SE511372C2 - Method and apparatus for controlling transformer / reactor and transformer / reactor - Google Patents

Abstract

The invention relates to a method for regulating an induced voltage in transformer, alternatively reactive power of a reactor, wherein a winding (5; 26) is achieved with an insulating electric conductor including at least one current carrying conductor, a first layer having semiconducting properties arranged to surround the conductor, a solid insulation layer arranged to surround said first layer, and a second layer having semiconducting properties arranged to surround the insulating layer, wherein a regulating winding (3, 22) is arranged around a magnetic flux carrier (1), and wherein the length of said regulating winding around the magnetic flux carrier is varied. The invention also relates to an arrangement for the realization of the method and a transformer/reactor including such an arrangement.

Description

i. Miu m h i nl mn i .m un »m i .. ..._- i .. 511 372 10 15 20 25 30 35 the requirement for an outer box in which the transformer must be housed when oil cooling is used.

However, it has proved possible to largely replace oil-cooled power transformers with dry-type transformers of a new type. The term dry transformer or reactor refers to a transformer / reactor which is preferably air-cooled. This new type of dry transformer is equipped with a winding made of high-voltage insulated electrical conductors, with fixed insulation, of a similar design as cables for the transmission of electricity (eg so-called PEX cables).

Thus, dry transformers can be used at considerably higher powers than was previously possible.

In the case of reactors, they comprise a core which is provided with only one winding. In other respects, what has been said above regarding transformers is largely relevant also with regard to reactors. It should be noted in particular that even large reactors are oil-cooled.

For various reasons, it is often necessary to be able to regulate and adjust the voltage of a power transformer. For example, it may be necessary to maintain a constant secondary voltage when the primary voltage for some reason varies; varying the secondary voltage; providing a reduced voltage to start a rotating machine; providing a neutral point for earthing or to take care of unbalanced current in different circuits, etc. For this reason, transformers are provided with an adjustable winding, hereinafter referred to as control winding, with which the transformer's turnover can be regulated.

In accordance with known technology, see for example “the J&P Transformer Book” (A.C. Franklin et al, llth Edition 1983), for conventional power transformers in the higher power range, ie oil-cooled transformers, this regulation can take place in different ways. The two most common ways are the use of so-called switching switches where switching can take place between different voltage outlets inside the transformer tank, which can only take place when the transformer is out of operation, and the use of so-called winding switches where switching takes place between different voltage outlets 10 15 20 25 30 511 372 extended outside the transformer tank, which can thus take place during operation.

In this switching, parts of said control winding are thus connected to the affected winding side so that the desired voltage control is obtained. This must be done step by step where a typical value of the step length between outlets is l0 winding turns. This arrangement has the disadvantage that, despite a relatively large number of outlets, which is necessary to provide a reasonable number of control possibilities, the control possibilities are still limited, and one is far from a stepless regulation.

Correspondingly, reactors can be provided with a control winding with which the reactive power of the reactor can be regulated, and which presents corresponding problems.

The object of the present invention is to provide a method and an apparatus which solve the above problems and allow improved control possibilities for transformers, alternatively reactors, especially of the dry type. An additional object is to provide such an improved transformer / reactor.

These objects are achieved by a method of the kind specified in the preamble of claim 1, which has the features stated in the characterizing part of the claim, and by a device in accordance with the preamble of claim 8 and with the features stated in the characterizing part of this claim. Furthermore, the object of a transformer / reactor is achieved in accordance with claim 32.

Thus, the present invention relates to a method of regulating induced voltage in a transformer, alternatively regulating reactive power of a reactor, wherein a controllable winding is arranged around a core, which is characterized in that a variable part of the controllable winding is transmitted to or from at least one storage means.

The corresponding device is characterized in that it comprises means for transferring a variable part of the adjustable winding to or from at least one storage means.

Through the described method, the advantage is obtained that the length of the control winding can be regulated continuously in a very simple manner. An important prerequisite for this,.: | In um 511 372 10 15 20 25 30 35 it should be possible, however, that the winding in the transformer / reactor consists of the above-described type of high-voltage insulated electrical conductor, so that the transformer / reactor is of the dry type. Thus, it is stated as a particularly advantageous feature that the device has a winding comprising at least one live conductor, that a first layer with semiconducting properties is arranged enclosing the conductor, that a solid insulating layer is arranged enclosing said first layer, and that a second layer with semiconducting properties are arranged enclosing the insulating layer. This achieves the additional advantage that it will also otherwise be possible to apply technology that was previously only known from the low-voltage range and electronics.

