DE964621C - Photoelectric calibration and testing device for electricity meters - Google Patents

Description

This calibration and testing device for electricity meters There are photoelectric meter testers known, by means of which a direct measurement the angular velocities of the counter anchors of calibration meters (calibration standard) and test meters (Test item) takes place and in an instantaneous measurement on the screen of a cathode ray tube can be compared with each other by photoelectric scanning of the meter armature from the test counter and calibration counter test and calibration pulses are obtained, their frequencies are proportional to the angular velocities of the two meter anchors. To the generation For example, a linearly deflected image are the pulses of a counter supplied as image voltage to the one pair of deflection plates of the picture tube, while the Pulses from the other counter create a sawtooth deflection voltage on the other pair of plates synchronize, or for e.g. circular deflection, the deflection voltages synchronized with the pulses of one meter, while the pulses of the other Counter for the light-dark modulation of the cathode ray influence the Wehnelt cylinder. In the known devices of this type, the synchronization of the deflection voltage takes place by the counter pulses only in a range of a few percent below and above the target frequency.

Since electricity meters usually operate at certain load levels in an area of some pro- cent to a few hundred percent the nominal load can be calibrated or checked and consequently the pulse frequency increases changes in the same area are the well-known calibration devices with frequency switches provided, which allows the choice of a frequency from a number of intended frequencies allow according to which the load of the meter is to be selected. It has proved to be disadvantageous when serial calibration or testing of various meters Nominal load not all frequencies corresponding to the normal load points are available to have and thereby counters on abnormal, the existing closest frequencies having to calibrate or check the corresponding load points.

It is also a synchronizer with a relaxation generator known for linear image deflection, in which on the one hand the measuring voltage (synchronizing voltage) is largely kept away from the breakover voltage during the run-out and on the other hand the synchronization affects the termination of the return. The synchronization of the tilting circle takes place via a screen grid tube, whose screen grid during the discharge of the breakover capacitor blocked by a pulse from the breakover circuit will.

The synchronization thus takes place at the expense of the tilt amplitude. Will the synchronization range is exceeded, the charging current of the charging tube must be manually adjusted be readjusted.

The invention aims at the various disadvantages mentioned at the outset remedy. It relates to a photoelectric calibration and testing device for electricity meters with two by photoelectric scanning of a calibration meter and a test meter obtained pulse sequences, which are proportional to the angular velocities of the two counter armatures and are compared on the screen of a cathode ray tube, by the pulses coming from a counter the image modulation voltage and the pulses from the other meter represent the cathode ray tube deflection voltage influence.

The invention is intended to ensure that the influencing of the Deflection voltage over a wide pulse frequency range, preferably with a frequency ratio from 1:30, is automatically effected. The ones required to solve this problem Means are in view of the difference between the two possible deflection systems (Rectangular or circular deflection) to adapt to the circumstances. If so the device a tilt generator for linear image deflection with a synchronizing device which contains a control pentode, according to the invention the charging current is the control pentode regulated by tilting amplitude charging current feedback, whereby the Sweep frequency of the deflection voltage over the entire pulse frequency range automatically - is regulated to the pulse frequency of the counter. But if the device contains a Phase splitter for splitting the pulse voltage into two go0 phase-shifted Deflection voltages for circular image deflection are those according to the invention applied means that the go ° phase splitter by two mirror images switched phase rotating elements of certain dimensions is formed, which by their interaction results in the go ° phase splitting for each pulse frequency over the the entire pulse frequency range of the counter.

Embodiments of the invention are explained in more detail with reference to the drawing explained.

The drawing shows in Fig. I a scheme of a photoelectric Meter tester with linear image deflection, Fig. 2 is a diagram of a device with circular.er image deflection, Fig. 3 a phase rotation element.

