DE484344C - Device for displaying frequency changes - Google Patents

Description

Device for displaying frequency changes in alternators or other AC power sources, it is often desirable to keep the frequency constant to keep; for this reason it is necessary to have any changes in frequency can be displayed in a reliable manner. Facilities are already known at. which depending on your exceeding or falling below a frequency value opposite effects are caused by having a primary circuit certain frequency affects two resonance crises that affect different frequencies are matched and in the opposite sense on a single device act.

The invention now relates to a device which instantaneously and most accurately, relatively small changes in frequency in appearance lets step; the new facility consists of a simple system, which is great Shows reliability in operation and enables easy and precise adjustment. As with the known device, the energy generated by the alternating current source is sent through two artificial lines, which are also set to that the output voltages of the artificial lines at one and only one Frequency are equal to each other. The invention therefore relates to a device for Displaying frequency changes in an AC system using two in parallel switched artificial lines in which, according to the invention, one of these lines one dependent on the frequency and the other one independent of the frequency Has attenuation, and both lines are connected to a display device, which indicates the difference in the output voltages of the two lines.

Since the output voltages of the two artificial lines are only available from one Frequency have some increase or decrease in frequency above or below the critical point an imbalance between the output voltages of the artificial lines. This imbalance-becomes larger as the frequency change becomes larger.

The AC components coming from the two man-made lines can also be rectified and directed against each other by means of a sensitive display device are compensated. The deviation of the latter indicates the increase or decrease in the normal frequency of the generator.

An embodiment of the invention will be described below, which on the one hand is sufficiently sensitive for the purposes occurring in practice and on the other hand it is extremely easy to manufacture and continues to do so works extremely reliably and precisely or can be adjusted very easily.

A control circuit is used for permanent observation of the instrument provided which forms a feature of the invention. The invention regarding their setup and operation and regarding their advantages and others Features is described below with reference to drawings. In these drawings FIG. 1 shows a circuit according to the invention, in which a lamp control circuit comes to use.

Fig. 2 shows a graph which explains the operation of the system.

Fig. 3 shows schematically a somewhat modified system of the invention represent.

In Fig. I, a pair of bus bars 6 and 6 are connected to the poles of an alternator or other source of alternating current 7. A filter 9 is connected to the busbars by means of a changeover switch 3 and an adjustable resistor 8. Furthermore, there is a compensating resistor or an artificial line io parallel to the filter 9 on the busbars. The latter shows the known one. Characteristics of a filter which passes a band of a certain width with essentially negligible attenuation while sharply attenuating frequencies outside that band. The type of filter that can be used is the one described in Part 3 of the article: Theory and Design of Uniform and Composite Electric Wav e-Filters by Otto J. Zobel, in The Bell System Technical Journal January 1923 . Such filters generally have a number of elements with series and shunt reactances which are constructed according to known theories for the frequency range which the filters are intended to transmit. However, the filter 9 is preferably a so-called low-frequency filter, ie it lets frequencies below a critical frequency through and attenuates the higher frequencies sharply.

A pair of rectifiers is coupled to the filter 9 and to the artificial line io, which has the purpose of rectifying the alternating currents. Any rectifier can be used, e.g. B. Detectors, as they are generally used in radio traffic, or in their place T hermo elements. The drawing shows two balanced detectors ii and 13 of the type in which highly evacuated tubes containing three electrodes are used. The detector ii is connected to the output circuit of the filter 9 via a transformer i2, while the detector 13 is connected to the output circuit of the artificial line io by means of the transformer 14. In the bridge to the transformer 12 there is a circuit q., Which is connected in a similar manner to the artificial line io and can replace the filter circuit 9 with the intermediary of the changeover switch 3. This circuit is explained in more detail below. The tubes II and 13 are in a balanced circuit, the result being the same for both. The anodes of the tubes are switched off at the winding ends of a sensitive galvanometer or at lines 30 and 32 of the lamp circuit on the right-hand side of the dash-dotted line in FIG. 1 in such a way that the rectified energy of one tube is opposite to the rectified energy of the other tube. The anode current is supplied to the tubes ii and 13 from the battery 16 which is applied to the center of the galvanometer winding or to the junction of the lines 29 and 31. The galvanometer is equipped with a scale and a needle that plays over it. The latter fails when the countercurrent currents in the galvanometer are unbalanced. This galvanometer can be replaced by the circuit shown on the right-hand side of the dash-dotted line in FIG. A pair of lamps is also provided. The circuits of these lamps are closed by the galvanometer needle when it swings out of its normal position by a certain amount.