The insulated conductor or high voltage cable used in the present invention is flexible and pliable and of the type further described in PCT application SB97 / 00874 and SE97 / 00875. Further description of the insulated conductor or cable can be found in PCT applications SE97 / 00901, SE97 / 00902 and SE97 / 00903.

According to a preferred embodiment of the invention, the insulated conductor or cable used in the device is flexible and this property is maintained by the cable during its service life. The different layers in the insulated conductor or cable are designed so that they adhere to each other even when the cable is bent.

According to a special feature, the adjustable winding is arranged on a rotatable control winding drum.

As an advantageous feature, the process is characterized in that the transformer / reactor comprises a main winding with which the control winding can be connected. Furthermore, the method is characterized in that, based on a zero position when there is no winding on the control winding drum, the induced voltage / reactive power of the respective transformer / reactor is increased by winding winding on the control winding drum in the same direction as the direction of the main winding. , and the induced voltage / reactive power of the respective transformer / reactor is reduced by winding winding on the control winding drum in the opposite direction to the direction of the main winding, the maximum variation of the number of winding turns being + -N, where N is the number of winding turns available on the control winding drum. This has the advantage that the winding can either be varied steplessly or with any number of revolutions, in contrast to known technology where only predetermined combinations of revolutions were possible.

Of course, a winding of control winding in one direction corresponds to a unwinding of control winding in the opposite direction. If the entire control winding is wound in one direction, which is assumed to be the same as the main winding winding direction, and the maximum induced voltage / reactive effect is therefore obtained, a reduction of the voltage / EFFECT takes place first by unwinding control winding before it can begin to be wound in the opposite direction. .

As regards the device according to the present invention, it comprises the advantageous features that the adjustable winding is arranged on a rotatable control winding drum, and that the storage means comprises a rotatable storage drum. The winding etc. unwinding takes place preferably in that the control winding is arranged on a rotatable member, such as said drum, but other solutions are also conceivable.

According to another advantageous feature, the storage means may be comprised of a second winding around a core. For example, the adjustable winding may be arranged on a core leg belonging to a phase of a multiphase system and the storage means on a core leg belonging to a further phase of the multiphase system. This has the advantage of enabling phase shift.

Furthermore, the device is characterized in that the transformer / reactor comprises a main winding and that the control winding is provided with means for electrical connection to the main winding. The device is also characterized in a particularly advantageous manner in that, on the basis of a zero position when there is no winding on the control winding drum, the induced voltage / reactive power of the respective transformer / reactor is increased in that said means for transmitting winding are suitable. to wind up winding on the control winding drum in the same direction as the direction of the main winding, and the induced voltage / reactive effect of the respective transformer! . The feeder / reactor is reduced in that said means for transfer are suitable for winding winding on the control winding drum in the opposite direction to the direction of the main winding, the maximum variation of the number of winding turns being + -N, where N is the number of winding turns available on the control winding drum.

The device further has the advantageous feature that the means for transmission comprise a drive means for rotation of a control winding drum and drive means for rotation of the storage drum. These drive means are preferably in the form of at least one motor and a device for belt drive of the respective drum. Thus, it is possible for a common motor to drive both the control winding drum and the storage drum. Another possibility is that each drum has its own motor. The transformer can also be of the multiphase type. In the case of a three-phase transformer, for example, which thus has three control windings, all of which can be independent of each other, it is conceivable that each of these control windings is driven by its own motor so that there are a total of three or six motors. , or that all phases are regulated in the same way, whereby the number of motors then becomes one or two, depending on whether this motor also drives the respective storage drum. Alternatives other than belt drive are of course possible.

According to a further feature, the control winding drum and the storage drum are rotatable in two directions.

Said means for electrical connection to the main winding are marked according to a feature in that it may comprise a winding coupler. With the help of this winding coupler, the winding can be varied with one winding revolution at a time.

This has the advantage of providing a significantly higher resolution and the possibility of more precise regulation than previously known technology.

