechanically are firmly connected to each other ° and in the actual execution of each other can be electrically isolated or not isolated. A third changeable Capacitor 3 has a movable part 3 ', which on a shaft .l. sits that through the hollow shaft 5, the two moving parts i 'and 2' of the former Capacitors passes through.

The capacitors: i and 3 connected in parallel form the Tuning capacity of a circuit 6, the frequency of which f, from the sum C, -j- C3 of Capacities of the two capacitors i and 3 depends. The capacitor 2 forms the Tuning capacity of another circuit 7, whose frequency f.2 only from the capacitance C2 of the capacitor 2 depends. At the end of the wave d. is as a handle a button 8 is attached and the operation of the device is as follows itself: If you turn the knob 8 steadily in the same direction of rotation, this takes Knob in its rotation the shaft .4 and the moving part of the condenser 3 with. In the course of one complete revolution of the knob 8, the capacity changes C3 of the capacitor 3 between its minimum value, which is reached when the movable Slats 31 are completely out of engagement with the fixed blades 32, and its maximum value, which, on the other hand, is reached at the moment in which the movable slats 31 are in full engagement with the fixed blades 32.

The wave q. also takes the hollow shaft 5 under its rotation Conveyance of any reduction ratio, which is shown schematically through the gearbox 9, io, i i, 12 is indicated, the last wheel 12 sits loosely on the shaft 5 and is connected to it only by the star springs 13. Rotates as a result of the reduction the shaft 5, when the knob 8 and shaft 4 complete one revolution, only at a very small angle, e.g. B. l / loo of a revolution if the fixed reduction ratio ioo: i is. The moving parts carried by it are of the shaft 5 il and 21 taken along, turning them only through a small angle, what results in a slight change in the capacitances Cl and C2.

So if you keep turning knob 8, the capacity also changes GJ Slow with a constant main tendency, and the frequency f2 of the vocal circle 7 also changes steadily and with the same main tendency. Against it lets the capacitance Cl + C3 of the circuit 6 has two expressions, Cl, which is continuous changes with a steady tendency, and C3, which changes periodically. From it it follows that the frequency f of the circuit 6 is simultaneously a constant change with constant main tendency that learns of the changes in capacity C1 arises and periodic fluctuations resulting from changes in capacitance C3, the periodic changes of which are all the more numerous in the complete one The range of fluctuations in Cl and C2 is, the larger the reduction ratio is of the transmission 9, 1o, i i, 12 is.

This device works according to the general scheme of Figure 6. That The only actuator here is button B. This drive element controls directly the organ that causes the periodic fluctuations, and here from the wave q. and the movable parts 31 carried by it, which by means of a suitable fixed reduction takes the organ that the fluctuations with a constant main tendency and which here from wave 5 and the movable parts 21 and il carried by it.

You can of course provide a second button 1.4 on the hollow shaft 5, as shown in dashed lines. This second button then allows before pushing the button 8 rotates to bring the capacities Cl and C. quickly to such values that the Circles 6 and 7 assume frequencies of the order of magnitude of the waves that one wants to receive. In order to then listen to all stations that work in this frequency range, it is sufficient to turn knob 8 slowly and steadily.

With the addition of the button 14 there is not the slightest thing about the essence the device changed. It just makes it faster and easier Handling achieved.

The device according to Fig. 9 (axial section) and io (vertical section to the axis) works essentially according to the process, which is based on the schematic Fig 7 depicted wound.

The two variable capacitors 15 and 16 have movable ones Parts 15 'and 161, which are fixed on a common hollow shaft 17. Through this Hollow shaft is passed through a shaft 18 which has a rotary knob on one end 181 carries. On the shaft 18 sits at the other end of a pinion i9, which is part of a Reduction gear i9, 2o, 21, 22 forms, the last wheel of which on the hollow Shaft 17 is loose and is only connected to it by the star springs 23.

The entire device described so far serves to take along the moving parts 15 'and 161 continuously and in a constant direction of rotation in a steady, very slow rotation when the knob 1 81 is rotated.

The part 162 of the capacitor 16 is full! constantly immobile like that of an ordinary variable capacitor; he is rigid in the frame of the Device built in.

The part i5` = of the capacitor 15, on the other hand, is on a shaft 24. fixed, which can rotate between two track pins 25 and 26, for example. These Arrangement has the consequence that the part 152 has an oscillating movement around the track pin -25, 26 can be given if the knob 181 is turned continuously.

For this purpose, the free ends 27 of the lamella of part 152 are firmly connected to the end 28 of a lever 29, which is connected to its other end can rotate about a shaft 31 which forms an extension of the shaft 24. One Latch 32 of suitable shape is attached to the end of shaft 18.

The lever 29 is based on this catch and is with her under the Effect of a spring placed around the shaft 31 is kept constantly in contact.

If the knob 18 "is rotated evenly and in a constant direction of rotation, the lug 32 gives the lever 29 a periodic oscillation about the shaft 31, and as a result the part 52 oscillates in the same way about the shaft a4.

The Fig. Io is a section perpendicular to the shaft 18 and contains only the essential organs that play a role in the oscillating movement of the part 152. But this figure clearly shows the mechanism.

If one examines the laws according to which the capacities C, and C2 of the two capacitors 15 and 16 in the course of a continuous rotation of the Change knob 181 in the same direction of rotation, one recognizes that C2 (capacitor 16) changes in a simple manner evenly and with a constant main tendency, while C, (capacitor 15) has an average value that increases with constant The tendency changes, but according to the periodic fluctuations of the part 152.

