DE711556C - Arrangement to improve the setting in compensation measuring devices with automatic adjustment - Google Patents

Description

Arrangement for improving the setting in compensation measuring devices with automatic adjustment The present invention relates to compensation measuring devices with automatic adjustment, in which the adjustment is carried out by means of a so-called zero motor takes place, which on the one hand adjusts an adjustment means and on the other hand with a Device for displaying or marking the measured variable is coupled. So that Display or writing device as possible without disturbing oscillations accordingly adjusts the respective value of the measuring devices, the zero motor is usually with provided a braking device, which is preferably carried out as eddy current braking is. If you z. B. as a zero motor built in the manner of a counting drive If an induction motor is used, its drive pulley rotates in the field as a force Permanent magnets in order to have a dampening effect on the vibrations. Will If a moving-coil measuring mechanism is used as a zero motor, the damping one is usually sufficient Effect of the movement of the coil frame in the field of the permanent magnet.

On the other hand, to dampen the vibrations, a so-called use elastic return, e.g. B. by means of a capacitor current surges are generated, which act in the sense of reducing the disturbing oscillations.

These means, which are known per se, can each be measured in such a way that that a sufficiently rapid and essentially oscillation-free adjustment takes place. But if the current or voltage acting on the test object is within wide limits is controllable, they can act in the sense of a damping middle are only dimensioned appropriately for a certain value of the current strength or voltage, so that the setting for other values of the current strength acting on the test object or tension is unsatisfactory. In such cases, you can use any bit Values of this current strength or voltage are equally good setting according to the invention achieve by such a design of the compensation device that the zero motor with increasing current or voltage on the test object inevitably in the sense of a Reduction of the rotational speed is influenced.

In order to influence the rotational speed of the zero motor, an known way z. B. a braking can be used by the on the test object Acting current strength or voltage would have to be controlled. To this end, could For example, an electromagnetically influenced friction brake can be used, however, one that depends on the current strength or voltage in question is more expedient Eddy current braking, with the movable member of the null motor being a conductive one Body, in particular a disk, which moves in a magnetic field, which is excited by a direct current, the strength of which is different from that at the measuring object Amperage or voltage is dependent. If you have a so-called elastic return is used, one can use suitable means to reduce the effect of the recycling in the desired Change the sense depending on the current and voltage effective at the measuring object, so could z. B. the capacity of a capacitor used for this purpose on electromagnetic Ways are influenced by the current or voltage in question.

Another means of influencing the speed of rotation of a Electric motor is and is an effective resistor in the motor circuit Means known to the amount of such resistance depending on a to change electrical current or voltage. It could be for the present Purpose in the motor circuit z. B. arranged a pressure-sensitive carbon resistor the pressure is influenced electromagnetically in the desired sense. Instead, however, a temperature-sensitive resistor can also be used, z. B. a thermistor, which by one of the effective current on the test object or voltage-dependent current is heated.

As a rule, with compensation devices with automatic Adjustment of the zero motor fed by an amplifier. In this case, according to According to the invention, the gain of the amplifier as a function of that on the test object effective current or voltage can be influenced. Such means are also on known.

If you z. B. in an AC compensation circuit a Tube amplifier used to feed the null motor, so it can be connected to the supply voltage a rectifier arrangement can be connected, which biases one in the Affected amplifier arranged preamplifier tube. If you use a magnetic one Amplifier with so-called magnetic feedback, this can be dependent on the current strength or voltage effective at the measuring object can be influenced.

In the drawing, some circuit diagrams are shown, the exemplary embodiments of the subject matter of the invention. 1 shows a device for testing of current transformers for repositioning and angle errors at different currents, using two zero motors built in the manner of induction counter drives will each control a sliding contact as adjustment means.

Fig. 2 illustrates a device for measuring the capacitance and the Dissipation factor of capacitor-like objects at different voltages, The calibration is carried out using a double electrodynamometer.

