DE500308C - Device for automatic control of antenna tuning - Google Patents

Description

Device for automatic control of antenna tuning The The invention relates to a device for the automatic control of antenna tuning, which is of value when there are sudden changes in antenna impedance, for example in stormy weather. It has become known for automatic control the antenna tuning a mechanically moved tuning element, z. B. one by one Motor controlled variometer, to be used, with the motor depending on the Changes in a changing size of the station, e.g. B. the variable antenna impedance, is controlled.

The present invention provides a particular type of such automatic control, which is very useful for sudden changes in antenna impedance is sensitive. According to the invention is used to control the movement mechanism The tuning element uses a continuously oscillating relay (vibration relay) and the vibration level of this relay is influenced by the antenna changes. The then occurring change in the regularity of the relay oscillations causes the control of the voting mechanism.

The invention is shown in the drawing in three figures.

Fig. I is a circuit diagram. Fig. 2 shows a cross section through the Coupling related to the invention.

Fig. 3 shows a modified embodiment.

It is i a high frequency machine with the stationary windings : 2 and an inductor 3 driven by a machine q. of constant speed is driven. Some of the anchor windings: 2 are one with the primary winding Transformer 5 connected, the secondary winding of which is connected to the antenna 6 in series. The variometer 7 and the primary transformer windings are located in the antenna circuit 8 and 9, which include the secondary windings io and ii.

A regulator with a saturated iron core or a magnetic amplifier 12 is used to interrupt the transmission of currents which are supplied to the antenna 6 by the machine i in accordance with desired signals. This magnetic amplifier contains the high-frequency windings 13 which are connected by capacitors 14 and 15 to a coil 16 which is inductively coupled to part of the antenna. This coil can form a third winding on the transformer 5 if necessary. A winding 18 is inductively coupled to the winding 13 and is fed with direct current from a current source i9 through a switch 2o. When this switch is in the position shown, the circuit of the coil 1 8 is interrupted and the impedance of the amplifier 12 is such that a voltage applied to the secondary winding of the transformer 5 by the machine i causes a radiation from the antenna 6. When the switch 20 is turned to the left, the current flows in the winding 18, thereby changing the impedance of the amplifier, detuning the antenna and in this way preventing its radiation.

For the purpose of regulating the antenna impedance, the variometer 7 sits on a shaft 2i shown in dotted lines, which can be rotated in one direction or the other by a coupling device 22. This device consists of 2 disks 23 and 24, which are rotated in opposite directions by a motor 25 by means of the gearbox 26. The variometer shaft 2i passes through the disks 23 and 24 and carries corresponding counter disks 27 and 28. The disks 23 and 24 are loosely mounted on the shaft 21 by means of their hubs 29 and 30 and, like the hubs, are made of magnetic material. On the hubs there are coils 31 and 32, which are fed according to the changes in the impedance of the antenna. When the coil 31 is energized, the disc 27 lies against the disc 23, whereby the shaft 21 rotates in such a direction that the antenna inductance is increased, for example by the variometer 7; when the coil 32 is energized, the disks 28 and 24 come into contact so that the shaft 21 is rotated in a direction which results in a decrease in inductance. The motor 25, which keeps the disks 23 and 24 rotating continuously, is fed by a voltage source 35 through the lines 33 and 34. To regulate the supply of the coils 31 and 32 relays 36, 37 and 38 are used. The relay 36 contains a curved permanent magnet 36R, which at one end carries an oscillating arm 39, the polarizing members 40 and 41 of the same polarity and the contacts 42 and 43 which control the relay 37 cooperates. The polarized part 4o sits on a core, and the core has 2 windings, of which the winding 44 is fed by a 60 periodic machine 45, while the other winding 46 with a tube 47 lies in a circle. The polarized portion 41 sits on a core which carries windings 48 and 49 similar to windings 44 and 46, but which are wound so that they produce opposite polarity. The winding 49 is in a circle with the second tube So. The oscillating member 39 is connected to the neutral point between the voltage source 35 and 51 through the relay contact 38 and the effective winding of the relay 37. The relay 37 is polarized similar to the relay 36, and it places its armature against contacts 52 or 53, depending on the direction of the current flowing through its winding. For example, if the oscillating member 39 of relay 36 lies against its contact 42, the current flows from the positive pole of 51 through contact 42, oscillating member 39, contacts of relay 38, effective winding of relay 37 back to the negative pole of 51. The relay 38 is then energized so that its armature lies against the contacts 53, whereby a circuit is closed, leading from the negative pole of 35 through the contacts 53 and armature of relay 37, coil 32 of the magnetic coupling 22 and line 55 to positive terminal of 51 and then back to voltage source 35. In the same way, when the oscillating member 39 lies against its contact 43, a circuit is closed from the negative pole of 35 through the contacts 43 and member 39. Contacts of relays 38 and effective coil of relay 37 to the positive terminal of 35. The relay 37 will then bring its armature into contact with the contacts 52, whereby a circuit is closed, leading from the negative pole from 35 through the contacts 52 and armature of relay 37, coil 31 of the magnetic coupling 22 and line 55 to the positive pole of 51.

