DE879408C - Control transformer with two parallel flow paths for drawing alternating current with constant voltage from a network with fluctuating voltage - Google Patents

Description

Control transformer with two parallel flux paths for the extraction of Alternating current of constant voltage from a network of fluctuating voltage Die The invention relates to a regulating transformer for voltage equalization, which converts the fluctuating voltage of the supply network into a constant voltage for converts the extraction point. Among other things, you have such transformers executed that it means depending on the fluctuations in the mains voltage under the action of a counterforce, the movable iron parts are automatically positioned change the reluctance of a flux path such that the secondary winding is continuously permeated by a constant flow, or that with economy circuit or Additional transformer circuit compensates for the rise or fall in voltage will. Such voltage equalizers have the disadvantage that the voltage regulation is strongly dependent on the phase and size of the load current.

The object of the invention is to provide a remedy here. She concerns a regulating transformer with two parallel flux paths for drawing alternating current constant tension from one Mains fluctuating voltage; - in which the magnetic resistance of the one flux path is practically constant and the reluctance of the other flux path through one in this one. River path lying movable iron anchors exposed to an opposing force is changed automatically in the sense of voltage equalization.

According to the invention acts on the movable iron armature in addition to the magnetic force of the controlled flux path and the opposing force another one of size and phase the load-dependent auxiliary worker in such a way that the voltage regulation of the Load is independent.

The invention is explained in more detail with reference to the drawing.

N is the network with the fluctuating voltage, n are the connecting conductors for the constant tension. The primary winding I is connected to the network N, which comprises the two legs i of two iron cores 2, 3. On the other thighs 4, 5 of the iron cores sit secondary windings 2i, 22 in an additional circuit. By doing a yoke of the iron core 2 is a movable iron armature 6 of such a shape, that when it rotates, the magnetic resistance of the flux path of core 2 changes. The series of windings 2i, 22 produce two oppositely directed windings Additional voltages, of which the additional voltage of the winding 22 is roughly unchangeable is, while the additional voltage of the winding 2.1 is when the armature rotates 6 changes relatively strongly, namely it increases in the sense of rotation of the armature of the arrow drawn. A spring 7 acts on the shaft of the armature 6, which is attached at one end to a lever arm 8. The arm 8 sits on one Shaft 9, on which an armature io is also arranged. One acts on the shaft 9 Spring ii a. The armature io is located in the mouth of an electromagnet 12, the Winding connected to the tapping points via a resistor arrangement 13 is. The load current flows through the resistor arrangement according to phase and size adapted auxiliary current generated by a current transformer 14. This will the constant extraction voltage for the magnet i2 is an artificial voltage drop or an additional voltage superimposed, depending on the size and. Phase of the load current. This additional tension, the shape of the armature io, the forces the springs 7 and i i and the length of the lever arm 8 are matched to one another in such a way that that regardless of the phase and size of the load at the extraction point always the same tension prevails.

The arrangement works as follows: Assuming that the tension N increases, so that the flux in the iron core a also increases. The increase in this flow causes the armature 6 to rotate in the direction of the arrow against the opposing force of the spring 7 acting on it . Balanced for the extraction point iz. If a lot of current is now drawn from the extraction point, the increase in flux in the iron core 2 is reduced. The armature 6 consequently rotates in the opposite direction of the arrow and thereby increases the magnetic resistance in the core 2. However, this results in a reduction in the flux. As a result, the additional voltage of the winding 21 is reduced and the increase in voltage of the network 7a is not sufficiently compensated. Now, however, the secondary current of the current transformer 14, which is proportional to the load current, generates an additional voltage in the resistor arrangement 13 which, in the arrangement of the exemplary embodiment, is separated from the voltage of the tapping point n. The magnetic force acting on the armature io decreases as a result, and the spring ii, which is stronger than the spring 7, rotates the armature in the direction of the arrow. As a result, the lever arm 8 is also pivoted in the direction of the arrow and the spring 7 is relaxed somewhat. This relaxation causes an additional rotation of the armature 6 in the direction of the arrow, which causes a reduction in the magnetic resistance in the core 2, an increase in the flux and thus an increase in the additional voltage in the winding 21. The resistance arrangement 18, the shape of the armature 6, io, the magnetic forces acting on these armatures, the tensions of the springs 7 and ii and the length and position of the lever arm 8 can easily be adjusted so that the voltage regulation is now independent of the load. Since the phase of the secondary current of the current transformer 14 also changes with the phase of the load current, the phase of the voltage supplied to the winding of the magnet i2 also changes, and consequently the magnetic force of the magnet 12 is also dependent on the phase of the load. It is therefore possible to make the voltage regulation independent of the phase of the load if the constants of the resistor arrangement 13 are set accordingly.

The invention is also applicable to analogous arrangements such as such for example is shown in Fig.2, useful. In Fig. 2 I is again the primary winding, which sits on the leg i. The secondary winding now in the main circuit 1I sits only on leg 5, while leg 4 is winding-free.

Claims (1)

PATENT CLAIM-: Regulating transformer with two parallel flux paths for drawing alternating current of constant voltage from a fluctuating network Voltage at which the magnetic resistance of one of the flux paths is practically constant and the reluctance of the other flux path through one in this one River path lying movable iron anchors exposed to an opposing force is automatically changed in the sense of voltage equalization, characterized in that that on the movable iron armature (6) besides the magnetic force of the controlled flux path and the opposing force an auxiliary force dependent on the size and phase of the load acts in such a way that the voltage regulation is independent of the load.