SE511136C2 - Stepless induction controlled voltage regulator, control winding for such and control method - Google Patents

Abstract

A step-free induction controlled voltage regulator, primarily for high-voltage regulation, includes a magnetic circuit based upon a magnetizable core (1) having one or more flux paths or legs (2) with at least one winding (3) supplying the output voltage (U). The output winding leg (2) includes a regulation arrangement (4-8) comprising a rotatable rotor means (4) carrying a regulator winding (6) electrically connected in series with the output winding (3). A compensator winding (7) can be arranged around the leg (2) and electrically connected in series with a capacitor means (8). At least one of the regulator winding (6) and the supply winding (3), or a part thereof, is wound by a high-voltage cable comprising at least one conductor surrounded by a first layer having semiconducting properties, a solid insulating layer, and a second layer having semiconducting properties.

Description

F! L fl U) (_ 511 136 from the transformer. The current power transformers and line transformers, such as those mentioned above and used in voltage supply networks, include sockets for voltage regulation. They are subject to mechanical wear and electrophysical erosion due to contact only discharge. Step-by-step voltage regulation and variable contacts are required for connection to various sockets.

The invention in brief The disadvantages of known voltage control are avoided by means of a stepless induction-controlled voltage regulator according to the present invention. The characteristic features are found in the fact that the magnetic circuit on the legs of the output winding comprises a rotatable rotor member which carries a control winding, which is electrically connected in series with the output winding.

An important prerequisite for enabling the achievement of such a voltage regulation of high voltages, ie 36 kV up to 800 kV, is that at least one of the control and output windings, or a part thereof, is constructed of a high voltage cable which comprises a conductor, a first layer with semiconducting properties, a solid insulating layer and a second layer with semiconducting properties.

The transformer / reactor is thus of the so-called dry type.

The use of such a high voltage cable makes it possible to "enclose" the electric field inside the cable insulation. This means that it is possible to design induction-controlled voltage regulators for high-voltage applications.

Advantageously, the layers are arranged to adhere to each other even when the cable is bent. This provides good contact between the layers during the entire life of the cable. In order to avoid the behavior as a rotating motor, the rotor member is suitably restricted by a self-locking member to allow only one rotation of a revolution in the forward or reverse direction. The control connection of the control winding to the output winding is preferably made by means of flexible cables, preferably of rubber elastic type.

The higher reluctance generated in the air gap between the core and the rotor member can be compensated by means of an additional compensator winding which surrounds the magnetic flux. This compensator winding is electrically connected in series with a capacitor such as a separate closed circuit.

Such a compensator winding loaded with a capacitor forms a negative reluctance R; = -nl w * C. The number of winding turns n and the regulation of the capacitor's capacitance C can be chosen in such a way that an equivalent is obtained to the positive reluctance of the air gap RL = l / A uy where l is the (effective) length of the air gap, A is the magnetic core cross-sectional area and u¿ is the permeability to air.

Typical values of capacitance C are of the order of a few microfarads to a few millifarads for voltages of the order of 1 kV.

By means of the transformer or reactor construction described above, it is possible to obtain a stepless induction-controlled voltage control. This is due to the fact that the voltage U: induced in the control winding 6 is determined by the angle of rotation d (between the direction of the magnetic flux in the leg 2 and the symmetry surface of the rotor member 4) Uf = n-co- (Ilcos d. This results in U; = nni ® for d = O and in Uf = n fl- a fl-® for d = K. The zero position (Uf = 0) is at Q = K / 2.

Various applications are within the skill of the artisan.

For example, it is thus possible to apply the present invention to single-phase induction-controlled voltage h) (D 511136 regulators). Devices with load terminal change, ie a single-phase induction-controlled voltage regulator which is integrated in a transformer, can also be realized. performed with individual phase control as well as with a common phase control.

Brief Description of the Drawings These and other features and advantages of the present invention will become more apparent from the following detailed description of exemplary embodiments thereof, which are illustrated in the accompanying drawings, in which: Fig. 1 shows a principle view of a portion of a transformer core; according to the invention seen from the side, Fig. 2 shows the same part of the transformer core aterger in a direction indicated by the arrow A in Fig. 1, Fig. 3 shows a three-phase transformer in which the principle of invention is realized and Fig. 4 shows a cross-sectional view of a high voltage cable used in the control windings of the present invention.