When the coils 44 and 48 are fed, their relays 36 are periodic 6o Current oscillates member 39 with 60 periods and remains alternately for the same Period of time in contact finite the contacts 42 and 43, thereby alternating the winding of 37 is fed with currents of opposite polarity. The anchor of the relay 37 is, however, equipped with sufficient inertia, for example by means of a Weight, or perhaps by springs, such that the coils 31, and 32 of the magnetic The clutch cannot be fed during this period.

To control the swinging arm 39 according to the changes serve the antenna impedance. the tubes 47 and So. The anodes of these tubes are connected to the secondary windings io and ii in such a way that the two anodes supplied. electromotive forces are in phase with each other. The anode circles are completed by the windings 46 and 49, while the grids with a the armature windings of the motor i are connected. In series with the armature winding of this motor are the resistor 56 and the capacitors 57 and 58 so that the phase relationship of the electromotive supplied to the two grids Forces that are one polarity for longer periods than the other polarity. As a result, the armature of the relay 37 lies against its contact 52 and feeds through it the coil 3 i, which now presses the disc 27 against the disc 23, whereby the shaft 21 moves in a direction that improves the antenna impedance. In the same way, if the antenna capacity is increased, it remains above normal the oscillating member 39 back against the pole piece 4o, so that the armature of the relay 37 comes into contact with the contacts 53. Then the spool 32 becomes the clutch 22 excited, whereby the disc 28 is pressed against the disc 24, the shaft 2i rotates in the opposite direction and thus the impedance of the antenna is corrected.

By switching on the relay 37 .mit an armature of relatively great inertia between the magnetic coupling 22 and the relay 36, the magnetic coupling does not respond to the normal action of the oscillating member 39 , but only when the effect of the impedance change in the antenna come in addition. Where the transmitted signals are generated by detuning, means are provided according to the invention to prevent the magnetic coupling from responding to the detuning. These means consist of the relay 28, the contacts of which are in a circle with the active coil of the relay 37 and the oscillating member 39. The effective coil of 38 is in a circle with the transmitter switch 20 and the voltage source 35. So if the switch 2o is set to the right, for example when transmitting high-frequency waves through the antenna, then the effective coil of the relay 38 is excited and the clutch is on address the action of limb 39. When the switch 2o is turned to the left, the contacts of the relay 38 open and the clutch 22 no longer responds.

