DE1137792B - Control device for the regulation of the reactive power requirement in several equal stages - Google Patents

Description

Control device for regulating the reactive power requirement in several equal stages The invention relates to a control device for controlling the Reactive power requirement in several equal stages, consisting of a number different large capacitor groups, which is smaller than the number of control stages achieved and with the contactors of the capacitor groups via contacts of a control switch are actuated by a reactive load-dependent Ferraris measuring mechanism accordingly are continuously closed or opened according to the current load condition.

Control devices of this type are often used because one in relation to the number of control stages - which is often because of the fine stages the control selects as large as possible - small number of capacitors to be switched need, which also corresponds to the number of switching devices required for this small and thus the effort for the creation and maintenance of the plant in portable Limits remain. The larger number of control stages is achieved with these controllers achieved that the individual switched capacitor groups are selected to be of different sizes and are interconnected in different combinations so that they just result in the capacity value that is available at the relevant point in time inductive reactive load value for the purpose of its compensation to the desired extent if possible comes close.

The formation of such switching combinations of capacitor groups requires practically their simultaneous connection and disconnection, if one is unsuitable in the network large and long-lasting voltage changes as well as fluctuations in the control process wants to avoid through longer over- or under-compensation. Fulfill this requirement ideally those controllers that make this switchover with the help of relays, because these, with their short proper times, have a largely more precise sequence of these Switching can be guaranteed as an exclusive control by cams.

Even reactive power regulators, which use mercury toggle switches actuated by camshafts to switch the capacitor contactors, also use relays to achieve switching accuracy, as shown in the circuit diagram in Fig : 4 stand, seven gear steps achieved according to the gear shift program given below; Fig. 1 shows the contact position when the control switches R1, R2 and R3 are closed. A- Closed capacitor group C is switched Control switch capacitance switched on I switched off R1 C1 - 1 R1 with R2 C2 Cl 2 R1 with R3 Cl - 3 R1 with R4 C ;; C2 -h C1 4 R1 with R5 C1 - 5 R1 with R6 C2 C1 6 R1 with R7 C1 - 7 In such a controller, in addition to the seven mercury toggle switches R1 with R7 operated one after the other by the reactive load measuring mechanism via a camshaft or seven switches of a different design, auxiliary relays Hi, H2, H3 with a total of four break contacts and three make contacts are required to achieve the switching program specified above, because through the shape of the individual cams alone cannot reliably achieve the precise actuation of these switches required for this combination of capacitor groups.

Another commonly used type of regulator is used in place of the through a camshaft controlled control switch especially because of the then required smaller torques a mercury ring tube driven by the reactive load plant with a number of control contacts corresponding to the desired number of control levels R1 to R7, which are bridged by the mercury during the rotation of the ring tube or opened and so the function of the otherwise used mercury toggle switch take over. In this case, too, the same number of auxiliary relays is required, because it is just a different form of control switch.

These auxiliary relays are saved in the controller according to the invention and the required switching combinations with even greater security and timing accuracy, than that of auxiliary relays because of the time constant of their windings, their deviating ones mechanical properties i.a. m. is possible, only through additional use achieved by auxiliary contacts, which are attached to the capacitor contactors that are already present and moved by them according to the required switching program.

The solution proposed according to the invention is therefore that the switching sequence of the capacitor contactors required for the capacitor group combination is achieved solely with the aid of auxiliary switches connected to the corresponding Capacitor contactors are attached and operated by them. With such a Arrangement exists in addition to the savings in expenses for the instead of the auxiliary switch hitherto customary auxiliary contactors also ensure that the for the combination required switching sequence is brought about much more safely than when you put it through brings about additional contactor relays because they get stuck or similar Failure can fail.