If the capacitors 15 and 16 are first the capacitors of the two Circles 34 and 35 are so changes if you press button 181 evenly and with constant direction of rotation rotates, the frequency f2 of the circle 35 with constant The tendency is steady, while the frequency f, of the circuit 34 has an average value that changes constantly with a constant tendency, but with periodic fluctuations is subject to around this mean value. These are exactly the theoretical ones at the beginning conditions that must be met in order to use a single drive.

The device works exactly according to the general scheme of Fig. 7. A single actuator (button 181) controls g1, in time and with appropriate fixed reduction ratios the organ that the constant changes causes (wave 17 and parts 151 and 161), as well as the organ, (read the periodic Changes caused (shaft 24 and part 152), the reductions through the gearbox i9, 2o, 2i, 22 on the one hand and on the other hand by the shape of the catch 32 are.

As with the device according to Fig. 8, one can use the hollow shaft 17 to arrange a second button 36 which allows the moving parts to be quickly activated 15 and 16 in such a position that circles 34 and 35 already have frequencies of the order of magnitude of the wave you are looking for.

After this preliminary setting, the knob 181 is turned slowly and with a constant sense of rotation and can listen to all transmitters with frequencies work that are in this area.

To simplify the description, only the changes in the tuning capacities of two circuits are considered, however, can the procedure described and the devices described, of course, also in all other electrical variables can be applied, whereby it is then general is possible when two electrically variable are given, by means of a single one Actuator a steady change of one of them with constant Main tendency to unite with a periodic change of a second, whereby these carry out a fluctuation around a mean value with a constant main tendency may or may not.

Figs. I i and 12 show a device in which the capacitors are replaced by variometers or by self-induction.

This device allows a preliminary actuation, which is used to: to operate the electrical characteristics of a first device by this first device in relation to a second device with variable electrical Characteristic is shifted.

In addition, the device according to Fig.1a shows that one first actuation to be carried out the variometer 4o with respect to the variometer 41 can move. For this it is sufficient to press the button 14 and thus the shaft 5 of the spool 4o1, which is stuck on this shaft, to rotate. On the other hand, this rotation has no influence on the variometer 41.

Once this shift has been made, further handling takes place, as shown in Fig. 8, in such a way that you press the button 8 rotates, which results in: i. the periodic change of the induction coil 42, this acts on the coil 421 by induction; 2. with the mediation of Reduction gear, 1o, i i, 12 and g1, 1o1, 111, 121 the smooth change of coil 401 in relation to 402 and coil 411 in relation to 412, the coils 402 and 412 are fixed. In the latter movement, the coils 4o1 and remain 411 are adjusted to each other at the same angle that they were at the preliminary adjustment have received.

The device for displacement described above with reference to Fig. 12 is of course not only with variometers, but also with capacitors among similar ones Conditions applicable.

The above devices can also be used with periodic Apply fluctuations in resistance, such as occur with a voltage divider, one element of which make a periodic movement can. For example this is the case when the contactors of such a voltage divider have a and carries out forward movement on fixed resistances, on the other hand another Experiences fluctuations in the electrical characteristics with a constant main tendency.

Claims (6)

PATENT CLAIMS: i. Procedure for setting the characteristics electrical oscillation circuits, especially for wireless communication, in which there is a periodic change in an electrical characteristic, and a change in another characteristic of this circle while the main tendency remains the same, where the curve of periodic changes is the curve of continuous changes in intersects a large number of points, characterized in that the setting either acts on the periodic change, which the change with constant Main tendency entails, or that it is due to the periodic change and the change acts with a constant main tendency, with a suitable fixed reduction ratio always between the periodic change and the change with a constant main tendency exists in such a way that the latter change is always slower than the periodic change. 2. The method according to claim i, characterized by a preliminary adjustment, which consists in that the electrical characteristic a first device is tuned, change this first device in relation moved to a second device with variable electrical characteristics will. 3. Electrical device for performing the method according to claim i, which is intended for the adjustment process of the tuning capacities of oscillating circuits apply, characterized by a single adjusting element (8), which is immediately acts on an organ (q.) which periodically changes one of the capacities causes, whereby the organ (q.) in turn - by means of a reduction (9, io, 11, 12) another organ (5) influences which fluctuations in the capacities at constant main tendency generated. q .. Electrical device for execution of the method according to claim i, which is intended to perform the adjustment method of the To apply tuning capacities of oscillation circles, characterized by a single Adjusting organ (i81), which acts simultaneously on an organ (2q., 15 ') which causes periodic changes in one of the capacities, and on an organ (17, 151, 161), which shows fluctuations in capacities with a constant main tendency generated while a suitable invariable reduction ratio is between the periodic Change and fluctuations with a constant main tendency are located, which the latter fluctuations take place more slowly than the periodic change. 5. Application of the method according to claim i for setting any, deviating from the capacity electrical characteristics and in particular for adjustment by means of a single organ that has a periodic electromagnetic or electrostatic effect which is caused in a circle and with the constant change an electrical characteristic, capacitance or, in particular, self-induction in is united in another circle. 6. Application of the method according to claim i with a periodic change of an electrical resistance, characterized in that, that this change with a fluctuation of an electrical characteristic with constant Main trend is combined.