DE1298456B - Switching arrangement with zero instrument for pulse frequency comparison measurement, especially for checking the accuracy of clocks - Google Patents

Description

The present invention relates to a zero instrument switch assembly for pulse frequency comparison measurement, especially for checking the rate accuracy of clocks, in which the beat noises converted into a pulse train of the Test watch an electronic switch together with a predetermined pulse sequence control so that with the same frequency of the pulse trains on one as a zero display DC voltage instrument to be used a standing display, with unequal Frequency a non-uniform oscillating display occurs.

Switching arrangements are known in which two thyratron tubes are connected so that each tube removes the anode voltage from the other when it is ignited by a pulse given to the control grid. Because of If one tube is ignited, the anode voltage of the other drops below the operating voltage, the current in this tube is extinguished. The control grid of one tube will be the clock pulse of the test clock, which is obtained by means of a microphone and amplifier the clock pulse pulses to the control grid of the other tube in the same way a comparison clock, which represent the specified pulse sequence, fed. By Both tubes now alternately anode current, which is limited by anode resistances will. There is an ammeter in the anode circuit of one of the two tubes, which a capacitor is connected in parallel, or it is parallel to the anode resistor a voltmeter and a capacitor.

It is also known to extract the predetermined pulse train from the subdivided Frequency of a tuning fork or quartz generator serving as a comparison standard produce.

Electronic switches with double triodes in two are also known stable positions, which are also controlled alternately by two pulse trains. There is also an ammeter in the anode circuit of one triode a capacitor connected in parallel.

In another known embodiment of an electronic switch only one 'ihyratron tube is used. With this switch, the anode current also measured and by the positive clock pulse from the test clock on the control grid ignited. The anode current is extinguished by negative impulses from the comparison clock originate at the anode of the tube.

In these switching arrangements with a zero instrument, the anode current switched on by the impulses of a test gauge and by the next one in time The pulse of the specified pulse sequence is deleted again. The anode current increases in; Moment of ignition to a certain maximum value and then falls at Delete back to zero. So there are constant square-wave current pulses formed, with the null instrument lying in the circuit being the one that is being formed Average value of current pulse duration and pulse pause with constant pulse height indicates. If there is now a frequency deviation between the two pulse trains, it changes Depending on their size, the pulse width changes more or less quickly. At the zero instrument a pendulous display can then be observed. The speed of change of the pointer deflection is a measure of the frequency or Rate deviation of the test clock, while the direction of the pointer movement reveals the sign of the deviation.

A disadvantage of these known switching arrangements with a zero instrument is that the frequency of the given pulse train is equal to the pulse train frequency the test clock at gear -f- must be zero. Small deviations of the test from the course -I- are therefore only zero after a long period of observation of the zero instrument to investigate. If both pulse trains also coincide in time, results It takes a long time to see another rash on the zero instrument is.

A double or triple frequency of the given pulse train results in double or triple the speed of the pointer movement, but at the same time there is also a reduction in the displayed current. The longest Occurring pulse duration of the switched current is in relation to the switching pause always smaller, the higher the frequency of the given pulse train becomes. While of the switching pauses is also the internal resistance of the ammeter or the resulting Resistance from the anode and internal resistance of the voltmeter as discharge resistance of the capacitor is effective. So it is not possible to go through a much higher lying frequency of the given pulse sequence for all common clock strikes tester to be used, which allows small rate deviations to be recognized quickly, with to build one of the known switching arrangements.

The object of the present invention is to address the disadvantages outlined to eliminate. According to the invention, this is the case at the outset in the case of a switching arrangement mentioned type achieved in that by the predetermined pulse train, the frequency is a high, integer multiple of the frequency of the clock pulse, a Pulse generator is controlled, the pulses are shaped so that they are on the one hand to extinguish, on the other hand to regulate the strength of the clock pulse switched on current in the electronic switch depending on the duty cycle are used with continuously falling instantaneous values, and that from the current strength voltage level derived at the moment of switching on the pointer deflection of a DC voltage measuring device determined. Here there is the electronic switch essentially consisting of a switching tube and a flow control tube.

An exemplary embodiment of the invention should be based on the drawings and the mode of operation will be explained in more detail. It shows F i g. 1 is a circuit diagram of the Switching arrangement, F i g. 2 and 3 show the voltage curve over time in the switching arrangement.

