EP1959460A2 - Method for manufacturing a transformer - Google Patents

Abstract

The polyphase transformer (101) has several toroidal cores (102) adjacently arranged in an axial direction. The toroidal cores support phase windings of different phases. The connecting points of the phase windings of two adjacent toroidal cores are offset from one another in a peripheral direction. The offset of the geometric angles between the connecting points of the phase windings of two adjacent toroidal cores approximately corresponds to the phase shift to the electric phase angle between the voltage signals of these toroidal cores (102).

Description

The invention relates to a high-voltage winding of a toroidal transformer, and their production method, for distribution transformers from a power of 100 kVA and a voltage from 6000 volts, based on toroidal technology.

The winding of the high voltage of toroidal distribution transformers high power and voltage, for example, 2,000 kVA and 20,000 volts, is very complicated, time-consuming and thus expensive. The high-voltage winding must be divided into several segments, so that the position voltage of the high-voltage winding can be reduced, and the reliability can be ensured. For example, at a voltage of 20,000 volts, 10 segments are provided. The voltage per segment is 2,000 volts. The layer tension is thereby reduced accordingly to a tenth. Furthermore, the voltage resistance to the low-voltage winding must be ensured.

It has therefore already created winding devices with which the winding of such transformer windings is simplified. In the EP 0761 009 A1 For example, a winding device is described, in the small winding rollers with winding material along a ring core encompassing leadership through the toroidal core be moved while Wiicklungsmaterial is wound on the toroidal core. However, this device is very expensive and the dielectric strength is limited to realize. In addition, it is necessary to wind first winding material on the small, can be passed through the toroidal winding rollers, which requires additional time. Furthermore, it is only possible to apply one winding at a time to the toroidal core at the same time. For larger toroidal cores with a plurality of juxtaposed windings (segments), therefore, it takes a long time to wind all the transformer windings.

From the DE 44 26 138 C2 is a mold for a transformer coil with control of the potting known, wherein a collar-like part of the free end of a movable shell part together with a fixed edge portion forms a funnel-like filling slot in the longitudinal direction of the coil and the other, solid shell portion serves as a holding element for connecting elements of the coil during potting and the filling slot is positioned on the circumference in the region of the connection elements, so that this region can be viewed from the outside through the filling slot, at least when the cover part is slightly open.

From the DE 1 916 637 A A method of winding closed cores with wire is known, in which a wire coil is parallel to a bobbin, a wire is drawn from the wire bobbin and guided by a guide wheel and wound up in layers on the bobbin.

From the WO 95/12887 A1 a method for winding a closed ring core for high power transformers and chokes is known in which a winding device has a winding to be wound around the toroidal leg guide and a plurality along this guide through the toroidal core transportable, unrollable winding rollers.

There is therefore in particular the task of creating a winding device and a high-voltage voltage winding of the type mentioned above, with which the winding can be simplified and accelerated, and the necessary dielectric strength against the low-voltage winding of the transformer can be realized.

The achievement of this object is in particular that at least one winding station with one on the winding support, consisting of two voltage-resistant half-shells with side flange (at least one side flange with an insulated cavity for the implementation of the line material) of insulating high strength, which to a voltage-resistant round Unit assembled around the closed ring core, or the winding support by means of a casting mold around the toroidal core in a Druckgelierverfahren as a whole, for receiving the segments of the high voltage winding of the transformer, consisting of at least one electrical conductor and at least one insulating material with a winding carrier acting on the holding and Drehlagerung for rotatably supporting the winding support, is provided, which holding and pivot bearing a plurality of peripherally acting on the winding support rollers or the like rolling elements of which at least one, is connected to the drive and brake device to drive and decelerate the winding support so that the electrical conductor and the insulating material can be wound onto a closed ring core.

This makes it possible to wind on a voltage-resistant winding carrier made of insulating material, which engages around a closed ring core and is rotated about the toroidal core cross-section. By using the voltage-resistant winding carrier, the other insulation measures can be significantly reduced. Furthermore, it is not necessary to first divide the ring core in half in order to postpone the windings can. The manufacture of a toroidal distribution transformer and the use of the physical advantages, in particular the much higher efficiency and the resulting reduced operating costs of a closed ring core, thereby significantly simplified.