The scheme Fig. I contains the two counter anchors ZI and Z 2, their Speed is to be compared with each other, two photocells F 1, F2 with photocell amplifiers I and II, a pulse converter III, a cathode ray oscilloscope tube IV, a Tilt generatorV and a synchronizing device VI. By a beam of light LI the edge of the counter anchor Z I, z. B. the meter to be tested, punctiform scanned and attached to the anchor marker such. B. Lines, slits or teeth, with a frequency determined by the speed of the counter armature the photocell reflects. The pulses emitted by the photocell Fi are amplified in amplifier I. This amplifier has a triode in a known arrangement VI, resistors R II, R I3, R I5 and a coupling capacitor CII. He is coupled through a capacitor C13 to the pulse converter III, which is a double triode V3, resistors R I7, R I8, R 19 and a capacitor CIg and the pulses converted into square-wave pulses by limiting the amplitude in the double triode V3. These pulses are used as the image modulation voltage across the coupling capacitor C. I6 of the vertical deflector plate P I of the cathode ray tube V4 is supplied.

The photoelectric scanning of the counter armature Z2, z. B. des Calibration or normal counter pulses obtained, which sampling is analogous to that of the counter armature Z I is carried out in the photocell amplifier II with triode V2, Resistors R 12, R I4, R I6 and capacitor C12 are amplified and through a capacitor CI4 fed to the tilt generator V, which via a capacitor CI7 the image deflection voltage on the horizontal baffle P2 of the cathode ray tube V4.

The generation of the tilting vibrations takes place as usual by means of a Gastriode V5 and by charging a breakover capacitor C I8 via a charging tube used control pentode Y6, with the breakover capacitor C 8 via the gastriode Y5 discharges.

The synchronizing device consists of a composite tube triode diode V7, a cathode resistor R 20, a voltage divider, consisting of three resistors R2I, R22, R23, and one Charging capacitor C 19. The one at the cathode the breakover voltage occurring in the gastriode (point 1) is applied to the grid of the cathode amplifier switched triode part of the composite tube V7 out. About the diode part will a positive potential is picked up at the charging capacitor C I9.

This potential is fed to point 2 of the voltage divider. The pulse frequency on the grid of the gastriode V5 is now coarser or smaller than that Sweep frequency, a forced synchronization is exerted on the sweep generator, and the breakover frequency is at first constant charging current of the breakover capacitor C I8 also larger or smaller. However, this changes the tilt amplitude and thus the positive potential across the charging capacitor C I9. The potential distribution in The voltage divider is chosen so that the potential in point 2 also increases or decreases. decreases. and in point 3 the necessary control voltage for the charging tube V6 occurs. If the positive potential in point 2 of the voltage divider is now larger or smaller, the selected potential distribution in point 3 results in the negative control voltage for the charging tube V6 smaller or larger. But that means that the charging current of the Breakover capacitor C I8 when the breakover frequency increases or decreases due to the breakdown amplitude control voltage feedback in the synchronizer also increases or decreases until the compulsory synchronization on the tilt generator by synchronizing the tilt frequency with the pulse frequency of the calibration counter Z I disappears. The one taken from point I. and deflection voltage supplied across the capacitor CI7 to the horizontal deflector plate P 2 thus has a regulated tilting frequency. This adjustment of the tilting frequency to the Pulse frequency of the calibration counter can be used in a useful range in the Frequency ratio of 1:30 can be done.

An arrangement for circular image deflection according to FIG. 2 has the following Construction. It contains the two counter anchors Zx I of the test counter and Z2 of the calibration counter, two photocells Pi, F2 with the two photocell amplifiers I and II, a broadband phase shifter III for generating two sinusoidal image deflection voltages shifted from one another by go0 and a cathode ray oscilloscope tube IV.

The light beams LI and L2 feel the edge of the counter armature ZI and Z2 and are applied to the photocells with a frequency proportional to the armature speed FI or F2 reflected. The voltage output by the photocell FI is used in the amplifier 1 and the Wehnelt cylinder of the cathode ray tube via the capacitor CI3 V3 supplied. The cathode voltage of the tube V3 is taken from a voltage divider, which is formed by two resistors R7, R 8. The Wehnelt cylinder receives besides the positive control voltage of the amplifier I from the tap at the resistor R 8 a negative reverse voltage. Due to the positive peak voltage of the test meter AC voltage, the negative reverse voltage is canceled and the cathode ray released briefly during each period.