There are already control devices known, but each with one Switch-on and switch-off reactive current relays work and those for each control stage in addition still need two timing relays to make reactive current surges ineffective. With you the electrical interlocking for the one after the other to be accomplished and disconnection of approximately the same size capacitor banks ensured by auxiliary contacts, which are attached to the capacitor contactors. With the much more commonly used, because simpler automatic compensation systems with a reactive current regulator, which is switched on by a single Ferraris blind load measuring mechanism as well as elimination of the individual compensation levels with the required Time delay via a control switch with continuously closing or opening Making contacts is the inventive arrangement for the combination circuit different sized capacitor groups have not been used, even by specialist companies, even if controllers, contactors and accessories were combined in one housing, so that the control lines between contactor auxiliary contacts and the contacts of the continuous closing or opening controller switch and thus the application the arrangement according to the invention is particularly appropriate.

The circuit diagram of a control device according to the invention with a mercury ring tube, but otherwise for the same conditions as the control device according to the circuit diagram in FIG. 1 is based on, is shown in FIG. 2. donut called while attached to the capacitor contactors auxiliary contacts ö the name with the index of the associated capacitor contactor ski to Sch, wear because they are contacts that open when the contactors ski to Sch ,, to which they are attached attract; the index of Ö indicates which of the three capacitor contactors will open or close the relevant auxiliary contacts.

In Fig. 2, for example, the switching state is drawn as it results when the reactive load measuring mechanism has closed the control contacts R1 to R3. The auxiliary contacts Ö2 and Ö on the capacitor contactors Sch, and Sch, in this case only leave the actuating voltage to the contactor coils of Schi and Sch2, so that only their main contacts K1 and K_ are closed, while the coil of the contactor Schi remains de-energized, so that in this switch position the capacitor groups C1 and C2 are switched on and the group C remains switched off. In this position of the mercury ring tube there is a capacitance value corresponding to the size of the total capacitance of C1 and C2. Closes the blind load meter z. B. also R4, because the total capacitance of C1 and C2 is not yet sufficient for the compensation, the contactor coil comes from Sch, voltage, picks up, the contactor closes its main contacts K, and opens all auxiliary contacts Ö at the intended time, so that the contactor coils of Schi and Sch2 are de-energized at the intended time. As is to be indicated with these two examples, the capacitance values according to the table also result with the circuit according to the invention when the control switches specified in their first column are closed, without the three auxiliary relays H1, H2, H3, as shown in FIG Arrangement according to Fig. 1 are required. The switching accuracy is even greater because the switching timing inaccuracies and other possible errors that lie in the relays connected there are eliminated.

The reactive load meters used to operate the control switch R1 etc. have a relatively small torque, so that one must strive to use control switches that only need small mechanical forces to switch them on and off, especially with a larger number of control stages with their many control switches. This leads to switches with small dimensions and the associated low electrical switching capacities, which are often no longer sufficient for the correct direct disconnection and connection of the mostly not insignificant inductive coil currents of the capacitor contactors. That is the reason why the capacitor contactors are sometimes not made to work directly via the contacts of the control switch, but indirectly via small intermediate contactors that only require small coil currents. In such a case, for example, the capacitor contactors Schi to Sch, in Fig. 2, take over the function of those intermediate contactors whose powerful contacts K to K3 can then reliably switch the larger coil currents of the capacitor contactors, with the auxiliary contacts attached to the intermediate contactors having the same mode of operation as before on the capacitor contactors. However, when using such intermediate contactors, the auxiliary contacts can also be attached to the capacitor contactors they switch. With such an intermediate contactor arrangement, for example, three auxiliary relays are saved, as can be seen by comparing the circuit diagrams in FIGS. 1 and 2.

You can also use this principle to build regulators with four capacitor groups in a ratio of 1: 2: 3: 6 twelve control stages or with four capacitor groups 1: 2: 4: 8 fifteen control levels and the like.

The controllers are sometimes exposed to vibrations during operation Fluctuations in the surface area of the mercury can cause the in the annulus is used. Such fluctuations can be unpleasant in certain regulator settings Trigger flutter phenomena on the shooter. To prevent them, the Contacts of the mercury interrupter amalgamated, which causes the mercury, if it has touched the contact once while its surface swayed, on him sticks despite the vibrations.