As an alternative, the core can be interrupted by an insulating member, whereby grounding or connection to the main winding takes place by means of a conductor emanating from the insulated member. The insulating member advantageously consists of a rotatable disc in an insulating material, or corresponding device. With the aid of the rotatable disk, a stepless variation of the length of the control winding can be possible, which is advantageous.

When the control winding drum is preferably arranged around the core, it is advantageously built up of at least two drum parts, which are joined together in radial direction to form the drum.

According to a particularly advantageous feature, it is stated that the insulated electrical conductor of said winding has a second layer which is connected to a predetermined potential, preferably earth potential.

In accordance with the device according to the invention, the high-voltage electrical conductor can be designed in several advantageous ways. It preferably has a diameter which is in the range 20-250 mm and a conduit area which is in the range 80-3000 mm 2. Furthermore, the first layer is essentially at the same potential as the live conductor. The second layer is preferably arranged so that it constitutes a substantially equipotential surface enclosing the live conductor (s). According to other designs, at least two adjacent layers have substantially equal coefficients of thermal expansion, the live conductor may comprise a number of strands, only a few of the strands being uninsulated from each other, and finally each of the three layers may be As a further feature, it is stated that at least one of the control winding drum or the storage drum is provided with means for connecting said second layer of the winding with semiconducting properties to a predetermined potential, preferably earth potential. . These bodies can be designed in several ways.

The control winding drum is also advantageously provided with a means for grounding the conductor in the winding. This member is advantageously designed as a trailer contact, for example in two halves.

The present invention will now be described in detail with reference to the accompanying drawing figures, in which various embodiments, as illustrative examples, of the invention and its constituent parts are shown: Figure 1 is a schematic diagram of a device according to the invention, Figure 2 is a schematic diagram of an embodiment of the device according to the invention, where the number of turns of the control winding is varied by one revolution at a time by means of a winding coupler. Figure 3 is a schematic diagram of a second embodiment of the invention, the winding can be varied steplessly, Figure 4 is a principle sketch of a variant of grounding of the winding and Figure 5 is a principle sketch showing another variant of grounding of the winding.

Figure 1 shows a transformer core 1 consisting of yoke and two legs, a main winding 2 being arranged around one leg and a control winding 3 arranged around the other leg. The main winding can either be a primary winding or a secondary winding. The control winding is thus used to vary the turnover of the transformer. The control winding 3 is arranged in the form of winding turns 5 wound on a rotatable drum 6. The drum 6 is here divided into two drum halves 7,8. Other dividing forms of the drum are also conceivable, to facilitate installation around the core legs.

The drum is equipped with at least one flange for belt drive by means of a motor (not shown). The control winding thus functions as a variable coil. The number of winding turns on the control winding drum is varied by means of a rotatable storage drum 12 for the winding 5. The storage drum 12 is also preferably belt-driven with a motor.

In the following figures, the same or corresponding elements referred to in Figure 1 have been provided with the same reference numerals. The designations A and B in Figures 2, 4 and 5 generally show connection points for the windings, for example to earth or the main winding.

The embodiment shown in Figure 2 relates to a control winding where the length of the winding is varied stepwise by means of one winding revolution at a time. This is done by means of a winding coupler which is known per se (alternatively called a load coupler) 15.

Figure 3 illustrates a second embodiment where the winding of the control winding drum can be varied steplessly. Shown here is a core 18 which is divided into two parts 18a, 18b by means of a disc 20 in insulating material. The disc is rotatable and is connected in its center to an output conductor 21, 2la, which enters and through the core part 18b, and to a radial conductor 22a in the disc which is connected to the winding 22. The conductor 21, 2la is thus connected to the winding 22 via the conductor 22a. The winding 22 of the control winding drum 23 is connected to a main winding, outgoing line or to ground potential, via the conductors 22a, 21 and 2la through said insulating means 20, as shown in the figure. Upon rotation of the disk, a steplessly regulated magnetic flux is obtained through the last turns 21 and 21a. between zero and the flow through a full revolution in the winding 22 .. given by the conductors 22a. This flow can be varied The conductor 21 can be either insulated or in contact with the core 18b.