Fig. 3 shows an arrangement for the changes in a current dependent Resistance to the operating voltage, with a zero motor connected to a magnetic Amplifier connected moving coil measuring mechanism is used.

In Fig. I, the primary winding is on two conductors of a three-phase network I. 2 connected to a transformer, the secondary winding 3 of which by means of a displaceable Tap contact 4 can be regulated so that the secondary current strength to be read on an ammeter 5 J can be changed within wide limits. This flows through in series connection the primary windings 6 and 7 of the current converter to be tested and of a comparison converter. The secondary windings 8 and g of the two converters form the two differential circuits an alternating current differential circuit, the secondary winding 8 of the to be tested Converter via a collar 10 and the secondary winding 9 of the comparison converter the primary winding of an auxiliary current transformer 1 1 is closed.

A resistor 12 is located in the zero branch of the differential circuit.

The secondary winding of the auxiliary converter I 1 feeds the primary winding a mutual inductance I3 and a resistor 14, at whose Clamps a slip wire I5 is connected. To the secondary winding of the mutual inductance I3 is a second slip wire via a resistor 16 and a parallel capacitor I7 I8 connected. The movable tap contacts 19 and 20 of the sliding wires 15 and I8 are connected to the terminals of resistor 12. The slip wires are provided with center taps connected to the input terminals 21 of an amplifier 22 are connected, which by means of special terminals 23 from the network I is fed.

The movable tap contacts 19 and 20 are worm gear 24 or 25 driven by induction counter measuring works, the drive pulleys with 26 and 27 are both. The voltage windings 28 and 29 of the two meter drives are via a three-phase connected to the network I phase regulator 30 with two fed in the phase by 900 mutually shifted currents, while the current windings 31 and 32 connected in series to the output terminals 33 of the amplifier 22 are.

To now independently of the by moving the tapping contact 4 current intensity to be regulated 1 a swing-free setting of the pick-off contacts I9 and 20 are obtained according to the invention, electromagnets 34 and 35 as brake magnets provided for the drive pulley 26 or 27 of the zero motors, their excitation windings 36 and 37 are fed by a rectifier arrangement 38, which via a series resistor 38 'is connected to the part of the secondary winding 3 tapped by the contact 4 is.

The measuring device described acts as is known in such a way that the alternating voltage prevailing at the resistor 12 through the voltage from the parts 13 up to 20 existing complex compensators automatically in two components is decomposed that the deflection angle ch and a2 of the tap contacts 19 and 20 dem Translation or

Correspond to the angle error of the current transformer to be tested.

If now, by moving the tap 4, the current strength J is increased at the device under test, the output current intensity J 'of the rectifier arrangement also increases 38 and thus the strength of the magnetic fields in the electromagnetic cores 34 and 35. As a result the speed of rotation of the zero motors decreases accordingly, so that it is through a suitable dimensioning of the field windings 36 and 37 is possible with any Values of the current intensity J effective at the test object are essentially equally good To achieve the setting of the pick-off contacts I9 and 20.

In the arrangement shown in FIG. 2, one is connected to two conductors Three-phase network 1 also connected to the primary winding 2 of a transformer, whose secondary winding 3 is provided with a displaceable tap 4. Through this the low-voltage winding 39 of a voltage converter Ao with a wide Limits of variable primary voltage U, fed. As a result, the High-voltage winding 41 of the voltage converter 40 is also within wide limits, z. B. between 10 and 100 01o of the nominal value of the operating voltage, adjustable secondary voltage U.2.

This is used to feed a bridge circuit that is in a bridge branch the measurement object, z. B. a capacitor 42 in an adjacent bridge arms a comparison capacitor 43 and resistors 44 in the remaining bridge branches and 45 contains.

