DEF0010367MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: November 11, 1952 Notified on 25th *. October 1956

GERMAN PATENT OFFICE

The present invention relates to a method of achieving phase lock Synchronous operation between the synchronous motor of a television film scanner and the one with vertical frequency occurring control voltage. There arises the problem of being proportionate low-energy pulse series directly or via corresponding switching elements that proportionally high-energy excitation field of the synchronous motor

ίο generate.

It is already known for speed control of a DC motor by means of a constant Control frequency to provide the motor with an auxiliary field winding, which is in the anode circuit of an electron tube located. The control frequency is fed to the control grid of this electron tube, while the anode circuit is periodically interrupted depending on the speed of the motor. In the case of phase and frequency equality, no current flows through the auxiliary field winding, while at different phase position a current flow is generated, which readjusts the frequency of the motor so long, until there is frequency and phase equality between motor speed and control voltage. the Application of such a circuit to a relatively powerful synchronous motor like him used to drive the movie drive is not readily possible because one is insufficient High-energy control voltage is available to after appropriate amplification

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to generate an auxiliary field.! Such an arrangement also does not allow a phase-locked coupling with the accuracy required for television purposes.

, 5 The object of the present invention is to provide a method in which by means of a relatively The entire excitation field of the synchronous motor is generated with a low-energy control signal.

ίο According to the invention to achieve a phase-locked synchronization with freely adjustable phase position between the synchronous motor of a Television film scanner and a control voltage occurring with vertical frequency from this Initially, pulses with a steep edge and the same frequency were obtained and these were used as ignition pulses with grid-controlled gas discharge tubes working circuit supplied in their output circuit the excitation field of the synchronous motor is.

This direct generation of the entire excitation field from the control voltage makes a complete phase-locked coupling between motor and control voltage achieved, especially with regard to on the position of the film field in relation to the raster recorded by the scanning tube Meaning is.

Expediently, the control voltage becomes First a sinusoidal voltage of the same frequency is generated by a phase shifter can be brought into the desired phase position and from this phase-shifted sinusoidal oscillation If necessary, after appropriate reshaping, impulses of great steepness are obtained, the flanks of which with the zero crossings of the sintis oscillation to coincide. This makes it possible to control the image phase by remote control for example can be changed from the mixer.

When converting the control voltage into a sinusoidal oscillation of the same frequency, to achieve an undeformed sinusoidal oscillation, it can sometimes be advantageous to first generate a meander-shaped voltage with an exact symmetry ratio ι: ι and only generate the sinusoidal voltage from this. From the sinusoidal voltage generated in this way, either when the method is used to synchronize a single-phase motor, the ignition pulses for current torso retention can be obtained directly by amplitude limitation and differentiation, or, if the method is applied to the synchronization of a three-phase synchronous motor, two more by 120 or 240 ⁰ compared to the original sinusoidal oscillation shifted sinusoidal oscillations can be obtained.

The invention is described below with reference to the figures showing the exemplary embodiments. Here are schematically in Fig. 1 the recorded individual steps of the method according to the invention.

A meandering pulse sequence with a symmetry ratio of 1: 1 is generated in the arrangement 2 from the pulses at frame rate 1. Such an arrangement with a controllable symmetry ratio is described in more detail in FIG. The meandering voltage is converted into a sinusoidal voltage by using appropriate filter elements in the switching means 3. Using a phase shifter 4 without a stop, this can be ^{converted into a sinusoidal oscillation that is arbitrarily shifted between ο and 360 0} with respect to the original control frequency. 3 shows an exemplary embodiment of an arrangement for converting a meander voltage into a sinusoidal oscillation and for phase shifting. From the phase-shifted sinusoidal oscillation obtained in this way, three sinusoidal oscillations which are phase-shifted ^{by 120 or 240 0} relative to one another can be generated by using a switching means 5, which is specified in more detail in FIG. are obtained, one of which is fed to the switching means 6 and the other to the corresponding switching means 9 and 10. In the switching means 6 there is a double-sided amplitude limitation of the sinusoidal oscillation and differentiation by a member with a small time constant. This creates a series of pulses with a steep edge and the same frequency as the control frequency, but double the number of pulses with alternating polarity. The series of pulses is fed directly to a tube belonging to a current gate circuit 8 and, after the polarity has been reversed in the switching means 7 of the second tube to the current gate circuit 8. Such a circuit of FIG. 8 is described in detail in FIG. In the output circuit of the current gate circuit there is a winding of the excitation field of the synchronous motor. The other two windings are connected to the current gates following the switching parts 9 and 10.