As described above, a simple galvanometer can use the the right side of the dash-dotted line of Fig. i shown lamp control circle substitute.

The artificial line io can be set to work for any frequency within the range of the filter 9 the output currents of the compensates for the latter and the artificial line io. For this purpose one moves the setting contact of the artificial line until the instrument points to zero. Then when the frequency of the current generated by the source 7 increases or decreases, this is how the currents flowing in the opposite direction in the winding of the galvanometer experience a change so that the galvanometer needle deflects.

If the tubes i i and 13 do not fit exactly together, a Attitude to compensate for such a difference is made, indifferently, whether or not the frequency is correct at this moment. Serves this purpose the artificial line q. which is set to have the same attenuation has like the filter 9.

When a new tube is switched on, the filter 9 is through the upper artificial pipe q. replaced by means of the changeover switch 3. The lower one Artificial line io is discontinued until the instrument dies Frequency change Shows zero. The changeover switch 3 is then switched on again for the purpose of switching the filter on again 9 returned to the original position.

The instrument now works with a correction deflection, the Size depends on the inequality of the two tubes.

FIG. 2 shows a curve from which the functioning of the system emerges. The readings on the instrument and the filter output energies are plotted as ordinates and the frequencies as abscissas. It can be seen from Figure 2 that curve A can represent either the output energy of the filter or the difference in attenuation of the two man-made lines and horizontal line B can represent the output energy of the man-made line or the zero line for the instrument readings. The galvanometer registers zero only at one frequency, namely at the critical frequency f ". As explained above, this is due to the fact that the artificial line io is set in such a way that the components flowing through the filter 9 and the artificial line io are the same at a given normal generator frequency and consequently the output energies of the tubes ii and 1 3 are also the same at - this frequency. If the frequency falls below the critical frequency f ", the attenuation of the filter 9 will decrease very quickly, so that the output energy of the filter increases to the extent that this is shown by curve A in FIG. However, if the frequency of the current generated by the generator 7 is higher than the critical frequency fo, the attenuation of the filter 9 increases very quickly. Since the artificial line io has an attenuation which is essentially independent of the frequency, the current component which flows through it is not attenuated by a change in frequency, as is expressed by the horizontal line B in FIG. So if the generator; If a frequency f "is generated, the alternating current which is fed to the detectors ii and 13 is the same, and the same direct current EAIKs are generated in the output circuits i1 adel of the galvanometer in its zero position: If the frequency of the generator 7 increases, the attenuation of the filter 9 is increased, and consequently the emf at the output side of the detector ii drops, and a resultant current flows through the winding of the galvanometer in one such a direction that the needle is moved in one direction on the disk and closes the circuit of a lamp However, if the frequency of the generator 7 falls below the critical frequency f 1, the attenuation of the filter 9 is lower, so that a resulting direct current -EMK is caused in the anode circle in the opposite direction, and the needle of the galvanometer deflects in the opposite direction u nd closes the circuit of the other lamp.

This control circuit, the one on the right of the dash-dotted line Line shown in Fig. I can be used advantageously if it is it is about; constant and reliable, visible control of the system admit. For this purpose, three lamps with different colors are used, only one of these lamps illuminating at a time. A white lamp i9 lights up on when the current of the generator 7 has normal frequency. There is a red lamp 2o on when the frequency rises above the normal frequency and a blue lamp 21 lights when the frequency drops below normal frequency. A pair of batteries 22 and 20 of equal voltage are provided, each capable of carrying a lamp to dine down to medium brightness.

