DE477333C - Device for measuring and adding up similar measured quantities - Google Patents

Description

Device for measuring and adding up similar 1V measuring variables In Large power plants often require an indication of the total output To maintain performance. Depending on local conditions, this may be the Total output of several individual generators or several partially spaced generators Act power stations. It is sometimes necessary, as is the service provided to be able to read at such points on the system that are at some distance from the actual measuring points. A usable reading device must meet the requirement meet that it is usable even if there are any changes within enter the power plant, be it by installing new generators or by installing new generators Changes in the location of the control station itself. The subject matter of the invention relates to a telemetry instrument which is generally applicable and which is characterized by its simplicity, Accuracy and reliability. It is suitable for both display the mean value as well as to display the voice or the difference between several similar ones Measurands.

A device according to the invention consists of the with the Measuring instrument coupled transmitter, the transmission lines, with possibly suitable Transformers can be switched on, and a display reproducing Recipient. The transmitter has a three-phase stator winding, suitably connected in star and a single phase rotor. The receiver also has a three-phase in Star-connected stator winding and a two-pole iron core as the rotor. In the Transmission lines can be single-phase transformers that use a Summation of the alternating currents generated in the stator and their transmission according to allow the receiver with only three lines.

Various exemplary embodiments are shown in the drawings.

Fig. I shows the apparatus for adding up two transmitters and the connection of the transmitters with the actual measuring instruments. Fig. 2 shows the circuit diagram of the arrangement according to Fig. I. Fig. 3 shows the voltage curves in the stator of the transmitter as a function of the respective position of the rotor. Figures 4 to 6 show circuit diagrams for further exemplary embodiments of the invention. In Fig. I, A and B designate transmitting stations, C a receiving station. In the arrangement shown, the displays in stations A and B are to be added up and transmitted to station C so that the total output of the two stations can be read off on a scale there. In stations A and B there are display instruments io; z. B. Wattmeter. A pointer 12, which allows a reading on the scale 13 , is arranged on the movable pointer axis ii of these instruments. In addition, the movable pointer axis carries a sprocket i ¢, which communicates with a ring gear 1 to 5 dei axis 16 of the transmitter in engagement. As can be seen more clearly from dep. 2, the transmitter has a polyphase stator winding 17 and a single-phase rotor winding 18. The rotor of each transmitter is fed by a common alternating current source i9. Other than this single auxiliary source, any auxiliary batteries are not required. In the examples shown in the figure, the stator is connected in star and has a three-phase design.

In the arrangement according to Fig. I and z, in the transmission lines three identical transformers 2o installed, each of which has three windings zi, 22 and 23 wears. Two of these windings 2i and 22 serve as the primary winding while the third winding 23 represents the secondary winding. It is not absolutely necessary that the windings of the transformers are the same in all arrangements, but they should be accepted here right away in order to: Simplify the description. The terminals of each transmitter are each with a primary winding on each of the three Transformers connected in series, e.g. B. the terminals A1 and A. with the winding 21 on the left transformer, AZ and A3 with primary winding 2i on the middle one Transformer, terminals A, and A3 with the primary winding 21 on the one drawn on the right Transformer. Similar are terminals B1, Bz and B, with primary windings 22 of the three transformers connected.

The receiver provided in station C has a three-phase stator winding 2, 4 and one or more two-pole iron cores 25 as a rotor. On the same A pointer 26 is attached to the axis like the iron cores and plays on the scale 27 can. The rotor 25 of the receiver can possibly be designed in the same way as the rotor 18 of the transmitter, if possible, from the same AC source to dine. The star-connected stator 24 of the receiver is connected to the three in Delta connected secondary windings 23 of the three transformers 2o connected, one transformer winding is connected to two terminals of the stator. The three transformers 2o are expediently set up so that the connecting lines between them on the one hand and the connecting lines to the transmitters on the other and the impedances of the primary windings of each transformer circuit are as small as possible are as much the same as possible, with slight deviations being compensated for in a suitable manner should be.