The course of the test clock is shown in FIG. 1 from the sequence of the clock striking noises by means of microphone 1 and a switching group 2, which consists of an amplifier with the following Thyratron stage, is converted into a pulse train in a known manner. the predetermined pulse train that z. B. from the divided frequency of a quartz generator is obtained, controls applied in point A, a known, blocked Breakover voltage generator, which consists of the charging resistor 3, the charging capacitor 4 and the tilting tube 5 consists. In the cathode line of the tilt tube lies here, differently from the usual circuit of a breakover voltage generator, the low-resistance primary winding of a small transformer 6. The secondary winding lies in the grid line of a triode 7, which in the further switching arrangement as Flow control tube is used. The control grid of this tube is also via a capacitor connected to the wiper of a potentiometer 8. In series with the triode and the anode resistor 9 is connected to a Tyratron tube 10 as a current gate. The control grid this tube receives a negative bias and is using a capacitor coupled to the output of switching group 2, which is assigned to the test gauge. Parallel to the anode resistor 9 is a charging capacitor 11 with one in its connecting line located diode 12. The charging capacitor is a moving coil instrument 13 in voltmeter circuit and a resistor combination connected in parallel as a controllable shunt 14.

The control grid of the flow control tube 7 are constantly positive Sawtooth pulses supplied by the breakover voltage generator. The working point of this tube is placed in the lower part of the tube characteristic curve by a negative bias. The sawtooth pulses are on the wiper of the potentiometer 8, which is in the negative Charge line of the charging capacitor 4 is removed. This arrangement will achieved that the sawtooth pulses, which are otherwise known to be taken from the charging capacitor and have a steep trailing edge, can be reversed as a mirror image. Sawtooth pulses with a steep leading edge are required to solve the task at hand. With each ignition of the tilt tube 5 are in the secondary winding through the over the primary winding of the transformer 6 flowing discharge current each a high positive and induces a negative voltage pulse. In a known way it is now possible completely suppress one of these impulses by placing a resistor in parallel is switched to the primary winding. Through a capacitor on the secondary winding the remaining impulses can be extended a little. These impulses are through Corresponding polarity of the secondary winding to the control grid of the current control tube 7 supplied as negative blocking pulses. These blocking pulses and the positive sawtooth pulses at the control grid, however, initially have no effect because of the in the anode circuit located locked thyratron tube 10, the anode current flow is interrupted. if Now a watch is placed on the microphone 1, generates the clock striking noise on Control grid of the thyratron tube 10 a positive ignition pulse. The now through both Tubes and the anode resistor 9 anode current flowing through the part of the Sawtooth pulse on the control grid of the flow control tube 7 affects the between the time of ignition of the thyratron tube 10 and the subsequent time the ignition of the tilt tube 5 is. The voltage pulse arising at the anode resistor 9, which has the shape of the effective part of the sawtooth pulse, charges via the diode 12 the charging capacitor 11. After the sawtooth pulse has subsided, the the ignition of the tilt tube 5 on the control grid of the flow control tube 7 is negative Blocking pulse given, which interrupts the anode current with certainty. At this moment the negative bias voltage on the control grid of the thyratron tube 10 is also restored effective until the next clock pulse initiates another ignition. the Charge the capacitor, the voltage of which, after a few ignitions, corresponds to the level of the voltage the leading edges of the sawtooth pulses tapped at the anode resistor 9 can during the time of the anode current interruption do not flow back via the anode resistor 9, since the diode 12 blocks in this direction. The discharge takes place slowly via the high-resistance voltage measuring instrument 13 (zero instrument) and partly via the also high-resistance adjustable shunt 14.

The possibility of using the new switching arrangement in clocks with different beat numbers depends on the frequency of the given pulse train. The pulse numbers of the test gauges must be an integer in the number of pulses specified Be divisible pulse train. For example, it is possible to set a pulse count of 45 to 180 pulses per second to be selected. 180 pulses per second can be used here can be seen as the upper limit for watches with mechanically driven rate regulators. With a higher number of impulses, the scattering of the clock strike impulses has an effect due to the uneven occurrence of the clock striking noises, disadvantageous.

F i g. 2 shows the predetermined pulse sequence of 45 labeled N Pulses per second. The pulse sequence of a test clock is denoted by X, which pro Second makes five beats. This is followed by the recordings of the voltage curve on Control grid Ug 1 of the current control tube 7, the tapped voltage pulses UR " at the external resistance 9 and the voltage Uk at the charging capacitor 11, which is determined by the voltage measuring instrument 13 is displayed.