Especially with large capacitors, it can happen after a mains voltage failure the sudden return of the mains voltage when the controller is set to a higher value Number of stages strong capacitive inrush currents and strong overcompensation for Have consequence.

For such cases, the controller is connected to a mains voltage Provided zero voltage relay, according to the invention in the event of a power failure over whose contacts on the one hand the actuating circuits of the capacitor contactors so be interrupted for a long time and on the other hand via other contacts of this relay Drive circuit for the reactive load meter is switched so that its normal Direction of rotation remains reversed until the mains voltage returns and after switching on Consumers turn the control switch back to the starting position is.

Such a zero-voltage device is shown, for example, in the part of the circuit diagram according to FIG. If the mains voltage fails, the relay N of this device reverses the direction of rotation of the measuring mechanism by means of the two changeover contacts UN and, at the same time, by means of the normally open contacts SN, that the relay N and thus the capacitor contactors Sch, with Sch, will not do so long even when the mains voltage returns tighten until the regulator is turned back to the zero position. Until then, after the return of the mains voltage, inductive loads remain uncompensated, so that the measuring mechanism turns the ring tube back into the zero position because of the previous switchover of its direction of rotation. The criterion that this has been achieved is the opening of the control contact R, the tube, whereby the coil of the relay n is de-energized. This then closes its NC contact Ö ", the coil of N is excited, its contacts SN closed and the changeover switch UN set to normal direction of rotation; the coil of N remains energized even if the coil of relay n is energized again as the control process progresses gets and thereby Ö "opens, since SN acts as a holding contact for N until the mains voltage fails again.

The regulator according to the invention can serve the same purpose be equipped so that one or more capacitor groups by one or more Relays are switched off immediately in the event of a mains voltage failure and when it returns the tension by means of a delay device, the train circuit only takes place, when a desired time has passed. Such a switching arrangement is, for example shown in the part of the circuit diagram of FIG. 2 delimited by dashes. The contacts these relays interrupt the control coil circuits in the event of a mains voltage failure one or more capacitor contactors immediately and maintain this state The voltage is restored by a delay device on the relay for as long as until it can be assumed that the mains voltage has returned and reactive load consumers have been switched on, so it is desirable to switch the capacitors through the delay relays to be switched on again without fear of a noticeably longer Overcompensation takes place because the control process then starts again immediately.

Claims (1)

PATENT CLAIMS: 1. Control device for regulating the reactive power requirement in several equal stages, consisting of a number of capacitor groups of different sizes, which is smaller than the number of control levels reached and for which the contactors of the capacitor groups are operated via contacts of a control switch that are operated by a reactive load-dependent Ferraris measuring mechanism according to the present one Load state are continuously closed or opened, characterized that the switching sequence required for the capacitor group combinations the capacitor contactor is achieved solely with the aid of auxiliary switches, which are attached to the corresponding capacitor contactors and operated by them will. z. Reactive power control device, in particular according to claim 1, with a Control switch driven by a Ferraris measuring mechanism in the form of a mercury ring tube, characterized in that their contacts are amalgamated. 3. reactive power control device, in particular according to one of claims 1 and 2, with one connected to mains voltage Zero voltage relay, characterized in that in the event of a mains voltage failure over its Contacts on the one hand interrupted the actuating circuits of the capacitor contactors for so long and on the other hand the drive circuit via further contacts of this relay for the blind load measuring mechanism is switched so that its normal direction of rotation is reversed remains until after the mains voltage has been restored and after consumers have been switched on the control switch has been turned back to its starting position. 4th Control device according to one of Claims 1 and 2, characterized in that one or several capacitor groups through one or more relays in the event of a mains voltage failure are switched off immediately and after the voltage has returned by means of a delay device the connection only takes place when a desired time has elapsed. In Considered publications: German patent specifications No. 726 974, 870 583, 895,943; German interpretation document D 17640 VIIIb / 21c (published May 24, 1956); AEG-Mitteilungen (1933), p. 163 ff .; "Der Elektromeister", 6 (1953), p. 591.