In the embodiment of the coupling according to FIG. 2, 6o is a shaft driven by a motor 25 at constant speed, and 61 is a flywheel of great inertia. The hub sleeves 29 and 3o, which sit loosely on the shaft 21, are connected to bevel gears 62 and 63 which mesh with the bevel gear 64 of the shaft 6o. As a result, the hubs 29 and 30 are driven in opposite directions at a constant speed, while the shaft 21 does not normally rotate. The disks 27 and 28 can perform a slight lateral movement with respect to the shaft 2i. The coils 31 and 32 are arranged in a housing 65 so that they do not come into contact with the rotating part.

With the arrangement described above, in which all parts including the rotor of considerable inertia are kept in constant rotation, one can obtain a very rapid operation. This is particularly desirable in stormy weather where the antenna capacitance is subject to very sudden changes. In systems where these sudden changes do not occur, the magnetic coupling can be replaced by the device according to FIG. Here the shaft 2 1 is driven directly by the armature of the motor 25. Under normal conditions, the armature of this motor does not rotate, but is short-circuited by a circuit consisting of line 33, the normally closed contacts of relay 31, armature of motor 25 and the normally closed contacts of relay 32. The effective coils of relay 3 i and 32 correspond to the coils 3 i and 32 of the magnetic coupling according to FIG. i and are controlled in the same way by the relay 37 of FIG. If, as a result of a change in the antenna impedance, the armature of the relay 37 lies against the contact 52, the relay 3 1 is energized, whereby the normally closed contacts are opened and the normally open contacts are closed. Then a circle is created, leading from the negative pole of 35 (Fig. I), through line 34, the lower contacts of relay 3i, the field winding 66 of motor 25, back through line 33 to the positive pole of 35; in the same way, a circuit is formed from line 34 through the upper contacts of relay 31, the armature of motor 25, the normally closed contacts of relay 32, back through line 33 to the positive pole of 35. The motor is then excited so that the variometerw eile 2i rotates in the corresponding direction. When the antenna impedance is corrected, the armature of the relay 37 interrupts the circuit of the relay 31. This then returns to its normal position and thereby short-circuits the armature of the motor 25, whereby it comes to a standstill. When relay 37 contacts its contact 53, relay 32 is energized which opens its normally closed contacts and closes a circuit leading from the negative pole of 35 through line 34, the lower contacts of relay 32, field winding 66 and line 33 back to the other terminal of 35. In the same way, a current is closed, leading from the negative pole of, 35 through line 3q., Upper contact of relay 32, armature of motor 25, the normally closed contacts of relay 31, back through line 33 to the positive pole of 35. Then the motor turns in the opposite direction. Sense.

Claims (5)

PATENT CLAIMS: i. Device for automatic control of antenna tuning by means of a mechanically moved tuning element whose movements are dependent on are controlled by antenna impedance changes, characterized in that for Control of the movement mechanism of the voting element is a continuously oscillating one Vibration relay is used, whose vibration state is influenced by the antenna change and that due to the change in the regularity of its vibrations the control causes. 2. Device according to claim i, characterized in that the oscillating relay with its regular movements between two magnetic coils Control contacts closes and opens, and that this process by additional excitation windings on the relay magnet is influenced by the antenna via a tube circuit are excited in such a way that, when the antenna is correctly tuned, the regularity the contact closures that do not result in any movement of the spacer element, do not interfere, but if you are upset, influence it in such a way that the duration of the closings becomes larger on one side than on the other, causing movement of the Voting element is caused. 3. Device according to claim i and 2 with a motor driven tuning element, characterized in that the continuously running, Motor not normally coupled to the tuning element, by the relay control in one or the other sense of rotation the tuning element is coupled as soon as the Antenna is out of tune and with it: the relay closings after one or the other Side predominate. q .. Device according to claims i to 3, characterized in that that for the coupling between the motor and tuning element electromagnetic couplings that are used by the vibration relay via an inertia working Intermediate relays can be switched on and off. 5. Device according to claim i to 3, characterized in that a device is provided through which at Intended antenna detuning, e.g. for keying by detuning, the Effect of the control on the movement mechanism of the tuning element interrupted will.