DE1237680B - Measuring transducer that supplies an output DC voltage, the magnitude and direction of which depends on the deviation of the frequency of an AC voltage from a nominal value - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

GOIr

German class: 2Ie-36/03

Number: 1237 680

File number: S 63645IX d / 21 e

Filing date: June 26, 1959

Open date: March 30, 1967

With most transducers, the output variable, which is dependent on the frequency, is calculated by calculating the difference two voltages or currents obtained from the same alternating voltage with the help of two parallel circuits can be derived. The resulting output variable is then no longer of Changes in the magnitude of the alternating voltage are dependent.

With these transducers, at least one of the two variables to be compared must be used be frequency dependent. In the known arrangements, this dependency is determined with the aid of capacitors, Choke coils and resonance circuits achieved with voltage tapping on similar elements.

In the simplest devices of this type, the two circuits contain a series capacitor or a longitudinal throttle. Currents are therefore compared with one another, which increase with frequency or fall. The resulting output is zero at a certain frequency. The arrangement is dimensioned so that this frequency is equal to the nominal value of the frequency of the alternating voltage. Disadvantageous in these arrangements is the relatively small change in the output variable in the event of deviations the, frequency of the setpoint. This increases the sensitivity of the control system impaired if this deficiency is not compensated for by appropriate reinforcement. Apart from that of which, however, in these arrangements is the frequency at which the resulting output variable becomes zero, strongly dependent on harmonics of the alternating supply voltage, since these harmonics in undiminished Size are included in the subtraction.

However, arrangements are also known which do not have these disadvantages. They are different from the described arrangements essentially only in that in the two circuits in place simple reactance series resonance circuits lie. The resonance frequencies of the two series resonance circuits are slightly below or slightly above the setpoint of the frequency. the The output variable of these devices has an approximately S-shaped curve. The steepness of the voltage change in the zero crossing can be determined the choice according to good resonance circles and by the position of the resonance frequencies in a wide range Change boundaries.

Such transducers can only be used if the frequency of the alternating voltage supply is different only in a relatively narrow, essentially due to the resonance frequencies of the two Resonance circles can change certain area.

Transmitter that supplies a DC output voltage that depends on the magnitude and direction of the
Deviation of the frequency of a
AC voltage depends on a setpoint

Applicant:

Siemens Aktiengesellschaft, Berlin and Munich, Erlangen, Werner-von-Siemens-Str. 50

Named as inventor:
Gerhard Schmidt, Munich

Very often, however, a transducer must also be used in the case of very large positive or negative frequency deviations provide a significant output voltage. Reference to illustrate this requirement we refer to the speed control of a water turbine that drives a synchronous generator Such a generator should deliver a voltage of exactly constant frequency. That means the speed Regulated to a constant value independent of the load by means of a very sensitive control circuit must become. For this purpose, a transducer is required that is already in the vicinity of the setpoint frequency supplies a considerable control voltage if this frequency deviates slightly from the nominal value. aside from that this control voltage should be as accurate as possible in the range normally considered be proportional to the control deviation. This requirement alone can be met with the known transducers solve with two series resonance circles. However, these would be at startup and at a Shutdown of the full load of the generator fail under full load. In one case there is the Actual speed - and thus the frequency - far below the setpoint, in the other case - if the Generator suddenly runs without load - the speed suddenly increases to values well above .Set speed (setpoint frequency) on .. So that the controller is still in the The situation is to adjust the valves leading to the turbines in order to compensate for the control deviation, must be the transducer even with so large

709 547/165

3 4

Control deviations result in a considerable output voltage Supply voltage, the polarity of which depends on whether that of Fig. 2 explained in more detail. In Fig. 2 is on the Actual speed above or below the setpoint speed, the voltage is plotted on the vertical axis and the frequency is plotted on the horizontal, right-hand axis. The curve

Furthermore, the output voltage of a measured value should be 5 20 shows the course of the output voltage of the

sensor in the vicinity of the setpoint frequency from active low pass 7 and curve 21 shows the course of the output

For technical reasons, the output voltage of the high-pass filter 3 is linear and mirror-inverted

get lost. on the frequency.