Detailed description of the invention The invention will now be described in detail with reference to some preferred embodiments, the principle of these being shown in the accompanying drawing figures. The same reference numerals used in different figures refer to similar or other equipment having a corresponding function. Figs. 1 and 2 show only the part of the voltage regulator which is essential for the present invention. 10; _ | Figs. 1 and 2 show a part of a transformer or reactor core 1, usually in the form of a magnetic stable packet which is part of the magnetic circuit of the transformer or reactor. The magnetic circuit may comprise one or more river paths 2 (or legs). as they are referred to in the following description) and in one of them a zone 5 with reduced permeability is arranged in the form of a rotatable rotor member 4, which is arranged to obtain stepless induction-controlled voltage control. The rotor member 4 is mounted on a shaft 10 in the zone 5. The rotation of the rotor member 4 is limited to at least half a revolution, so that the angle of rotation d (between the direction of the magnetic flux in the leg 2 and the symmetry surface of the rotor member 4) will at least extend between 0 and R. The rotation is limited in the forward and rear direction by means of a worm gear. 9 as shown in FIG.

The rotor member 4 is made of magnetizable material and is provided with a recess 11 in its peripheral surface. A control winding 6 is wound in the rotor recess 11, which control winding 6 is connected in series with the output winding of the transformer or reactor 3. The connection cable 12, Fig. 2, is of a flexible type which allows a limited rotation of the rotor member 4. The output voltage U is thus generated over a series circuit. of the output winding 3 and the control winding 6.

A compensator winding 7 is wound somewhere around the leg 2 which comprises the rotor member 4.

The compensator winding 7 forms a closed circuit which comprises a capacitor means 8.

To enable regulation of high voltages, ie within the range of approx. 36 - 800 kV, is at least one of the regulator and output windings 6 and 3, or a part of any of them, wound using a high voltage cable 61 of the type shown in Fig. 4 as an example. The high voltage cable used in the present invention is flexible and pliable and of the type further described in WO 97/45919 and WO 97/45847. Further description of the cable can be found in WO 97/45918, WO 97/45930 and WO 97/45931 .

Such a high voltage cable 61 may comprise one or more electrical conductors 631. The cable embodiment shown in Fig. 4 comprises an insulation and the conductor 631 is in direct connection with a first layer 632 with semiconducting properties. The first layer 632 is in turn surrounded by a solid insulating layer 633, which is then surrounded by a second layer 634 with semiconducting properties.

In Figure 4, which shows the detail of the invention relating to the cable, the three layers are arranged so that they adhere to each other even when the cable is bent. The cable shown is flexible and this property is maintained by the cable during its service life. 637 Preferably, the layers -_, 633, 634 are made of the same plastic material or of other materials having the same coefficient of expansion. This achieves the important advantage that defects, cracks or the like are avoided during thermal movement in the winding. The plastic material in the first and second layers 632, 634 has an electrically conductive material inserted therein.

Fig. 3 shows the principle of a three-phase transformer invention. Transform and 2C, constructed according to the present dryer core 1, comprise three legs 2A, 2B, each leg carrying a primary winding 15, which supplies the transformer with a voltage to be transformed, and an output winding 3 from which the output voltage is obtained. As described above with reference to Figs. 1 and 2, each leg comprises a control arrangement 4-8. Although for the sake of clarity it is not shown in Fig. 3, each air gap can be compensated with a compensator winding 7 and an associated capacitor 8.

The three individual phase control arrangements 4 - 8 thus mounted in each of the phase legs 2A, 23, 2C are operated either together, if no voltage symmetry is expected in the transformer, or individually if each phase should be controlled individually. Although the present invention has been described above with respect to transformers or reactors, it is obvious that it also applies to similar apparatuses, for example in autotransformers and in suction transformers.

