DE895417C - Transmitter device for remote transmission of measured values - Google Patents

Description

Giving equipment for remote transmission of measured quantities for remote transmission of measured variables, especially in electrical power, sales operation, has been shorter Transmission distance where there are switched transmission lines, the compensation method has proven its worth. The originally to be measured Size in a donor instrument after some effect, e.g. B. the torque detected and this through an automatic compensation through the similar effect of a The auxiliary variable used for the transfer is saved in a compensation instrument. The two instruments are usually mechanically coupled so that the Comparison of the two effects via the torque produced in the measured variables can be done.

An automatic control device that monitors the equality of effects ensures that the auxiliary compensation variable used for the transmission causes the same effect as the original measured variable in the transmitter instrument.

In other cases, compensation is also provided via the rash made both cutting devices, for example a contact device between one Contact pointer on the axis of one device and a contact part on the axis of the second M - ßgeräl #, - s wear.

In all of these cases it is necessary to connect the two measuring devices to one another to couple mechanically on a continuous axis and with the help of this mechanical Coupling the comparison of the effects of the original required variable and the auxiliary compensation variable to be executed in or at least to be arranged in a common axis direction. this however, has various disadvantages, the main being that by the mechanical assembly of the two measuring devices caused additional frictional forces or that: the moment of inertia of the moving system is increased, etc., so. that the accuracy or setting speed of the measuring devices are impaired, To avoid this, an arrangement has already been proposed at the comparison of the deflections and the automatic adjustment of the auxiliary compensation variable with the help of light beams, mirrors, photocells and an amplifier device is carried out.

The present invention also aims at the creation of a remote compensation measuring device without mechanical coupling of the two measuring devices, whereby the automatic control device becomes particularly simple and precise for the auxiliary compensation variable and also the The advantage arises that the encoder measuring device for the original measured variable and the compensation measuring device completely identical additions received for the auxiliary variable intended for transfer, so that it is particularly easy to manufacture.

According to the invention, a transmitter device for remote transmission is provided of measured values according to the compensation method, in which the original measured variable fed to an encoder measuring device and better in the form of one for long-distance transmission. suitable auxiliary variable obtained by automatic compensation, preferably a direct current variable, which in turn is transmitted to the transmitter device Co-working Kompensationsnießgerät supplied and as a result of a with the help of this The comparison carried out on both measuring devices is automatically adjusted to the correct value is created by the fact that each of the two measuring devices without a mechanical Coupling with the other is arranged independently, and one preferably inductively or capacitive, deflection-dependent control device that carries the frequency an auxiliary generator is able to change in a certain range, and that further a monitoring device is provided that the constancy of the Auxiliary generator generated frequency-monitored and the compensation auxiliary variable automatically so. sets that the two control devices of the two measuring devices together the right one value. the frequency.

The invention is explained with reference to the drawings, namely shows FIG. 1 shows a principle diagram of a transmitter device according to the invention, FIG. 2, on the other hand a curve sheet to explain the mode of operation of the arrangement.

In Fig. I i represents the actual transmitter instrument with which a capacitive control device is mechanically coupled, which can be constructed like a small variable capacitor. 3 is a measuring device for the auxiliary compensation variable, which is displayed as! DC current is intended and therefore allows the use of a moving coil instrument. On the axis of this measuring device there is also a capacitive control device in the form of a variable capacitor 4. Both capacitors: 2 and 4 are connected in parallel to a fixed capacitor 5 and determine with an inductance, 6 the frequency of a tube generator 7, whose anode voltage is determined by the Current source 8 and its grid bias voltage is supplied by a cathode resistor 9. io is a feedback winding which is located on the grid of the tube and is necessary for generating vibrations, ii is the secondary winding which supplies the alternating voltage generated to the monitoring device 12. This can be of any type per se, but has a fundamental effect, depending on the value of the frequency, in such a way that depending on the value of the frequency, it delivers a DC current quantity which on the one hand flows through the compensation measuring device 3 and on the other hand is transmitted via the long-distance line 13 to the receiving instrument 14 .

The monitoring device 1: 2 for the frequency of the auxiliary generator In the simplest case, it can consist of a resonance circuit whose Spantiung'glaichdirected is.

