DE864421C - Device for speed comparison measurement on electricity meters - Google Patents

Description

Device for speed comparison measurement on electricity meters Addendum to patent 841454 The subject of patent 849 454 is a device for Speed comparison measurement on counters, which is characterized in that the speed a normal counter and the counter to be set by photoelectric, capacitive or inductive scanning in electrical pulses with speed dependent Frequency is converted after demodulation in a frequency comparison device are converted into voltage drops, which are fed to a suitable for direct error reading Measuring instrument are created.

According to one embodiment of the main patent, the frequency comparison each of the two frequencies is applied to the grid of two tubes in antiphase, the are alternately made conductive by each half-wave and to recharge a capacitor serve, whose recharging currents cause voltage drops at a Vi7iderstand, which are connected to a display instrument in counter-connection.

With this circuit, the display is heavily dependent on the amplitude the input voltage. But since a constancy of the amplitude bci one by photoelectric or capacitive or inductive scanning of the counter generated and then amplified Input voltage cannot be expected, the invention provides a circuit of the frequency comparison device that does not require this constancy. The invention consists in that for frequency comparison of one half-wave each of the two frequencies made a tube conductive and thereby the charging of one Capacitor in the anode circuit of this tube and through the other Half-wave of each of the two frequencies blocked the tube and the discharge of the capacitor is brought about via a resistor, and that the charging and / or discharging currents be evaluated to measure the frequency difference.

In the drawing, Fig. I is an explanatory sketch; Fig. 2 shows a block diagram; Fig. 3 shows an embodiment according to the invention dar; Fig. 4 shows a further embodiment.

Corresponding parts are identified by the same in the individual figures Provided with reference numerals.

In the explanatory sketch (Fig. I) is only the left half of the circuit shown; the right half is constructed in a corresponding way. The voltage a voltage source U is alternated in the cycle of the frequency to be measured closed and open switch Ro2 alternately to one of a capacitor C and a parallel to this - resistance R existing circle placed, which the measuring instrument J contains. The negative half-cycle closes the switch Ro2, the capacitor C charges on the voltage U, and the charging current surge is in the instrument J for Display brought. The positive half-cycle opens the switch Ro2, the capacitor C discharges through resistor R, and the surge of discharge is also through the instrument J measured. The instrument J must therefore be an AC instrument be. The displayed current is proportional to the frequency up to certain limits.

In the basic circuit (Fig. 2) are both halves of the circuit shown, namely in the left half that generated by a normal counter Frequency fi and in the right half that generated by the counter to be set Frequency converted into charging and / or discharging currents. The Ro2 tube is a control tube Rol connected upstream, as well as the tube Ro2 'a control tube red'. The anode voltage a stabilizer st is removed for all tubes. Through the cross flow of the Stabilizer and its cathode resistance, the tube Rol receives a negative grid bias of about 6 V. The tube Rol is therefore blocked at an anode voltage of 100 V. The tube Ro2 is open, and a current flows through the resistor R1, which corresponds to the voltage drop generated across it charges the capacitor C1. The charging current will measured in the instrument J1. Will now be a positive on the grid of the tube Rol Voltage half-wave placed, which must be greater than 6 V, then the tube Ro, opens. The grid of the tube Ro2 is made negative by its anode current to such an extent that this tube is blocked.

The voltage drop across resistor R1 disappears, and the capacitor C1 discharges through instrument J1 and resistor R1. In corresponding Way is of the frequency f2 from the capacitor C2, the resistor R2 and affects the existing capacitor circuit of the instrument J2.

A direct current instrument in Graetz circuit is expediently used as the measuring instrument chosen for each capacitor circuit. The difference between the charging and discharging currents of the two Circles can no longer be measured in the usual way with a voltmeter.

If you still want to measure the difference, then the torques are subtract the two instruments, d. H. you have to juxtapose two instrument coils let act on an axis. You can also put a thermostat in each circuit set and measure the difference between the generated thermal voltages.

With differential switching one must take a precaution that causes the display instrument to be switched off when a frequency and thus a charging current fails. This is achieved by a two-leg relay, of which One winding each lies in a charging or discharging circuit. The rivers work against each other; if a current fails or if it exceeds a certain size, the resulting one brings Flow the relay to respond and a contact in the circuit of the display instrument opens so that it cannot be overloaded.

If you always want to use the same pitch of the display instrument, then a corresponding capacitor must be used for the differential measurement of each frequency be assigned in order to always receive the same charging current. As a result, one can only compare two frequencies at fixed points or the deviation from each other determine.

It is more useful to have a Kreuzspulmeßmerk with four free ends in to close the two capacitor circuits, since with this instrument the quotient the charging and discharging currents or the frequencies detected and thus an error curve not point by point, as before, but can record continuously.

Such an arrangement is in the embodiment of Fig. 3 is provided, in which the structure of the circuit is basically the same as according to the basic circuit diagram in FIG. 2.