The resistors 2q., 25 are shunted to the lamps 2o and 21 respectively. A pair of relays 26 and 27, which have three windings, are used to switch the lamps i9, 2o and 21 on and off. The direction of current flow through each of these windings is always the same. The arrows next to your relay indicate the direction in which each winding tries to influence the relay armature when excited. The right winding of each of the relays is a crooked winding which gives the relay armature a certain direction and which is normally excited by a circuit that runs from one side of the battery 28 through the right windings of the relays 26 and 27 after the other Pole of the battery 28 runs. As is intended to be expressed by the arrows indicated on these windings, the armature of the relay 26 is directed against the conductor 36 and the armature of the relay 27 is directed against the conductor 34. The middle and left windings of the relay 26 and 27 are identical windings which carry the anode current of the tubes ii and 13, respectively. The tube ii is supplied with the anode current from the battery 16 via line 29, left winding of relay 27, middle winding of relay 26, line 3o, anode of tube ii. The tube 13 receives anode current from battery 16, line 34 left winding of relay 26, middle winding of relay 27; Line 32, anode of tube 13. If the output energies of tubes ii and 13 are equal, the current flow through the left windings of relays 26 and 27 is equal to the current flow through the middle windings of these relays. In this case the effect of the current flow in the middle and left windings is canceled and the armatures of the relays are attracted by energizing the right windings in the direction shown in the drawing. If this condition exists, the lamp ig lights up as a result of a current of the batteries 22 and 23 on the way: positive pole of the battery 22, line 35, lamp 2o or parallel resistor 24, line 34, armature of the relay 27, lamp ig, negative pole of battery 22, and is also excited via a circuit that runs: positive pole of battery 23, lamp ig, armature of relay 26, line 36, lamp 21, parallel resistor 25, line 37 to the negative pole of battery 23. Since the If the lamp ig is in both circuits and both currents flow through it in the same sense, the lamp ig has four times as large a current as either of the lamps 2o or 2, 1, if the resistances 24 and 25 are as large as the resistances of the lamps 2o and 2i. The ig lamp will therefore light up and the 2o and 21 lamps will remain dark.

When the frequency of the generator? grows so does the anode current of the tube i i drop proportionally, as explained above. ' As a result 'is the: .current passing through the middle and left windings of relay 26 and 27 flows, not balanced. A smaller current flows through the middle one Winding of relay 26 and the left winding of relay 27 than through the left Winding of relay 26 and the middle winding of relay 27. The train that the Armature of relay 26 experiences as a result of the excitation of the left winding of relay 26, is consequently greater than the pull that is exerted on the armature by the excitation of the middle Winding is exercised. The armature of the relay is consequently moved so that he comes into contact with his upper contact. In the same way, the train the upward on the armature of the relay 27 through. the excitement. the middle one Winding is exercised outweigh the pull, which is due to the excitation of the left winding of this relay downwards. But since the anchor is already in Touch with his upper contact is because he is going in that direction the right winding of the relay 27 has been turned over, the armature of the relay remains in the position that is drawn in the figure. The white lamp becomes ig as a result short-circuited, the blue lamp 21 is in an open circuit, and the red Lamp 2o is energized via a circuit which is connected to one pole of battery 22 through a line 35, lamp 2o, armature of the relay 26 to the other side of the Battery 22 runs. This shows the frequency of the generator 7 has risen above the normal critical frequency. However, the frequency falls of the generator below the normal critical frequency, the anode current of the increases Tube i i in a proportional manner as explained above, and the current, the one through the middle winding of the relay 26 and the left winding of the relay 27 flows is greater than the current flowing into the left winding of relay 26 and the middle winding of the relay 27 flows. As a result, the armature of the relay comes 26 in contact with its lower contact, and furthermore becomes the armature of the relay 27 also placed on the lower contact. In this case the blue lamp lights up 21 on, on the way: positive terminal of battery 23, anchor and lower contact of relay 27, lamp 2,1, line 37, negative pole of battery 23.

If the armature of one of the relays 26 or 27 between the upper and lower contact remains for some time as a result of a slight change in the frequency of the generator 7 and consequently in the anode current of the tube i i; . so the white lamp will light up dimly and in this way indicates that no special Change in frequency has occurred. If z. B. the armature of the relay 26 between the upper and lower contact is located, the ig lamp is still energized, namely on the way: negative pole of battery 22, line 35, lamp 2o or parallel resistor 24, line 34, upper contact and armature of relay 27, lamp ig, negative pole of the battery 22. In this case, lamp ig receives half the current and lamp 20 receives a quarter the full current of the lamp ig. In the same way, if the armature of the relay 27 remains between the upper and lower contact for a certain time, the lamp ig excited by the battery 23.