Claims (21)

t. J (J) 30 511 136 P A T E N T K R A V A stepless induction voltage regulator, in particular a transformer or a reactor, comprising a magnetic circuit comprising a magnetizable core (1) having two or more flow paths or legs (2), at least one of which legs is surrounded by an output winding (31, which regulator is characterized in that the leg (2) with the output winding (3) has a control arrangement (4 - 8) comprising a rotatable rotor member (4), which carries a control winding (6) connected in series with the output winding (3), and in that at least one of the control windings (6) and the output winding (3), or a part thereof, is wound with a high voltage cable (E1) comprising a conductor (63l), a first layer (632) having semiconducting properties, a solid insulating layer (633) arranged around the first layer (632) and a second layer (634) having semiconducting properties arranged around the insulating layer (633). Regulator according to claim 1, characterized by a compensator winding (7) arranged to surround the leg (2) provided with the output winding (3) and electrically connected in series with a capacitor means (8). Regulator according to claim 1 or 2, characterized in that the rotation of the rotatable rotor member (4) is limited to at least half a revolution in the forward and rearward direction by means of a self-locking member (9). Regulator according to Claim 3, characterized in that the self-locking member (9) is of the snack gear type. Regulator according to one of the preceding claims, characterized in that the cable (12) which connects the output winding (3) to the control winding (6) is of the rubber-elastic type. A controller according to any one of the preceding claims, characterized in that the controller is a multiphase transformer, wherein the output winding (3) on each phase leg (2) comprises a control arrangement (4 - 8) for independent control of each phase. A controller according to any one of claims L - 5, characterized in that the controller is a multiphase transformer, wherein (3) on each phase leg (2) comprises a <4 _ 8): the output winding control arrangement wherein the control windings (6) on these legs are interconnected to obtain a unified regulation. A controller according to any one of claims L - 5, characterized in that the controller is an autotransformer or a suction transformer. Regulator according to one of Claims 1 to 8, characterized in that the layers (632, 633, 634) are arranged to adhere to one another even when the cable is bent. Control winding (6) for an induction-controlled voltage regulator, in particular a transformer or reactor means, comprising at least one output winding (3), according to any one of the preceding claims, characterized in that at least one of the windings (3, 6), or a part of any of these, (631), a first layer (631), comprises at least one live conductor (632) having semiconducting properties arranged around the conductor (633) arranged around the first layer (634) (633). a solid insulating layer (632) with semiconducting properties and a second layer arranged around the insulating layer Winding according to claim 10, characterized in that the potential of the first layer (632) is substantially equal to the potential of the conductor (631). Winding according to claim 10 or 11, characterized in that (634) are arranged to substantially (631). that the second layer constitutes an equipotential surface surrounding the conductor Winding according to Claim 12, characterized in that it is connected to a specific potential. second layer (634) UI 20 N U »30 511 136 10 Winding according to claim 13, characterized in that the specific potential is earth potential. Winding according to any one of claims 10 to 14, characterized in that at least two of the layers (632 - 634) have substantially the same coefficient of thermal expansion. Winding according to one of Claims 10 to 15, characterized in that the current-carrying conductor (631) comprises a number of strands. Winding according to any one of claims 10 - 16, characterized in that each of the three layers (632 - 634) is fixedly connected to adjacent layers along substantially the entire connecting surface. Winding according to any one of claims 10 to 17, characterized in that the layers (632, 633, 634) are made of the same plastic material, wherein the plastic material of the first and second layers is supplied with an electrically conductive material. A method for voltage control on an electrical line and / or for reactive power control in plants comprising at least one transformer or a reactor with at least one of these windings, or a part of any of these, performed with a high voltage cable type according to any one of the preceding claims, where the voltage control is effected by means of induction control. Method according to claim 19, characterized in that the induction control is obtained by rotating a rotor means included in the river path or legs of the transformer / reactor, its permeability being affected by the current fed through a control winding connected in series with the output winding of the transformer / reactor. . Method according to claim 20, characterized in that the voltage induced in the control winding is determined by the angle of rotation between the direction of the magnetic flux and the symmetry surface of the rotor member according to the idealized equation U; = n fl iqlcos a, where U: = induced voltage, n = number of revolutions, w = 2nf, where f = the frequency of the current flow through the wind- ® = magnetic flux and a = the angle of rotation. you