Fig. 3 shows the relative voltage values applied to the stator terminals each transmitter can be measured when the rotors are rotated by 36o °. the Curves agree with those for three-phase, sinusoidal current. However, it is to take into account that the abscissa in the diagram shown is rotor positions represents, but not a time. When the rotor is excited with alternating current, a spatially stationary, but temporally pulsating field. The location of this Field depends on the respective: rotor position, as can be seen in the diagram leaves. The different stator windings are induced differently, and in the transformer windings connected to them flow currents that are proportional, generate magnetic fluxes in the transformers. Corresponds to every rotor position in each of the three transformers a flux, with the ratio of the three fluxes depends only on the respective rotor position and is constant. on the summation only has the rotor position, but not the strength of the rotor excitation Influence. By doing. In the example shown, the arrangement is made so that the Voltage at terminals i and 3 is zero when the two transmitters are assigned Pointer to zero. Since in the arrangement shown in Fig Rotation of each rotor is about .80 °, so it is enough to only look at the changes between zero and 80 °, although the arrangement is not limited to this is.

It is first assumed that the three windings of the transformer 2o are completely the same. The voltages in the two primary windings of each transformer are in phase. In the event that: the displays of the variables to be measured are the same in both stations, the voltage in the two primary windings of each transformer is of the same size. The secondary winding will consequently receive a voltage which is equal to the sum of the voltage in the two primary windings. The receiver will therefore assume the same position as the two transmitters, since the ratio of the voltages in it is the same as the opposite direction flow when voltages in the same direction are generated in the stator windings 17. With this arrangement, the voltage of the stator 17 in station B has the same direction as the voltage that is induced in secondary windings 22 'under the assumption made by the primary windings 21'. As a result, both voltages will add up and result in currents in the secondary circuit which correspond to the sum or the average voltage of the corresponding phases of the stator 17 in stations A and B. With the arrangement according to Fig. Q. the stator windings of the transmitter and the receiver are partly galvanically and partly inductively coupled.

In Fig. 5 an arrangement is described in which the voltages of the Transmitter direct, d. H. can only be added galvanically. Here are the windings the transmitter and receiver are not star-connected, but the connections are taken so that each winding of the transmitter and the winding of the receiver one behind the other are connected and form a closed circuit. With this arrangement so transformers are not required. However, six lines are closed available to the recipient. When the receiver is at a great distance from the transmitters is set up, the interconnection of the transformers is usually less expensive than the six-line version.

In Fig. 6 an arrangement is shown with which the power of the stations A, B and D is summed and transmitted to the receiver C. Two sets of three transformers each are provided. The arrangement corresponds to the circuit according to Fig. 4. In order to add up N displays, three (Nr) transformers are required for the arrangement according to Dep. 6. The numbering of the scale of the receiver must accordingly have an N-fold value of the scale of an individual transmitter instrument.

With the arrangements described above, it goes without saying also possible instead of a summation. make a subtraction.

Claims (1)