A circuit is connected to the diagonal voltage Uf of the bridge circuit connected, the two resistors 46 and 47 and the input circuit 48 of a tube amplifier 49 contains. The resistor 46 is connected to a series resistor 50 and an inductor 51 the moving coil 52 is connected to an electrodynamic Mefiwerkes, which is located in the Fields of a fixed coil 53 moved. In this case, there is a parallel to the resistor 46 Capacitor 54. The resistor 47 is connected to a series resistor 55 and another Resistor 56 together with parallel capacitor 57, the moving coil 58 of a second electrodynamic Measuring mechanism connected, which moves in the field of a fixed coil 59. The firm ones Coils 53 and 59 are connected to the resistor 60 together with a parallel capacitor 6t Niederspannungswicl; lung62 of a normal voltage converter 63 connected, whose High-voltage winding 64 is connected to the supply voltage U of the bridge circuit.

With the spinning coils 52 and 58, the spinning coils 65 and 66 are of two, respectively Electrodynamic directional measuring units mechanically coupled, whereby they are in the field of fixed coils 67 and 68, respectively, which are connected in series to the output terminals 69 of the amplifier 49 are connected. The moving coils 65 and 66 of the directional measuring units are shifted by 900 in phase via series resistors 70 or 7I with two Voltages from a phase regulator 30 connected to the network I are fed.

The amplifier fed by the network 1 by means of the connection terminals 23 49 contains an amplifier tube having an exponential characteristic, the bias of which according to of the invention by a two auxiliary clamps 72 to be fed Auxiliary current can be influenced, which is taken from a rectifier arrangement 73 which is connected to the primary voltage U1 via a series resistor 73 '.

The arrangement described is in a manner known per se the diagonal voltage UK of the bridge circuit automatically in two at the resistors 46 and 47 effective stress components decomposed in such a way that the deflection angle α1 and a2 of the moving coils 52 and 58, the loss factor or the capacity of the Correspond to the test object.

If this shifts the tapping contact 4, the primary voltage U1 and also the secondary voltage U acting on the test object is changed, see above The output voltage of the sliding rectifier arrangement also increases with increasing primary voltage U1 73. With this, the bias of the exponential tube arranged in the amplifier 49 becomes increased, which in a known manner, a decrease in the gain factor causes. As a result, the output current of the amplifier and thus also increases the field strength in the coils 67 and 68 of the directional measuring units acting as zero motors so that the setting speed of the measuring mechanism is reduced accordingly.

Here, too, the dimensioning can be chosen so that any Values of the test voltage Ua, the moving coils adjust themselves to be vibration-free.

The resistance measuring device shown in Fig. 3 is connected to a DC power source 74 and consists of a bridge circuit shown in a bridge branch a current-dependent resistor 75 to be examined and in an adjacent bridge branch contains a comparison resistor 76. The two other bridge branches are slidable through the two parts one through one Tap contact 77 subdivided sliding wire 78 given. To avoid the dependency of the To investigate resistor 75 from the operating voltage U is the bridge circuit to an adjustable by a displaceable tap contact 79 part of one of the DC power source 74 fed resistor 80 connected.

A moving-coil measuring mechanism serves as the zero motor for setting the pick-up contact / 7. which is only indicated by a moving coil 81 in the drawing. This is from fed to a magnetic amplifier, which excites from a Wedselstromnetz 82 is. For this purpose, the primary winding S3 of a transformer is connected to the network 82 connected, which is provided with two secondary windings 84 and 85. The winding 84 feeds the excitation windings 87 and 88 of two via a rectifier arrangement 86 Iron cores 89 resp.

90, which also have a control winding 91 or 92 and an additional winding 93 or

94 wear. Similarly, the winding g5 feeds through a rectifier arrangement 95 the excitation windings 96 and 9 of two iron cores 98 and 99, each with a control winding 100 or IOI and one additional winding 102 or 103 each.