In the capacitor circuits are in the diagonal of the Graetz circuit the direct current instruments J1 or J2 and the terminals K1 or K2 for the connection of a arranged cross-coil instrument, not shown. Parallel to the diagonal are each a smoothing capacitor GC or GC 'and the by means of the selector switch S, or S, 'switchable resistors W1, W2 or W1', W2, for setting the sensitivity of the measuring instruments and thus for setting various error measuring ranges.

Instead of the fixed capacitors C1 and C2 in FIG. 2, there is in each Capacitor circuit a set of switches that can be switched on by a selector switch S1 or 52 Capacitors C1 to C5 or C1 to C8 'are provided, of which the same numbered Capacitors of both circuits, e.g. B. C5 and C3 ,, are the same size.

The capacitors of each set are also stepped so that an equal current in the instrument circuit at all load points (or frequencies) can be set by setting the associated selector switch accordingly. to that purpose are the capacitors are graded so that the capacitance inversely proportional to the frequency to be measured changed by the selector switch can be, e.g. B. at I5 Hz 0.8 pF, at 30 Hz 0.4 pF, at 60 Hz 0.2 suF, at I20 Hz 0, I pF etc.

With a selector switch Ss with the positions »synchronous« and »balanced load« the device can optionally be used to test counters according to the synchronous or Synchronous method or can be used for testing according to the uniform load method.

When checking according to the synchronous method, which is known to be the normal counter and the meter to be tested have the same speed during zero adjustment and thus produce the same frequency during photoelectric scanning, the selector switch is S3 set to the "synchronous" position and the two capacitor circuits are thereupon by means of the selector switch S and S2 for the individual load points one after the other switch on capacitors with the same number.

When testing according to the uniform load method, it is at all load points of the meter to be tested the speed of the normal meter and thus also its scanned Frequency constant. The selector switch S3 is set to the position "equal load" set and thereby a corresponding fixed capacitor FC in the normal circuit switched on. Therefore, a constant one is obtained for all load points of the test object Current in the normal circuit. To now look at the various load points for the test circuit an equal current as in the normal circuit and thus a zero display for all To obtain load points, a corresponding capacitor must be used in the test circuit for each load point be assigned by means of the selector switch S2.

Since the normal counter showed i 01o errors with 100% load in this case, the error of the test item can be read off directly. One The fixed capacitor FC is increased by I O / o by switching on an additional capacitor ZC by means of switch 54 gives an error display of I ° / o and thereby enables checking the display device.

The facility is also capable of testing counters of various constants using one and the same normal counter. The current in the instruments J1 or J is J = f.C.U.K, where with f the frequency, with C the capacitance, with U the effective charging voltage and with K the instrument constant is designated. From this it can be seen that, if one uses the same normal counter, counters of different constants want to calibrate, you can change one of the sizes C, U or K, either in the normal circle or in the test group or in both.

For example, if the change is made in the test group, so result The following possibilities arise: a) The new test meter has a higher nominal speed than a previously checked meter. The sampled frequency at nominal load is greater, the capacitor in the test circuit is chosen to be correspondingly smaller in order to reduce the current in J2 to be brought to the same size as before. Instead, you can only have one Display part of the charge current or discharge current by going to the instrument J2 connects a resistor in parallel. b) The new test meter has a smaller one Rated speed. As a result, the sampled frequency at nominal load is lower. Man can increase the effective charging voltage to ensure the same current in the instrument J2, for example by using a voltage divider across the stabilizer or by changing the resistance R2.

The device is calibrated using the potentiometer P. The two inputs are switched to the normal frequency in parallel by the switch D and D ' f, and set the instrument deflection to zero by turning P.

4 shows a circuit which can be achieved by using Grid-controlled gas or vapor discharge vessels (thyratrons) are permitted, larger ones To achieve charging and discharging currents of the measuring capacitors C1 and C2 than with the embodiments described above. The frequency sampled by the normal counter is back to the grid of a control tube Rol and that of the meter under test The sampled frequency f2 is applied to the grid of a control tube Ro1. The tubes Ro2 and Wo2 ', whose grids are connected to the anodes of the control tubes Rol and

Ro1, are connected, in this case are grid-controlled gas or Vapor discharge vessels in series with the measuring capacitors C or C2 and the resistors R or R2 lying parallel to this are parallel to the total voltage a stabilizer are switched. The measuring capacitors C1 and C2 are over the interrupters Ro2 and Ro2 'are charged very quickly.

Shortly before the end of charging, the associated switching tube goes out, since the cathode has a very high positive potential in relation to its grid. The capacitors discharge through the resistors R or R2. The charge and discharge currents are used by measuring instruments J1 and J2 (thermo converter or rectifier instruments) measured.

If you switch the two windings in place of the instruments J and J2 of a cross-coil instrument, this shows the quotient of the two directly Capacitor currents.

The measuring instruments J or J2 must be placed between the capacitors C, or C2 and the points B1 and B2 are switched so that they the current that through the resistors R1 or R2 flows when the switching tube is ignited, do not measure it.