The winding support preferably consists of two high-strength half-shells with side flange, which are equipped with an overlapping latching device, or a hinge and an overlapping latching device, which are firmly assembled before the actual winding process to the closed ring core to a round unit, preferably with a special adhesive, so that the voltage resistance to the low-voltage winding can be guaranteed.

A further embodiment of the winding carrier provides that a divisible casting mold is placed around the closed ring core, with the aid of which the winding carrier, for example in a Druckgelierverfahren can be made directly on the closed ring core and is located after removal of the mold in one piece around the toroidal core and wound can. The winding support has at least one side flange an insulated cavity with respect to the winding space, wherein at the lower end of the cavity an opening in the winding space of the winding support is to carry out the lower Wicklungsanfangs, laterally past the winding, upwards. This winding carrier has six advantageous functions firstly to ensure the basic voltage resistance to the undervoltage, secondly the holder for the high-voltage winding, third to allow the winding process, fourthly, the distance of the segments to each other by spacers allows fifth, a predetermined distance to the low-voltage winding is realized and sixth is the insulation of the lower Wicklungsanfangs by an isolated cavity opposite to the winding in the winding support in a small space upwards allows. For the various fields of application of toroidal distribution transformers and for ensuring the Withstand voltage, the winding carriers can be filled with the segments of the high-voltage winding with one or more insulating materials. For example, with a casting resin under atmospheric conditions, casting resin filling under vacuum, casting resin filling by a Druckgelierverfahren or in a dense implementation with gaseous or liquid insulating materials, for example with nitrogen or a suitable oil. If necessary, the coil carriers can be designed with a cover for insulation, leak-tightness or damage. A further embodiment provides that the winding support can be made electrically conductive to the outside, taking into account that no closed turn around the ring core itself arises. If necessary, this electrically conductive layer can be grounded or set to a defined potential.

For winding a winding carrier this is used in the holding and pivot bearing of the winding device and the winding material is supplied to the winding support of the (the) holding and pivot bearing spaced winding material storage roll (s) supplied. With the drive and braking device, at least one of the rolling elements is driven, or braked and rotated, whereby the winding support on which this rolling body circumferentially engages, gets into rotation. Rolling elements not connected to the drive device serve as a holder for the winding carrier. To avoid frictional forces, these are preferably also rotatably mounted, so that a rolling or rolling of the winding carrier on these rolling elements is possible.

It is advantageous if between the winding support and at least the rolling element (s) connected to the drive and braking device a frictional, optionally positive drive and braking device is provided. A frictional connection can be realized in a structurally simple manner. However, it is also possible to provide a positive connection, for example by a Teeth of the rolling elements and the side flanges of the winding carrier.

As a result of the rotation of the winding carrier, the winding material is removed from the winding material storage roll (s) and wound onto the winding carrier. Since the winding material storage roll (s) are fixed in place and are not moved around the winding support, large winding material storage rolls may be used, on which winding material for winding a plurality of winding supports may be sequentially applied. Windings can be wound for high-power toroidal distribution transformers, for example, over 10 MVA. As a winding material both round wires and flat strips can be used.

A particularly favorable embodiment provides that a plurality of circumferentially juxtaposed winding stations are provided for simultaneously winding a plurality of, in particular arranged on a ring core winding carrier. As a result, a plurality of juxtaposed winding carriers can be wound in groups or all at the same time, as a result of which the time required for winding can be considerably reduced. The number of winding stations can be chosen so that a winding station is available for each winding carrier. This winding carriers can be wound in groups or all at the same time. The control succeeds centrally. In this embodiment, the winding device is preferably divided into two levels, wherein the winding material storage roll (s) are arranged in the upper floor of the winding device. As a result, the usability is much easier. The floors can also be reversed as needed.