2 shows the generation of a meander-shaped voltage that can be regulated in terms of the symmetry ratio from a pulse-shaped. The multivibrator circuit consists of the two tubes 11 and 12. Via terminal 13, the braking grid of the first tube is subjected to a pulse-shaped voltage that becomes more negative Polarity supplied with the frequency of 50 Hz. The multivibrator maintenance generates from this a meandering voltage that is phase-locked to the control oscillation is also included the frequency of 50 Hz. By coupling via diodes 14 and 15 and those connected in series Capacitors between the anode and the control grid of the tubes can be connected directly to the anode of the two tubes, for example at terminal 16, a purely meandering voltage is removed will. The two amplitudes of the meander voltages occurring at the anode of the tube 12 are opposite to the capacitors 17 and 18 and the diode sections 19 and 20 with " Forward direction used to charge the capacitor 21. The control voltage is by setting the tap on the one connected in series to the bleeder resistors 22 and 23 Resistor 24 adjusted so that, for. B. with the desired width ratio 1: 1 of the two span

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nungsabsohnitte the on the capacitor 21 occurring Average voltage is about -2 volts. The control voltage becomes positive when the positive Half-wave is greater than the negative, and it becomes negative when the negative is greater than the positive. The two boundary lines of the meander voltage should be free of interference, i.e. H. be parallel. This is achieved by the diodes 14 and 15. At Omitting these diodes would make the meander-shaped one Voltage asymmetrical voltages superimposed, which are caused by the grid currents that occur develop. It may also be possible to omit the diodes and instead to use other limiter circuits, for example by raising the brake grille.

The control voltage appearing at the capacitor.21 is between the control grid and the cathode of the Control tube 25 placed. A voltage is tapped at the anode resistor 26 of this control tube, via the resistor 27 via the change in bias voltage of the diode 15 to change the Pre-tensioning of the tube 11 and thus to change the width ratio of the two sections the meandering tension is used. The corresponding voltage of the symmetrical part the multivibrator circuit is kept constant by the stabilizer 28.

3 shows in detail a circuit for generating a phase-shifted sinusoidal voltage from a pulse-shaped voltage. The series of pulses is fed via terminal 30 to the steamer grid of tube 31 of the EL 41 type, in the anode circuit of which there is the filter circuit consisting of inductances 32 of approximately 6 H and capacitances 33 of 0.5 to ι μ ¥ . A purely sinusoidal voltage thus arises in the primary and secondary windings of the output transformer 34. In parallel with the secondary winding, there are several series connections of resistors and capacitors, the common points of which are connected to a potentiometer 35 without a stop. The resistances used in the i? C elements fluctuate between 2.5 and 6.5 kOhm and the capacitance between 0.5 and 1.3 _; uE. For example, a layer potentiometer with eight taps can be used as the potentiometer, in which the resistance from tap to tap is 5 kOhm. By shifting the potentiometer tap 36, the phase of the sinusoidal voltage taken from the potentiometer tap can be shifted ^{between zero and 360 0 with respect to the pulse voltage supplied via the terminal 30;} their amplitude is almost constant.

FIG. 4 shows an exemplary embodiment for the switching unit indicated in FIG. 1 under 5 for generating three ^{sinusoidal voltages shifted from one another by 120 or 240 0} from a likewise sinusoidal voltage. The latter is fed via the terminal 40 to the control grid of the tube 41 of the EL 41 type, in the anode circuit of which there is an oscillating circuit 42 tuned to the frequency of the sinusoidal oscillation (50 Hz). The voltage occurring in the resonant circuit is taken off by means of a transformer. Parallel to the winding 43 of the transformer there are two series connections of resistors and capacitors, at the common point of which a phase-shifted sinusoidal voltage can be tapped. The voltage appearing at terminal 44 is in phase with the original control voltage, while the voltage appearing at terminals 45 and 46 is out of phase with the original control voltage. By changing the resistors 47 and 48 it can be achieved that the phase shift is exactly + 120 ° with respect to the applied voltage.