F i g. 3 also shows the predetermined pulse sequence of 45 pulses per second, denoted by N. The pulse sequence X of the test gauge is shown here shifted by about 0.01 seconds. Such a shift could occur, for example, in the event of a rate deviation of the test clock of one second per day in 14 minutes if the rate deviation of the clock would not change during this time. The pulse width and height of the effective part of the sawtooth-shaped control pulses Ugl, which is shown in dashed lines in both figures, on the control grid of the flow control tube 7 have been reduced by about half in this example. The height of the leading edge of the voltage pulses UR ″ tapped at the anode resistor 9, which corresponds to the height of the voltage measured on the charging capacitor 11 , has also decreased by about half the characteristic of the triode 7 is not taken into account.

The pulse duration of a sawtooth pulse from the breakover voltage generator is 1/45 of a second in this example. In the case of a clock with 5 beats per second, the charging capacitor 11 is supplied with a charging pulse after every 1/5 second, the pulse duration of which can be from 0 to 1/45 of a second. The longer the duration of the charging pulse, the higher its leading edge. The duration and thus the height of the leading edge of a charging pulse is dependent on the phase position of the clock pulse to the pulses of the predetermined pulse sequence on the control grid of the tilting tube 5. The level of the charging voltage on the charging capacitor 11 is not dependent on the duration of the charging pulses and the switching pause in the switching arrangement according to the invention, but the charging voltage corresponds to the voltage level of the leading edge of the voltage pulse tapped at the anode resistor 9 at the moment the thyratron tube 10 is ignited. During the switching pauses, there is only a very slight discharge due to the high discharge resistance, which is formed from the internal resistance of the voltage measuring instrument 13 and the controllable shunt 14.

By increasing the frequency of the predetermined pulse sequence, small rate deviations of the test watch can be recognized even more quickly from the deflection of the voltage measuring instrument 13. The adjustable shunt 14 can also influence the smoothing effect of the charging capacitor 11 and the most favorable adjustment can be achieved with other clock beats, so that a uniform pointer movement on the voltage measuring instrument 13 can always be observed with small rate deviations.

This new switching arrangement can now be used advantageously as a zero display device for watch testers, in which the continuously controllable predetermined pulse sequence at the measurement must be matched to the pulse sequence of the test clock, find application.

Claims (7)

Claims: 1. Switching arrangement with zero instrument for pulse frequency comparison measurement, especially for checking the accuracy of clocks in which the in a pulse train converted impact noises of the test gauge together with a predetermined pulse sequence control an electronic switch so that the pulse trains are at the same frequency on a DC voltage instrument to be used as a zero display, a stationary Display, if the frequency is not the same, there is a non-uniform oscillating display, characterized in that by the predetermined pulse sequence, the frequency of which is a high integer multiple of the clock pulse pulse frequency, a pulse generator is controlled, the impulses of which are shaped so that on the one hand they are used for erasing, on the other hand to regulate the strength of the duich.die Uhrenschlagimzulse switched on Current in the electronic switch depending on the duty cycle with steady falling instantaneous values are used, and that the current strength im At the moment of switching on the voltage level derived the pointer deflection DC voltage measuring device (13) determined. 2. Switching arrangement according to claim 1, characterized in that the electronic switch consists of a triode (7) serving as a current control tube with an anode resistor (9) and a blocked thyratron tube (10) connected in series with this. 3. Switching arrangement according to claims 1 and 2, characterized in that on the control grid of the triode (7), whose operating point is suitably placed by a negative bias in the lower part of the tube characteristic, constantly positive sawtooth pulses with a steep leading edge and after the decay of one Each sawtooth pulse a steep negative blocking pulse is given, while the control grid of the thyratron tube (10) the clock pulse pulses of the test clock are fed as positive ignition pulses. 4. Switching arrangement according to claims 1 and 3, characterized in that that the positive sawtooth pulses on a potentiometer (8), which is in the negative Charging line of a breakover voltage generator is generated by the specified pulse sequence is controlled, is tapped. 5. Switching arrangement according to claims 3 and 4, characterized in that the negative blocking pulses of the secondary winding one Transformer (6), the low-resistance primary winding of which in the cathode line of the The tilt tube (5) of the tilt voltage generator is removed. 6. Switching arrangement according to claims 3, 4 and 5, characterized in that the size of the anode current and thus also the level of the voltage drop across the anode resistor (9) are determined by the part of the sawtooth pulse of the breakover voltage generator between the time of one of the test clock initiated ignition of the thyratron tube (10) and the subsequent point in time of the ignition of the tilt tube (5). 7. Circuit arrangement according to claims 1 and 9, characterized in that the sawtooth-shaped voltage pulses generated at the anode resistor (9) are fed via a diode (12) to a charging capacitor (11), the charge of which is slowly passed via a voltage measuring device ( 13) and an adjustable shunt resistor (14) can flow off.