The obtained by the photoelectric scanning of the calibration counter Z2, If possible, sinusoidal alternating voltage is amplified in amplifier II.

The transformer T located in the anode circuit of the tubes2 becomes the output voltage of the amplifier II is balanced to ground and then fed to the broadband phase shifter III, which regardless of the frequency causes gop splitting. The go0 phase-shifted from points A and B Stresses are applied to the vertical and horizontal baffles of the cathode ray tube fed.

Structure and mode of operation of the broadband phase shifter is first explained with reference to FIG. 3. A quadrupole with three RC elements and more symmetrical Input voltage according to FIG. 3 has the rating R; CI = R2 C2 = R3 C3 = Where where coo is the resonant angular frequency and RI: R2: R3 = the property, an output voltage to deliver, the size of which is frequency-independent at constant input voltage and their phase shift against the input voltage in a wide range natural logarithm of o> / w o is proportional, where (9 is the operating circle frequency represents.

The broadband phase shifter III in Fig. 2 consists of a combination of two phase shifting elements according to FIG. 3 arranged in mirror image to one another with the dimensioning RICI = R2C2-R3C3- WI: 6: 3 and R4C4 = R5C5-R6 C6C6 = 1 / # 22; R4: R5: R6 = 1: 6: 3.

With this combination you get two against at points A and B. Ground measured output voltages, their phase angle against the symmetrical input voltage are proportional to the quantities In "and in. The phase difference is therefore proportional.

# # # 2 in -ln = In WI w2 WI d. H. independent of w and only through the resonance circuit frequencies a> 1 and W 2 of the combined RC elements are determined. With go0 phase shift results for a network area in the frequency ratio 1: 30 an error of at most a few percent.

As a result of the automatic generation of the deflection voltage over the whole Pulse frequency range, both for linear and circular image diversion, it is possible to control the DUT at all Load points within a range of e.g. B.

OK to calibrate or check up to 300% nominal load.

If the test item runs with the calibration counter over the entire load range synchronously, the same position is obtained for all load points in this range Image on the cathode ray tube. If the test item and calibration counter do not run synchronously, so moves with linear deflection or rotates with circular deflection, and the faster the greater the difference in the angular velocities of the two Counter anchor is. The cathode ray tube is connected in both examples so that with plus errors (test item runs faster than calibration counter) the image to the right and in the case of minus errors (test item runs slower than calibration counter) moves to the left or turns.

Claims (2)

PATENT CLAIMS: I. Photoelectric calibration and testing device for electricity meters with two by photoelectric scanning of a calibration meter and a test meter obtained pulse sequences that correspond to the angular velocities of the two meter anchors are proportional and compared on the screen of a cathode ray tube by the pulses coming from a counter the image modulation voltage and the pulses from the other meter represent the cathode ray tube deflection voltage influence, and a tilt generator for linear image deflection, with a synchronization device, which contains a control pentode, characterized in that the charging current of the Control pentode is controlled by tilting amplitude charging current feedback, whereby the Sweep frequency of the deflection voltage over the entire pulse frequency range automatically is regulated to the pulse frequency of the counter. 2. Photoelectric calibration and testing device for electricity meters with two by light-electrical scanning of a calibration meter and a test meter obtained pulse sequences that correspond to the angular velocities of the two meter anchors are proportional and compared on the screen of a cathode ray tube by the pulses coming from a counter the image modulation voltage and the pulses from the other meter represent the cathode ray tube deflection voltage influence, and a go ° phase splitter for circular image deflection, characterized in that the phase splitter by two mirror images switched phase rotating elements of certain dimensions is formed, which by their interaction results in the goo phase split for each pulse frequency over the Entire pulse frequency range of the counter automatically effected Publications: German patents No. 86o 516, 9I3 078.