Figure 4 illustrates a principle for earthing the second semiconducting layer of the winding. The control winding drum is here provided with at least one weakly or moderately conductive ring 28 at one end. This ring is highly resistive, at least IOOQ and preferably IOOOQ, to prevent short circuits. The resistance of the ring can be evenly distributed along the ring or concentrated in areas with high resistance connected with well-conducting material. Along the drum, ie in the axial direction and on the outside of the drum but below the winding itself, there are a plurality of elongate elements 29 arranged at regular distances in a conductive material. These are connected to the ring 28 and thereby connected to each other. Through contact between the outer second layer of the winding with semiconducting properties, the winding will be grounded. The storage drum 12 can also be provided with a corresponding device 30.

Figure 5 shows a variant of earthing of the outer, second layer of the winding with semiconducting properties. The control winding drum is also here provided with a ring 38 connected to ground potential and located at one end of this drum and i ._un || w .. Hm i ... m-.AII-u .__...... .. i ..u \ .Ålliwlh i: | i IH H || l 511 372 10 15 10 extending around the circumference of the drum. Other rings in a conductive material 40 are arranged around the semiconducting layer on the insulation of the conductor 36, at regular intervals from each other so that rings in a winding turn are in contact with corresponding rings in adjacent winding turns. In this way, these rings form at least one continuous electrical connection 42 across the winding, and said connection is grounded by contact at one end of the drum with the existing first ring 38. Alternatively, the storage drum 12 may be grounded correspondingly or both drums be grounded.

The embodiments and variants described above are to be considered only as examples of a non-limiting nature and the invention can thus be varied within the scope of the following claims.

Claims (33)