FIG. 5 also shows the arrangement indicated in FIGS. 1, 8 for the actual generation of the excitation field of a synchronous motor. For better clarity, the control oscillation is again recorded under 61, the meander-shaped oscillation derived therefrom under 62, and the impulses derived therefrom with great edge steepness of the same frequency but double the number of pulses with alternating polarity under 63. The last-mentioned pulses are fed once to the ignition grid of the current gate 64 and with reversed polarity to the ignition grid of the current gate 65. The anodes of the two current gates 64 and 65 of the type PL 17 or PL 57 are coupled to one another via the inductance 66. The anode voltage is supplied via the choke 67 and the center of the primary winding of the transformer. Depending on which tube has ignited, a current flows, the direction of which is indicated by the arrow 68 or 69. When the first ignition pulse arrives at the current gate 64, the tube ignites, due to the steepness of the pulse edge, essentially independent of the amplitude of the ignition pulse, as long as this SO ^{1 is} large so that the ignition voltage is reached with a safety factor. If a sinusoidal voltage were used for ignition, the instant of ignition would depend on the amplitude of the control voltage, ie an undesired phase shift would occur depending on e.g. B. from mains voltage fluctuations or pulse voltage fluctuations. In contrast, when control pulses with a steep edge are used according to the invention, the time of ignition becomes independent of changes in the mains or pulse voltage. Initially, a current indicated by the direction of arrow 68 flows. When the second ignition pulse arrives (180 ° later), which is fed to the ignition grid practically of the current gate 65, the current indicated by the arrow 69 also flows. Since it starts suddenly, a negative pulse occurs at the anode of the current gate 65, which is transmitted via the capacitor 70 and the inductance 66 to the anode of the current gate 64 and blocks it by lowering it below the operating voltage. Through this mutual coupling

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conditionally, only one of the two power gates is current-permeable. The excitation winding of the motor to be synchronized is coupled to the secondary winding of the output transformer. The natural oscillation period of the output circuit, which is caused by the capacitances 70 and all inductances, is matched to a frequency which is somewhat below the frequency of the control oscillation. The course of the current through a current gate is shown by diagram 71. Curve a shows the optimal time course of the current, curve b the course with an unfavorable dimensioning of the circuit. During the circuit, the choke 67 has the task of acting as an energy store and must be dimensioned so that the maximum of the current lies in the middle of the ignition period of a current gate, as curve α in diagram 71 shows. An incorrect dimensioning of the throttle has the consequence that the maximum is already, for example, in the first half of the ignition period, as is shown by curve b in diagram 71. The following dimensioning has proven itself:

Capacitor 70 5 to 6 μ ¥ .

Throttle 67 about 4.5 Ή

The output transformer is adapted to the power of the engine.

The present invention is not limited to that described Embodiment limited, .sondern has many different embodiments.

Claims (10)

PATENT CLAIMS: 1. Method of achieving phase lock Synchronization with any adjustable phase position between the synchronous motor of a Television film scanner and a control voltage occurring with vertical frequency, thereby characterized in that the control voltage generates pulses with steep flanks of the same frequency and these as ignition impulses of a gas discharge tube that is controlled with a grid Circuit are supplied, in whose output circuit the excitation field of the synchronous motor located. 2. The method according to claim 1, characterized in that that the control voltage is fed to a phase shifter and from the voltage taken from the phase shifter, if necessary after corresponding conversion Pulses of great steepness are generated whose flank. with the zero crossing of the dem Control oscillation taken from the phase shifter coincides. 3. The method according to claim 2, characterized in that that from the control voltage first a meandering voltage with the Symmetry ratio 1: 1 derived and · from this the sinusoidal voltage is obtained. 4. The method according to claim 1 to 3, characterized in that three sinusoidal voltages displaced ^{from one another by 120 0 are obtained from the sinusoidal voltage taken from the phase shifter.} 5. The method according to claim 1 to 4, characterized in that the steep pulses through double-sided amplitude limitation of the sinusoidal voltage and differentiation can be obtained, such that the leading edges of the steep pulses with the zero crossings of the dem Phase shifter extracted sinusoidal voltage coincide. . . · 6. Arrangement for performing the method according to claim 1 to 5, characterized in that that a non-stop phase shifter is used to phase shift the sinusoidal voltage. 7. An arrangement for carrying out the method according to claim 4 to 6, characterized in that to generate the three ^{sinusoidal voltages shifted by 120 0} from one another from a single sinusoidal voltage, the latter is fed to an amplifier tube, in the anode circuit of which is a tuned to the frequency of the Resonant circuit is located, which ^{is bridged by the series connections of: in} each case a capacitor and resistor, at the common point of which a phase-shifted voltage is tapped. 8. Arrangement according to claim 6 and 7, characterized in that the pulses with steep edge in opposite phase alternately fed to the control grids of two power gates in whose output circuit the field windings of the synchronous motor are located. 9..Arrangement according to claim, characterized in that that the anodes of the current gates are connected to one another by connecting a capacitor and an inductor in parallel are, via whose center tap the anode voltage is fed via a choke. 10. Arrangement according to claim 8 and 9, characterized in that the output circuit the current gate circuit is tuned to a frequency that is lower than, but at most is equal to the excitation frequency of the synchronous motor. Considered publications:
German patent specification No. 567 690. For this purpose 2 sheets of drawings © 609 659/172 10.5β