The entirety of this requirement can be The curve 22 represents the difference value from the

previously known transducers do not meet, each io curves 20 and 21. With f _K , the setpoint frequency

but with the transducer according to the invention. value, with / ₀₇ the resonance frequency value of the low

The invention accordingly relates to a pass 7 and with / ₀₃ the resonance frequency of the high-level transducer, which denotes a DC output voltage passes 3. As can be seen from the diagram, which goes from the exit in _{terms of size and direction, the resonance frequency / 07 of} the low-pass filter 7 is below the frequency of an alternating voltage of 15 and the resonance frequency Z _{03 of} the high depends on a target value, and at which this alternating-pass 3 above the resonance frequency f _K. The voltage across two parallel, one each inductive low-pass and the high-pass are dimensioned so that tion coil and a capacitor complement their output voltages at setpoint frequency to zero series resonance circuits with above and below. In the event of deviations in the resonance frequency to be measured, each frequency below the desired frequency f _K , the rectifier predominates, with the output voltage of the low-pass filter 7; in the output voltages with each other frequency f _K the output voltage of the high-pass filter 3; are connected. In addition, the low pass 7 and the high

The invention is characterized in that the 25 pass 3 is dimensioned so that its resonance overvoltages voltage for the one rectifier at the connector (at / ₀₇ or / ₀₃ ) are the same,
capacitor of the series resonant circuit (low-pass) with The lower resonance frequency and the voltage rectifier 14 and 15 provided in the circuit according to FIG Height- 30 different phase position of the same is not tapped from the resonance frequency in a disruptive manner. can work. By connecting the two in series

For a more detailed explanation, the drawing rectifier via the resistor 18 is the im

referenced. It shows resistor 19 according to size and current flowing

Fig. 1 shows an embodiment of the new measuring direction a measure of the deviation of the to be measured

value transmitter, 35 the frequency of the target frequency f _K.

F i g. 2 a diagram of the voltage curve of Um largely harmonic-free output voltage

To obtain the high and low pass circuit and the differential voltages at the rectifiers 14 and 15,

from the two voltages mentioned. can depending on the required freedom from harmonics

To the conductors R and S, between which there is a span in addition to the charging capacitors 16 and 17

voltage is applied that carries the frequency to be measured, 4 ° additional sieve means are provided,

the input terminals 1 and 2 are the high-pass filter because the resonance circuit, whose resonance

circuit 3 and the input terminals of an isolating frequency is above the setpoint frequency, than

transformer 4 connected. The secondary winding high pass is executed, it is achieved that the output

Development of the isolation transformer 4 is also with the input variable of the frequency transducer

terminals 5, 6 of a low-pass circuit 7 connected. 45 large frequency deviations above the SoD

The low-pass circuit 7 consists of the series switching frequency that does not become zero.

processing of an ohmic resistor 8, an inductive The formation of the difference can already be described in the 9 and a capacitance 10. The terminals of the resistor network are made, but it can Capacity 10 are at the same time the output terminals and the outputs of the rectifier arrangement at each the low-pass circuit 7. The high-pass circuit 3 50 consists of a control winding of a downstream magnet from the series connection of a capacitor 11, amplifier, so that a magnetic an ohmic resistor 12 and an inductive difference formation takes place. Furthermore, the Diffevitätl3. The output terminals of the Ä-L combination renzbildung by connecting the train against each other the output terminals of the high-pass input voltages take place at the same time.

circuit. To the output terminals of the low-pass 55 The influence of the input voltage on the switch-off is a rectifier assembly 14, the output size is small because of an increase in Einder High-pass circuit a rectifier arrangement output voltage to the same extent also an increase 15 connected. Parallel to the outputs of the output voltages of high and low pass Rectifier arrangements 14 and 15 are each effected. The influence falls through the formation of the difference Charging capacitor 16 and 17 placed. The starting 60 of the tension increase largely out. Of the clamps of the rectifier arrangement are over an influence of a voltage increase is the less, Resistor 18, which is provided with a center tap the closer the resonance frequency of the high and low is, connected in series. The center tap passes together. The one in the input voltage of the resistor 18 is through a resistor 19, contained harmonics affect the Ausder z. B. also through the control winding of a 65 output variable only slightly, since already the third Magnetic amplifier can be formed, with the harmonic is strongly attenuated. The influence of common connecting terminal of the two equal temperature changes on the measurement result judges 14 and 15 connected. can be kept low if the

Claims (1)

circles contained ohmic damping resistance large compared to the copper resistance of the inductance is. Claim: Transmitter that supplies a DC output voltage that is determined by size and direction depends on the deviation of the frequency of an alternating voltage from a nominal value, and at to this alternating voltage via two parallel, each consisting of an induction coil and a capacitor existing series resonance circuits with above or below the setpoint frequency Resonant frequency is fed to a rectifier each, the output terminals of this Rectifiers connected to one another in the sense of forming the difference between the output voltages are, characterized in that the voltage for one rectifier (14) is on the capacitor (10) of the series resonance circuit (low-pass filter 7) with the lower resonance frequency and the voltage for the other rectifier (15) on the induction coil (13) of the series resonant circuit (High-pass filter 3) is tapped with the higher resonance frequency. Considered publications:
French Patent No. 901969;
British Patent No. 690292;
U.S. Patent No. 1663 086. 1 sheet of drawings 709 547/165 3.67 © Bundesdruckerei Berlin