DE679632C - Device for remote display of the deviation of a frequency from another constant frequency - Google Patents

Description

Device for remote display of the deviation of a frequency from a other constant frequency The invention relates to a device for remote display the deviation of one frequency from another constant frequency, which however is not used to synchronize two AC sources, where it is not is necessary too. know which of the two frequencies is greater. If this task previously had to be fulfilled, it was customary to transmit both frequencies to the display location, where they could be compared to each other. Naturally, this is very annoying, because the equivalent stresses themselves may be transmitted over long distances Need to become. But even if you telemetry about both frequencies Would have transferred replica quantities, the expense of two special ones would still remain Telemetry equipment and the creation of two transmission channels. These disadvantages the known devices are eliminated by the present invention, that at the encoder location the variable frequency beats with the constant frequency is brought about, the impulsive changes in the intensity of high frequency transmission vibrations cause. These beats are then displayed at the receiving location. This will created a device that over the known arrangements the preference low transfer effort and, above all, high transfer accuracy hiet. By converting the beats into pulses of high-frequency vibrations the advantage is also achieved that clear display conditions at the receiving location created with respect to a deviation of one frequency from the constant frequency can be.

The features of the invention are to be explained in more detail with reference to the drawing will. The drawing shows a device that has already been proposed elsewhere for synchronizing two alternating current sources I, 2 from a remote I command post B shown in which after the command post B all for the display of the Synchronism necessary values through simulation variables over a single transmission channel be transmitted remotely, preferably by means of a single multiply modulated High frequency carrier wave. I means a circuit, as a multi-phase network shown is a single generator or, as usual, a branched one Distribution network may include. It is assumed that this network has a certain has constant fre quency. 2 shows a generator at a substation A of the distribution network. This generator supplies a frequency that is called the actual frequency and their deviations from the constant frequency are measured and displayed remotely should be. The arrangement shown at A includes that on the substation devices placed near the generator 2. Devices are shown at B which are arranged in the distribution or switching point. To control the generator 2 and switch 3 from B can be any known remote control or remote switching device to be used. These facilities are therefore not described in detail here.

In the substation 24 is a vibration generator, 'through the coupling capacitor 5 high-frequency currents to the grid circuit of an amplifier 6 supplies the output circuit through a transformer 7 and the conductor 8 with the network 1 is in communication. The vibration generator 4 and the amplifier 6 can be designed in any way; in the drawing they are as discharge tubes with three Electrodes shown, the cathode circle of which is through the circle 9, the transformer 10 and the conductors II, each of which is connected to a phase of the generator circuit 2 stands, to be fed. I2, I3, I4 represent transformers, the number of which number the phases of the generator 2 or the network I corresponds. The primary winding each this transformer is available via lines I5, I6, 17 with the corresponding Phase of the generator 2 and the network I in connection and bridges each phase of the connection switch 3.

Rectifiers are attached to the secondary circuit of each of these transformers Ig, I9, 20 connected as ordinary discharge tubes with two electrodes are designed and the rectified voltage of the transformers I2, I3, 14 for modulating the high-frequency carrier wave to the anode circuit of the vibration generator 4 and the amplifier 6 supply. The circle of these rectifier tubes is complete via the cathode and anode of these tubes, the secondary windings of the transformers I2, I3, 14 and the conductors 21, 22, 23, the cathode circuit g of the vibrator 4 and the amplifier 6, the distance between the cathode and anode of the vibration generator 4 and the amplifier 6, the anode chokes 24 and 25 and the cathode circuit of the Tubes 18, I9, 20. The cathode circuit of these tubes is made by the transformer 27 also fed from the conductors II. It can be seen that at the moment where an alternating voltage occurs at 'Whom contact pair of switch 3, -dl? 1, idh- the tubes 18, 19, 20 over the circle given above the anodes of the vibrator 4 and the amplifier 6 is supplied with a DC voltage through which these tubes come into effect and high-frequency currents of appropriate strength over the Transformer 7 and circuit 8 to supply network I.

A rectifier 28 is provided at the remote distribution point B, which is also designed as a discharge tube with three electrodes and through the Circuit 29, the transformer 30 and the circuit 31 is connected to the network 1. The circuit 29 includes a self-induction 32 and a capacitor 33 through which he to the carrier wave emitted by the vibration generator 4 and amplifier 6 can be tuned. In the anode circuit of tube 28 is a direct current instrument 34, the primary winding of the transformer 35 and the usual anode voltage source 36 switched on.

With the establishment, as far as they are until now, as part of others Place already specified synchronization device is described, the following is reached: It is assumed that the generator 2 is running at a speed which deviates from that of the rotating field of the network 1, without the speed and thus the frequency deviation initially changes. It then occurs in the primary windings I2, I3, 14 at the same time an alternating voltage. This voltage is rectified and fed to the anode circuit of the tubes 4 and 6 and puts them into action, see above that they supply pulsating high-frequency currents to the network I and consequently also to the rectifier 28, whereby corresponding deflections in the display instrument 34 be evoked.

If the frequency of the generator 2 fluctuates continuously, then this occurs in the display instrument 34 also fluctuations which are equal to the beat frequency between the voltages of the network 1 and the generator 2 are. The pointer of the instrument 34 oscillates back and forth across the scale between two limits, those of the Mlaximal and The minimum size of the recorded carrier wave corresponds, the oscillations take place with a frequency that is directly the time difference between the two frequencies indicates.