10 15 20 25 30 35 511 372 ll PATENT REQUIREMENTS A method of regulating induced voltage in a transformer, alternatively reactive power of a reactor, wherein an adjustable winding is arranged around a core, characterized in that the winding is performed with an insulated electrical conductor comprising at least one live conductor, a first layer with semiconducting properties arranged enclosing the conductor, a solid insulating layer arranged enclosing said first layer, and a second layer with semiconducting properties arranged enclosing the insulating layer and that a variable part of the adjustable winding is transferred to or from at least one storage means. Method according to Claim 1, characterized in that the adjustable winding is arranged on a rotatable control winding drum. Method according to claim 2, characterized in that the transformer / reactor comprises a main winding to which the control winding can be connected. Method according to claim 3, characterized in that, starting from a zero position when there is no winding on the control winding drum, the induced voltage / reactive power of the respective transformer / reactor is increased by winding winding on the control winding drum in the same direction. as the direction of the main winding, and the induced voltage / reactive power of the respective transformer / reactor is reduced by winding winding on the control winding drum in the opposite direction to the direction of the main winding, the maximum variation of the number of winding turns being + -N , where N is the number of winding turns available on the control winding drum. Method according to one of Claims 2 to 4, characterized in that the length of the winding on the control winding drum is varied steplessly, whereby the induced voltage and the reactive effect are varied steplessly. Method according to one of Claims 2 to 4, characterized in that the length of winding present on the control winding drum is varied by at least one winding revolution at a time, whereby the induced voltage or the reactive power is varied in steps corresponding to one winding revolution. A method according to any one of claims 2-6, characterized in that the storage means comprises a rotatable storage drum, wherein the control winding drum is rotated by means of drive means and the storage drum is rotated by means of drive means so that winding is transferred from the control winding drum to the storage drum or vice versa. Device for regulating induced voltage in a transformer, alternatively reactive power of a reactor, wherein the transformer / reactor comprises at least one core and wherein the device comprises a controllable winding (3; 22) arranged around a core, characterized in that the winding is out provided with an insulated electrical conductor comprising at least one live conductor, a first layer with semiconducting properties arranged enclosing the conductor, a solid insulating layer arranged enclosing said first layer, and a second layer with semiconducting properties arranged enclosing the insulating layer, and that the device further comprising means for transmitting a variable part of the adjustable winding (3; 22) to or from at least one storage means (12). Nordning according to Claim 8, characterized in that the adjustable winding (3) is arranged on a rotatable control winding drum (6). Device according to one of Claims 8 to 9, characterized in that the storage means comprises a rotatable storage drum (12). 10 15 20 25 30 35 2511 372 13 ll. that the storage means comprises a second winding arranged Device according to one of Claims 8 to 10, characterized by around a core. The cleavable winding is arranged on a core leg belonging to a device according to claim 11, characterized in that it regregates a multiphase system and that the storage means comprises a winding arranged on a core leg belonging to a further phase of the multiphase system. 13. that the transformer / reactor comprises a main winding (2) and that the control winding (3; 22) is provided with means for electrical connection to the main winding. Device according to one of Claims 9 to 12, characterized by Device according to claim 13, characterized in that, with the outer winding drum, the induced voltage / reactive power of the respective transformer / reactor is increased by said means for transmitting winding. (5) are suitable for winding winding on the control winding drum (6) in the same direction as the direction of the main winding, and the induced voltage / reactive power of the respective transformer / reactor is reduced by said transfer means being suitable for winding up. roll winding (5) on the control winding drum (6) in the opposite direction to the direction of the main winding, the maximum variation of the number of winding turns being + -N, where N is the number of winding turns available on the control winding drum. A device according to any one of claims 8-14, characterized by the actuation of the control winding drum and drive means for rotation of the storage drum. Drive means is in the form of at least one motor and one device. Device according to claim 15, characterized in that said for belt drive of the respective drum. 511372 10 15 20 25 30 35 14 17. that the control winding drum (6) or the storage drum (12) is a device according to any one of claims 10-16, characterized by rotatable in two directions. Device according to any one of claims 13-17, characterized in that the means for electrical connection to the main winding comprises a winding coupler (15) by means of which the length of the winding is varied by one winding revolution at a time. 19. that the core is interrupted by an insulating member (20), wherein the device according to any one of claims 13-17, characterized by coupling of the adjustable winding (22) takes place through said insulating member and through the core, to obtain a stepless varying the length of the adjustable winding. The revolution (22a, 21, 21a) of the adjustable winding encloses the device according to claim 19, characterized in that the latter has a magnetic flux which can vary between zero and the flux through a full revolution in the winding (22). 21. said insulating member being constituted by a rotatable disc (20) Device according to any one of claims 19-20, characterized in an insulating material. 22. that the control winding drum consists of at least two drum parts. Device according to any one of claims 9-21, characterized by (7, 8), which are joined in the radial direction to form a drum. 23. in that the second semiconducting layer is connected to a predetermined potential according to any one of the preceding claims. 24. the semiconductor layer is connected to earth potential. Device according to claim 23, characterized in that the second 10 15 20 25 30 35 511 372 15 25. in that the layers of the insulated electrical conductor are arranged. Device according to one of the preceding claims, characterized in that they adhere to each other even when the insulated conductor is bent. 26. that at least one of the control winding drum (6) or legal device according to any one of claims 10-25, characterized by the ring drum (12) is provided with means for connecting said second layer with semiconducting properties to a predetermined potential. 27. The determined potential is earth potential. Device according to claim 26, characterized in that the 28. characterized in that both the control winding drum (6) and the storage device according to any one of claims 26 or 27, the sensing drum (12) are provided with means for connecting said second layer with semiconducting properties to the predetermined potential. A device according to any one of claims 26-28, characterized by a1 comprising at least a partially conductive ring (28) connected to the predetermined potential and located at one end of the drum and extending around its circumference , the ring being connected by means of a plurality of axially and on the outside of the drum, at regular intervals, elongate members (29) arranged in a conductive material, the winding (26) lying on top of said elongate members so that the second layer with semiconducting properties enters contact with said elongate means and that connection to the predetermined potential of the winding thereby takes place at regular intervals. The means for connecting to a predetermined potential. A device according to any one of claims 26-28, characterized by a1 comprising at least a partially conductive first ring (38) connected to the predetermined potential and located at one end of the drum and extending around the drum. circumference, (40) a plurality of second rings in a conductive material, which D11s are arranged around the insulated conductor (36) in the winding at regular intervals from each other so that rings (40) in a winding turn are in contact with the corresponding rings (40) in adjacent winding turns, the rings forming at least one continuous electrical connection across the winding, and said connection being connected to said predetermined potential at one end of the winding by contact with said first ring. Device according to claim 29 or claim 30, characterized in that the partially conductive (first) ring is highly resistive. Transformer / reactor comprising a core and an adjustable winding, characterized in that it comprises a device according to any one of claims 8-31. Transformer / reactor according to Claim 32, characterized in that it is a dry transformer / reactor.