Fig. 2 shows above the amplitude which arises in such a resonance circuit, it has its maximum at the travel resonance frequency fo and below the resonance frequency, for example at the frequency f, an edge-like rise.

Assuming that such a monitoring device 12 is in place, the device according to FIG. I operates as follows: The measuring device i receives any measured variable corresponding to the instantaneous value and executes a deflection indicating this measured variable. The capacitor 2 is rotated to a certain position and therefore assumes a certain value of the capacitance. The measuring device 3 shows z. B. initially to zero. The total capacitance in the resonant circuit then has a certain value and thus results in a certain frequency, * the z. B. lies between F 'and f . In this way, however, the monitoring device 12 supplies a direct current for the compensation device 3, which increases the deflection of this instrument until the capacity of the; Rotary capacitor 4 has decreased to the value that is just required for a state of equilibrium.

It can be seen that the arrangement must be made so that an increase in the deflection of the measuring device i z. B. an increase in the capacitance of the capacitor 2, an increase in the deflection of the measuring device 3, a reduction in the capacitance of the capacitor 4 causes. Apart from the small deviation that arises due to the finite steepness of the slope of the curve for the dependence of the amplitude a on the frequency f , the sum of the two capacitances 2 and 4 must always be constant. every change in capacitance 2, i.e. every change in deflection of the original measuring device i, causes an automatic readjustment of the current in instrument 3 and thus the deflection and capacitance 4. Because the curve for the dependence of the amplitude a on the frequency f is not infinitely steep , but rather has a certain finite inclination, the sum of the two capacities will not remain completely constant, but rather lose something with the magnitude of the deflection. However, since the properties of the resonance circuit are unchangeable, this deviation can be calibrated in the display of the l- ', mpfangs, aerät-l's 14, especially if it is linear, which can easily be achieved by suitable selection of the individual members and appropriate dimensioning can be. This is also related to the setting property of the arrangement, which contains an automatic control, so that for this reason too, consideration must be given in the dimensioning. The #O, especially for the mechanical adjustment times of the two measuring devices, for which aperiodic damping is useful.

Instead of utilizing the amphtude of a resonance circuit in the monitoring device 12, a milling device known per se can also be used for the phase shift, the basic course of which, depending on the frequency f, also includes Fig. 2: in the lower curve representation. At the resonance frequency f. Of the resonance circuit, the so-called phase jump occurs, i.e. H. the phase shift goes through zero and thus changes. the sign.

With a phase-dependent rectifier circuit, a DC value can be produced, deir represents the phase shift and can be used as an auxiliary compensation variable.

Another type of monitoring device 12 may e.g. B. from a There are filter circuits whose cutoff frequency is approximately the same as the operating frequency of the auxiliary generator is placed. Such a filter circuit, e.g. B. a high or low pass, shows a output voltage, which varies greatly with frequency, after appropriate rectification and any gain can also be used as a compensation variable.

In Fig. I the circuit for the transmission circuit is drawn in such a way that the transmission operates with impressed current, i. H. that current strength which flows through the instrument 3 and causes its deflection is also used for the transmission. This current is set in the same way, regardless of all external influences, since the state of equilibrium is only reached when the correct frequency of the auxiliary generator is set. The process basically shares this property with all compensation processes.

When the Kompensationsmeßgerät 3 is not switched through as a flow meter, but as Spannungsmesiser, can just as easily Weirden a circuit with impressed voltage produced which operates advantageous for some arrival, vendungszNvecke, in particular for Zweckv the summation.

A linear relationship between deflection and compensation auxiliary current can by choosing a suitable cut for the moving part of the variable capacitor can easily be achieved with the desired accuracy.

To power supplies to the bypassable part of the variable capacitor To avoid this, the moving part can also be used as an intermediate document between two fixed Enclosures are arranged, between which the series connection of two with the rash, variable partial capacities arise. The power supply then only need to be brought to the two solid documents, but not to the moving part, which odeir to avoid additional frictional moments other adjustment forces is desired.