PATENT CLAIMS: mizing of similar measurands, yyda ~ -rch- characterized in that upon rotation d with otors connected to the instruments the ratio of the stator spans Station is changed and In summary, it corresponds to phases in the stator of the receiver a field, stands whose position the S me or the Mean value of the individual measured variables speaks. : 2. Facility according to claim i, that by gekennzeichn that the transmitters each one of the ichen alternating current source fed otor and one each three- phase stator. 3. Einric g according to claim i, that by gkn eichnet that the recipient a #reiph; sige stator winding r d no the pointer provided with it u d G h ', 1 C p _otor carries a bipolar iron core. 4. E ' direction according to claim i to 3, characterized by the fact that the he measurement of the corresponding voltage and ge direct, d. H. galvanic or inductive u switching on converters or oto nding both arrangements d, rehVerbi me b 5. Device according to -Anspruch i and ¢, characterized in that three transformers are arranged which have a number of primary windings and a secondary winding corresponding to the number of measuring points. 6. Device according to claim i and d., Characterized in that three (Ni) single-phase transformers are arranged for the summation of N measuring points and that one transmitter is connected to the secondary windings of the converter and the receiver in such a way that a summation corresponding phases of the various broadcasters takes place. Ratio of the voltages in the stator windings of the transmitters. With different settings of the transmitter, ie with different positions of the pointer z2, the voltages in the two primary windings of each transformer will no longer be the same. Accordingly, the secondary voltage will be proportional to the mean value or the sum of the two primary voltages. The conditions that occur are to be explained using an example. The instrument in station A is rotated through an angle of 20 °, the deflection of the instrument in B is qo °. The diagram (Fig. 3) then shows a voltage of 2o at terminals A, A3 and 35 volts at terminals B1, B3. These voltages are composed and, if the number of turns of the three windings are the same, induce a voltage of 55 volts in the secondary winding of the transformer shown on the right. In the same way, the voltages on the other two transformers are made up of the voltages on terminals A1, A2 and B, BZ or A., A3 and B2, B3. The (secondary voltages of the three transformers are therefore proportional to the sum of the voltages at their primary terminals. The currents from the primary windings cause flows in the three transformers that correspond to the pointer positions. These flows add up in each of the three transformers and give a resultant flow, The voltage generated in the secondary winding as a result will create a position of the field in the stator of the receiver 24 that corresponds to the resulting transformer fluxes, so that the position of this field also corresponds to the sum of the displays of stations A and B. The The iron core 25 located with the pointer on the same axis adjusts itself to the position of the field and indicates the corresponding values on the scale 27. If the scale 27 has double the values as the scales 13 of the instruments in stations A and B, the sum of the individual readings is displayed in C. If dag If the scale 27 has the same numbering as the transmitter instruments, it is possible to read an average of the individual readings. In order to eliminate repercussions of the stator winding on the rotor and the resulting incorrect settings of the rotor, it is necessary to keep the torque of the transmitters small compared to the torque of the measuring instruments connected to them. This can e.g. B. can be done in that suitable resistors 28 are switched into the rotor circuit of the transmitter. The effect of such resistors can be seen in Fig. 3, in which the three rows of ordinates show the voltage: when the resistor 28 is designed with zooo, 2ooo and 0 ohms. The larger the resistors 28, the smaller the reaction of the stator on the rotor will be. These resistors can also serve to compensate for any differences in the torques of the transmitters or to compensate for differences in the impedances of the circuits between transformers and transmitters. It has been found that the system, when properly balanced, produces very accurate results. It was previously assumed that the scales of the two transmitters have the same length and the same values. Any differences in this regard can be corrected by appropriately dimensioning the ratios 1q. and 15 are balanced. On the other hand, they can also be taken into account in that the primary windings 21 and 22 of the transformers have different numbers of turns. In the present case, where only two instrument data are to be added, each of the three transformers has two primary windings. If a larger number of displays is to be added, it is only necessary that each of the transformers receives additional primary windings, and each of the three transformers must receive as many primary windings as the pointer positions are to be added. In contrast, each transformer has only one secondary winding. If there are more than two measuring points, the scale of the receiver is given a number that is a corresponding multiple of the values of the individual transmitter instruments. If only the mean value is to be measured here, the scale would have the same numbering as the transmitter instruments. The connections between the transmitter and the receiver can also be made in other ways than described above. When arranging according to. Fig. ¢ there are three transformers 2o ', each of which has two windings 2, 1' and 22 '. The primary windings 21 ′ are connected in star and connected to the terminals of the transmitter 17. The secondary windings 22 'of the three transformers are connected in series with two terminals of the stator 17 , the transmitter B and the receiver 24. The windings of the transformer 2o 'are to be switched in such a way that the currents of the transmitter 17 in the primary and secondary windings are