With the same available stabilized DC voltage and even with the same effort, this circuit delivers about 3.5 times as large Measuring currents like the circuit according to the exemplary embodiments according to FIGS. 2 and 3, because once there are the measuring circuits consisting of the switching tubes and the measuring capacitors parallel to the total voltage of the stabilizer and also the internal voltage drop of an ignited grid-controlled gas discharge tube is much smaller than the internal voltage drop of an electron tube Ro2 in the circuit according to FIG. 2 or 3.

When using an additional small stabilizer for the two Control tubes Rol and Ro, 'can one increases the currents obtained 4.8 times.

The instrument Js measures the sum of the two currents through the instruments J1 and J2 and is therefore a measure for ei and f2 which may be in another context may be of interest.

PATEP {TANSPRÜCHE: I. Device for speed comparison measurement at Electricity meters, where the speed of a normal meter and the one to be set Counter by photoelectric, capacitive or inductive scanning into electrical Pulses with a frequency dependent on the speed are converted and used in a frequency comparator transformed into currents or voltage drops applied to a measuring instrument according to patent 849 454, characterized in that for frequency comparison of the one Half-wave of each of the two frequencies made a tube (Ro2 and Ro2,) conductive and thereby the charging of a capacitor (C1 or C2) in the anode circuit of this Tube and through the other half-wave each of the two frequencies the tube (Ro2 and Ro2 ') blocked and the discharge of the capacitor (C1 or C2) takes place via a resistor (R1 or R2) and. that the charge and / or discharge currents to measure the frequency difference.

Claims (1)

2. Device according to claim 1, characterized in that each of the two tubes (Ro2, Ro2 ') with their grid on the anode of an upstream Tube (wo1, red '), on whose negatively biased grid the received frequency lies (fi. f2) is applied. 3. Device according to claim I and 2, characterized in that a parallel connection of a capacitor (C1, C2) with a discharge resistor (R1, R2) in series with a grid-controlled vapor or gas discharge vessel (Ro ,, Ro2) and the measuring circles formed in this way for the two frequencies to be compared parallel to the total voltage of a stabilizer (St) (Fig. 4). 4. Device according to claim I to 3, characterized in that the charging and discharging currents caused by the two frequencies over each one Display instrument (J1. J2) are directed. 5. Device according to claim I to 4, characterized in that for measuring the difference between the charging and discharging currents in the two capacitor circuits from each circle an instrument coil is influenced, which against each other on a common axis act. 6. Device according to claim I to 4, characterized in that In each condenser circuit a thermal converter is connected and the difference between the generated thermal voltage is measured. 7. Device according to claim I to 4, characterized in that to measure the quotient of the charge and discharge currents, the rectified currents of the two capacitor circuits passed over one coil each of a cross-coil measuring mechanism are. 8. Device according to Claim I and 4 to 7, characterized in that that especially with differential switching a two-leg relay with one each other counteracting winding in each of the two capacitor circuits, the shutdown of the indicating instrument if one of the two is to be compared with one another Frequencies and thus the charging current in one of the capacitor circuits fails or exceeds a certain value. 9. Device according to Claim I and 5 to 7, characterized in that that to adjust the measuring device the two inputs of the measuring device by means of a Changeover switch (D, D 'in Fig. 3) placed in parallel with the setpoint frequency (f,) and through Adjustment of a potentiometer connected between the two resistors (R1, R2) (P) the meter is zeroed. IO. Device according to Claims 1 and 5 to 7, characterized in that that the sensitivity of the or the display instruments by means of selector switches (56, S, 'in Fig. 3) to the measuring instrument branches in both capacitor circuits equal resistances (W1, W2 or W1 ,, W2,) parallel are switched. II. Device according to Claims 1 to Io, characterized in that a set of capacitors graded in the same way in each of the two capacitor circuits (C1 to C8 or C, 'to cs, in Fig. 3) are arranged and the gradation in such a way is that by means of a selector switch (ski, S2) the capacitance of the capacitors is reversed can be set proportionally to the load points or frequencies to be measured. I2. Device according to claim II, characterized in that for Testing of counters according to the synchronous or synchronous process in both capacitor circuits Capacitors of the same size corresponding to the frequency to be measured are switched on are. 13. Device according to claim 11, characterized in that for Testing of meters according to the equal load method in the capacitor circuit of the normal meter a fixed capacitor (FC) and by means of a changeover switch (53) for all load points into the capacitor circuit of the meter to be tested for the frequency to be measured corresponding capacitor is switched on. 14. Device according to claim I3, characterized in that for Check of the display device of the fixed capacitor (F C) by means of an additional capacitor (ZC) is changeable. 15. Device according to claim 1 to I4, characterized in that for checking counters with different constants either in the normal circle or The charging capacitor can be changed accordingly in the test item circuit or in both circuits is. I6. Device according to Claims 1 to 14, characterized in that for testing meters with different constants either in Normal circuit or in the test object circuit or in both circuits the charging voltage accordingly is changeable. 17. Device according to claim 1 to I4, characterized in that for checking counters with different constants either in the normal circle or in the test item circle or in both circles the constant of a measuring instrument branch can be changed accordingly by series or shunt resistors.