'' In order to keep the variable capacitor as small as possible, it is advisable to the frequency of the auxiliary relatively high, e.g. B. of the order of a few To put MHz so that capacities in the order of magnitude of a few pF are usable, which can be carried out with small occupancy areas. That way will the additional mass to be moved by the axis of the measuring device is kept small and the error to be expected due to the additional load on the cutting device as well kept small.

Instead of a capacitive control device on the axis of the encoder devices an inductive control device can also be used, which. a variable self or alternating induction represents. Here, too, devices in which power supply lines to the axis are avoided, so the control z. B. by connected to the axis swiveling magnetic conclusions or by in the air -., palt of a fixed Magnets immersing diaphragms is effected.

Such inductive control devices are expediently so operated so that the restoring forces exerted by them are so small that they are opposite the setting forces of the measuring devices can be neglected. At de-in capacitive This is always to be expected from the outset for control systems, with inductive ones Control devices, however, only if the inductions are kept small enough will.

The requirement for a mechanically independent arrangement of the two measuring devices extends only to the avoidance of a mechanical coupling between them, on the other hand, it does not depend on the common accommodation of the two measuring devices in one Housing, which is useful because both are connected to the measuring devices Control devices belong to the same resonant circuit.

in the embodiment is one of many in #, alike arrangements described, in addition to which there can be others on an equal footing, if t -we only the basic working principles are retained. She demands that for that original measured variable to provide a measuring device with a control device is, for the auxiliary compensation variable vin another measuring device with similar stabilizing device, both of which together determine the frequency of an auxiliary generator, which is controlled by a Monitoring device is monitored and, according to the result of this monitoring, a value for the Compensation auxiliary variable supplies.

Claims (2)

PATENT CLAIMS encoder device for remote transmission of measured variables according to the compensation method, in which the original measured variable is transmitted to an encoder measuring device is supplied and in the form of a more suitable for long-distance transmission automatic compensation obtained auxiliary variable, preferably a direct current variable, is transmitted remotely, which in turn interact with the walking device Compensation measuring device is supplied and as a result of a between these two devices carried out comparison is automatically adjusted to the correct value, characterized in that each of the two meters is mechanically different from the other is arranged independently and a preferably inductive or capacitive acting deflection-dependent control device carries the frequency of an auxiliary generator is able to change in a certain area, and that further a monitoring vox direction is provided that monitors the constancy of the frequency generated in the auxiliary generator and automatically adjusts the auxiliary compensation variable so that the control device of the two measuring devices together give the correct value of the frequency. 2. Encoder device according to claim i, characterized in that the pivotable part of a three-phase capacitor is connected to the axes of the encoder measuring device and the Kempensationsmeßgerätes, which rotates relative to a stationary part and thus a change in capacitance as a function of the position of the axis results. 3. Transmitter device according to claim i and 2, characterized in that the variable capacitor connected to the axis of each measuring device is designed so that no voltage supplies to the movable part are necessary, but the set capacitance by series connection of two partial capacities between each fixed part and the moving part is made. 4. walking device according to claim i, characterized in that the Stetter devices connected to the axes are effective on inductive ways and represent variable self or alternating rope inductions. 5. Transmitter device according to claim i and 4, characterized in that the inductive control devices are designed on the axes of the measuring devices so that no power supply to the movable part is necessary, but the windings are designed to be spatially fixed. 6. Transmitter device according to claim i, characterized in that the monitoring device for the frequency of the auxiliary generator consists of a resonance circuit. 7. Transmitter device according to claim i and 6, characterized in that the amplitude of the voltage or the current, which varies with the frequency, is used to set the auxiliary compensation variable. is used in the resonance circuit. 8. Transmitter device according to claim i and 6, characterized in that the phase shift between voltage and current in the resonance circuit is used to set the auxiliary compensation variable. G. Transmitter device according to claim 1, characterized in that the monitoring device for the frequency of the auxiliary generator consists of a band filter, preferably a high or low pass filter, the output voltage of which, which varies greatly with the frequency in the vicinity of the limit frequency, is used to set the auxiliary compensation variable. ok Gebeireinrichtung according to claim i, characterized in that the frequency of the auxiliary generator is chosen so high that it is possible to get by with very small and light mechanically moving parts of the star devices on the axes of the measuring devices.