Fig. 3 shows the application of the invention to a radio signal system in a somewhat different embodiment. Here, the antenna 38 is connected to earth in series with the primary winding of the transformer 39. The secondary winding of the latter is connected to the input circuit of a modulator 4o. The waves picked up by the antenna 38 are combined in the modulator 4o with an auxiliary wave which is generated by the constant, high-frequency alternating current source 41. The current source 41 is connected to the third winding of the transformer 39 in a circuit. The anode current of the modulator 4o is fed to an amplifier 42. The latter is connected to the input circuits of a filter for low frequencies 43 and an artificial line 44 connected in parallel therewith. The filter 43 is connected to the input circuit of a detector 45 and the high frequency filter 44 is connected to the input circuit of a detector 46. These detectors are differentially connected to the winding of the galvanometer 15. In a system of this type, which works well, the normal frequency of the waves picked up by the antenna was 6,100,000 periods. In this system, if the frequency of the constant auxiliary wave was 594,000 periods, the lower modulation component of 16,000 periods was impressed on the amplifier 42. A wave of 16,000 periods was fed to the filter 43 and the artificial line. As long as the frequency of the incoming wave is kept at its normal critical frequency of 60,000 periods, the output currents of the filters 43 and 44 are the same. As a result, the DC voltages generated by the detectors 45 and 46, which are proportional to the amplitude of the waves sent through each artificial line, are also equal. If, however, the frequency of the waves which strike the antenna 38 increases, the frequency of the waves which are supplied to the filters 43 and 44 will increase accordingly. The filter for low frequencies 43 is in this case arranged so that it strongly attenuates currents above 16,000 periods, and as a result, since the frequency of the current supplied to the filter 43 exceeds 16,000 periods, less current is supplied to the detector 45. However, since the filter 44 has an attenuation which is the inverse of the frequency of the filter 43, the current flowing through the detector 46 is amplified. As a result, the EMF on the output side of the detector .IS will be smaller than on the output side of the detector 46, so that a resulting current flows through the windings of the galvanometer 15 in such a direction that the galvanometer needle deflects towards the lower or positive side of the disc and indicates an increase in frequency. On the other hand, if the frequency drops, the attenuation of the filter 43 will increase, so (let a resultant direct current emf be generated in the output circuit in the opposite direction. In this case, the galvanometer needle 15 is moved to the upper or negative side of the disk and points a The control lamp circuit of FIG. 1 can be used in conjunction with the system of FIG. 3.

1) he iviodulator 40 and the constant auxiliary squell.e 41 of the system, which are shown in Fig. 3, serve to the incoming radio frequency waves to transform into a proportional wave of lower frequency since, it would be difficult would and also costly to build a filter for lower frequencies, e.g. B. 43, which has a critical frequency of 60,000 periods. Such a modulation however, is not essential and is by no means necessary if the Antenna 38 imposed waves have relatively low frequency.

It is clear that the high frequency filter 44 is also an artificial one Line can be which corresponds essentially to the artificial line io of FIG. If you want two filters, the sensitivity of the indicator is greater, but the adjustment is of course more difficult than if a filter and an artificial one Line can be used.

Claims (5)

PATENT CLAIMS: i. Device for displaying frequency changes in an alternating current system by means of two artificial lines connected in parallel, characterized in that one of these lines is a frequency-dependent one and the other has an attenuation independent of the frequency and that both lines are connected to a display device which shows the difference in the output voltages of the two lines. 2. Device according to claim i, characterized in that that the arrangements, which serve, the output voltages behind the artificial To compare lines, include a circuit which has a rectifier on which these tensions are pressed in the opposite direction, and an indicator by which the voltage is proportional to the difference in voltages and correspondingly directed current passes through it. 3. Apparatus according to claim i and 2, characterized in that a device such. B. a changeover switch (3) and another artificial line with one of the artificial lines in connection binding stands, whereby a device for correcting the display device is obtained, which is independent of the frequency. q .. Device according to claim i, characterized characterized in that the device used to compare the stresses consists of two mutually balanced rectifier tubes, their anode circuits are each connected to a relay, each of which has windings, the differential are connected to the anode circuits, and that the relays have a common lamp control circuit influence. 5. Viorrichtung according to claim i for displaying high-frequency vibrations, characterized in that the high-frequency vibrations by superimposition with an auxiliary oscillation in a known manner in low frequency oscillations that however, it is always proportional to the frequency to be displayed.