By the arrangement described so far, the operator the size of a frequency deviation is displayed remotely. It is also desirable that the operator learns whether the frequency of machine 2 is too high or is too low, a device 37 of a known type is provided for this purpose, which contains a synchroscope or any suitable instrument that points to the Frequency deviations of voltage sources 1 and 2 responds. The arrangement is I, for example the following: A fixed coil 38 is wound on a U-shaped M-agnetkern 39 and is fed by a voltage between the lines 65 of the generator 2.

Furthermore, two rotatable coils 40 and 41 are provided in the right Angle z, mine are arranged and induced by the coil 38 and the magnetic core 39 will.

One of the coils is through one of the lines 65 corresponding Line of the network 1, a self-induction 42 closed, the other coil is in communication with the same line via resistor 43. A more detailed description this arrangement is not necessary as it is already known. With the axis of the rotatable coils 40 and 41 is now a rotating disk 4 extended. 45 represents a lever arm, the center of which is a pivot point near the edge the disk 44 has. One end of this hel, els is through a friction clutch connected to the disk 44, the other end bst free. On both sides of the free At the end of the lever 45 there are two pairs of contacts 47 and 48. Their arrangement is taken as follows: the coils Ao and 41 rotate and consequently also the disk 44 clockwise, which occurs when the frequency of the generator 2 is greater than that of network I, the contacts +7 are set by lever 45 brought to the touch; ; on the other hand, the coils and thus the disc rotate in the opposite sense of what happens when the frequency of generator 2 is lower is than that of the network I, the contacts 48 are closed. The purpose of this Arrangement will be explained in more detail. It now provides a constant running engine is on the shaft of a slip ring 50 and a pair of commutators 51 and 52 sit. Each of these commutators has a number of conductive segments on the circumference of the commutator are isolated from each other and each of which is in electrical communication with the slip ring 50 stands. The commutator 51 lies in a circle that is from the Slip ring 50 across the primary winding of the influencing transformer 53, the Voltage source 54, conductor 55, the contacts of relay 56, conductor 57 and the brush 66, which rubs on the commutator 5I, runs. The commutator 52 in turn lies in a circle from the slip ring 50 via the primary winding of the influencing transformer 53, the voltage source 54, the conductor 55, the contacts of the relay 58, the conductor 59 and the brush 67, which slides on the commutator 52, runs. The secondary winding of the influencing transformer 53 is located between the cathode and grid of the amplifier 6. The excitation coils of relays 56 and 58 are powered by circuits that make the contacts 47 or

48, conductor 60, voltage source 54 and conductor 55 include fed. The contact points of the relays are set up so that they are slightly open slowly, making them less sensitive to shocks as a result of the Stop the contacts 47 and 48 are.

The mode of operation of this part of the facility is as follows: Assuming the frequency of generator 2 is greater than that of network r, then if the disc rotates clockwise, the lever 45 closes the Contacts 47 and energizes relay 56. This relay then closes its contacts, because excited with the primary circuit of the influencing transformer 53 via the slip ring 50 and the commutator 51 and causes the current emitted by the amplifier 6 is modulated by currents whose character is determined by the distance between the segments of the Commutator 51 is determined.

If the frequency of generator 2 is lower than that of network I, SO the disc 44 rotates counterclockwise, and the Het, el 45 closes the contacts 48 and thus energizes the relay 58. The relay 58 in turn closes its contacts and energizes the primary winding of the influencing transformer 53 via the slip ring 50 and the commutator 52 and thereby causes the output current of the amplifier 6 is modulated by currents whose character is determined by the distances the segments of the commutator 52 is determined. It is now z. B. assumed that the segments of the commutator 5t and 52 each have the same distance between each other at the edge, but that the number of segments of commutator 51 is greater than that of commutator 52, while the diameter of both commutators is the same. It is then evident that if the frequency of the generator 2 is greater than that of the network I, the output current the amplifier 6 is modulated by alternating currents of a certain frequency, while, when the frequency of generator 2 is lower than that of network I, the output current of the amplifier is modulated by alternating currents that have a lower frequency own.

To the secondary windings of the transformer 35 in the output circuit of the rectifier 28 on the receiving side are now as well has already been proposed at the other point mentioned several times, suitable Instruments 61 and 62 connected, giving the operator in B the character of the Show modulation currents. For example, these instruments can be a pair of headphones be, or in the above-mentioned case where the modulation currents are in their Distinguish character by frequency, 6I can be a matched relay, which responds to the modulation frequency when generator 2 is running faster, and 62 a tuned relay, which reacts to the modulation frequency at slower speed Run of generator 2 responds. If necessary, the relay 6I can be an optical one Indicator 63 and the relay 62 a visual indicator 64 in action put, one of which through a conductor 68, the voltage source 69 and the Conductor 70, the other through conductor 68, voltage source 69 and conductor 7I is connected.

By observing the strength of the picked up carrier wave and its The operator in the station can detect fluctuations on the display instrument 34 B in addition to the frequency deviation of generator 2 from network I, when the frequency deviation g is eliminated. Likewise, by observing the Instruments 6r and 62 or, if appropriate, 63 and 64 determine whether the generator 2 runs faster or slower than the rotating field of network 1.

Instead of the described modulation device for the carrier wave any other suitable device can also be used.

Likewise, instead of the special device 37 for actuating the Contacts 47 and 48 any other suitable means can be chosen based on the frequency deviation of the generator 2 from the network I responds.

Likewise, the change in the amplitude of the carrier wave can also be corresponding the voltage across the connection switch 3 take place in another suitable manner.

Claims (1)

PATENT CLAIM: Device for remote display of the deviation of a Frequency from another constant frequency, except for use in synchronizing equipment for alternating current sources, characterized in that the variable Frequency with the constant frequency is brought to beats, which become impulsive Changes in the intensity of high frequency transmission vibrations are used, and that the beat is displayed at the receiving location.