The control windings 9, 92, 100 and 101 are connected in series connected to the diagonal of the bridge circuit. The alignment arrangements 86 and 95 are on the DC side in the manner shown in the drawing Series connection connected with one another. The additional windings 93, 93, 102 and 103 in series with the moving coil 8I in a current differential circuit to the rectifier assemblies 86 and 95 connected. In addition, one of the alternating current network 82 is fed Auxiliary rectifier arrangement 104 on the DC side via resistors 105 and 106 so connected. that the control windings 91 and 92 from the sum and the control windings 91 and IOI are traversed by the difference between the relevant direct currents.

Parallel to the. Series connection of the additional windings 93, 94, 102 and 103 is now, according to the invention, a thermistor I07 which is powered by a current J " is heated in a winding 108, which is connected to the voltage via a series resistor 109 U is connected.

When the amount of resistor 75 z. B. increases, the Current intensity in the control windings 91 and 92 decreases accordingly. This also decreases the alternating current strength in the excitation windings 87 and 88, whereby the balance the alternating current differential circuit fed by the two secondary windings 84 and 85 is disturbed.

As a result, flows in the equalizing branch of the rectifier arrangements 86 and 95 a direct current, which the auxiliary windings 93, 94, I02 and 103 as well as the Moving coil 8 l flows through it. The additional windings are now switched so that the The bias of iron cores 89 and 90 increases while the bias the iron cores 98 and 99 decreases. This creates a magnetic feedback, which leads to a significant increase in the gain factor.

Since the thermistor 107 is shunted to the additional windings 93, 94, 102 and 103, the greater the amount of the in the balancing branch the current compensation circuit flowing direct current on the additional windings bypassed, the lower the resistance of the thermistor becomes.

If now by moving the tapping contact 79 the operating voltage U is increased, the heating current strength 1 "in of the winding Io5, so that the resistance of the thermistor 107 is reduced. Through this the amperage in the auxiliary windings 93, 94, 102 and 103 decreases, thereby reducing the feedback is reduced and the current intensity flowing through the moving coil 8I is lower, so that the setting speed is reduced.

P. \ TEN-TANSPRÜCIIE: I. Arrangement to improve the setting the adjustment element controlled by a zero motor in compensation measuring devices with automatic adjustment, in which the current strength effective at the test object or Voltage can be regulated within wide limits, characterized in that with increasing Amperage or voltage on the test object of the zero motor inevitably in the sense of a Reduction of the setting speed is influenced.

2. Arrangement according to Claim I, marked by one of the am Measurement object effective amperage or voltage-dependent braking device.

Claims (1)

3. Arrangement according to claim 2, characterized in that with the movable member of the null motor is a conductive body, in particular a disk (26, 27), which moves in a magnetic field (34 or 35) that is generated by a direct current is excited, the strength (J ') of which effective on the test object Current (J) or voltage is dependent. 4. Arrangement according to claim 1, characterized by one in the circuit of the zero motor effective resistance, the amount of which differs from that effective on the DUT Amperage or voltage is influenced. 5. Arrangement according to claim 4, characterized by a thermistor, which depends on the current strength or voltage acting on the test object Electricity is heated. 6. Arrangement according to claim I with one for feeding the zero motor Serving amplifier, characterized by means for influencing the degree of amplification depending on the current strength or voltage effective at the measuring object. 7. Arrangement according to claim 6 with an alternating current compensation circuit and a tube amplifier for feeding the null motor, characterized in that to the supply voltage (U2) of the compensation circuit or one that is dependent on it Voltage (U1) a rectifier arrangement (73) is connected, which in itself known way the bias of a preamplifier tube arranged in the amplifier (49) influenced. 8. Arrangement according to claim 6 with one over one with magnetic Feedback working magnetic amplifier powered zero motor, labeled by means of influencing the magnetic feedback as a function of the current strength or voltage effective at the measuring object. 9. Arrangement according to claim 8, characterized in that in the shunt to the windings (93 94, I02 I03) of the magnetic Amplifier a thermistor (IO4) is arranged, which through one of the on the test object effective amperage or voltage (U) dependent current (J ") is heated.