It is expedient if at least one winding material storage roll with conductor material and at least one second winding material storage roll with insulation material for the simultaneous, layer-wise winding of Conductor material and insulation material are provided on the winding support. It is also possible to provide three, four, or five winding material storage rolls for simultaneously winding a winding carrier, wherein two, three, or four of the winding material storage rolls carry conductor material and a third, fourth, or fifth winding material storage roll carries insulating material for insulation. When using insulated conductive material, a winding material storage roll is sufficient.

A preferred embodiment provides that the rolling elements are spring-loaded for adaptation to different winding carriers in the diameter and / or the outline shape and are preferably also supported in a damped manner. This makes it possible to wind with a winding station winding support with circular cross-sections and different diameters, without making any structural changes to the winding station, or the holding and pivot bearing. For this purpose, the rolling bearings can be positioned more or less spaced apart from the spring force according to the winding carrier diameter. In addition, it is possible to wrap also winding carrier with a non-round, for example oval cross-section. Due to the sprung bearing, the rolling elements are always in non-circular cross-section of the winding support to this, whereby on the one hand the holder and on the other hand, the rotational drive of the winding carrier are ensured.

It is expedient if in each case a rotary bearing with a drive and brake device is provided for the winding material storage roll (s), so that a defined winding tension can be maintained.

With the winding carrier according to the invention for the high voltage winding of a toroidal distribution transformer, the dielectric strength can be realized and with the winding device, it is possible, the high-voltage windings for a toroidal distribution transformer in a relatively short time to wind.

The object is achieved by a transformer, in particular the high-voltage winding of a toroidal transformer high power, and their manufacturing process, wherein at least one winding station with a winding support, consisting of two voltage-resistant shells with side flange of high-strength insulating material, which to a voltage-resistant round unit to the closed Combined toroidal, for receiving the segments of the high-voltage winding of the transformer, consisting of an electrical conductor and an insulating material with a winding carrier engaging on the holding and pivot bearing for rotatably supporting the winding support, is provided, which holding and pivot bearing a plurality, peripherally acting on the winding support Rollers or the like rolling elements, of which at least one, is connected to the drive and braking device to drive the winding support and decelerate, so that the electrical conductor can be wound on a closed ring core with the insulating material.

In a further embodiment, a transformer, in particular the high-voltage winding of a toroidal transformer high power, and their production method is provided, wherein the winding support is filled after or during the application of the high-voltage winding with solid, liquid or gaseous insulating material.

In a further embodiment, a transformer is provided, wherein at least one side flange of a winding carrier is provided with an insulated cavity, wherein at the lower end of the cavity an opening in the winding space of the winding support, for the implementation of the underlying winding start of the line material of the high-voltage winding upwards located.

In a further embodiment, a transformer is provided, wherein a divisible mold is placed around the closed ring core, with the aid of the winding support, for example, can be made in a Druckgelierverfahren directly to the closed ring core and after removal of the mold is in one piece around the ring core and can be wound.

In a further embodiment, a transformer is provided, wherein the winding support consists of at least two parts with side flange, they are equipped with at least one overlapping latching device, or a hinge and an overlapping latching, the before the actual winding process to the closed ring core to a round unit , preferably with a special stress-resistant adhesive are joined together.

In a further embodiment, a transformer is provided, wherein the winding support consists of several insulating materials, and wherein the winding support has holders for the high-voltage winding, and wherein the side flanges of the winding carrier have a frictional or form-fitting surface, and wherein the winding support spacers for setting a has defined spacing of the segments to each other, and wherein the winding support has holders for setting a defined distance to the low-voltage winding.

In a further embodiment, a transformer is provided, wherein the coil carrier with a casting resin under atmospheric conditions, casting resin filling under vacuum, casting resin filling by a Druckgelierverfahren or in a dense implementation with gaseous or liquid insulating materials, for example with nitrogen or an insulating oil, during or after the winding process is filled.

In a further embodiment, a transformer is provided, wherein the winding support can be carried out to be electrically conductive, taking into account that no closed turn around the toroid itself, this electrically conductive layer can be grounded, or can be set to a defined potential.

In a further embodiment, a transformer is provided, wherein for the simultaneous winding of several, in particular arranged on a toroidal winding a plurality of circumferentially juxtaposed winding stations are provided.

In another embodiment, a transformer is provided, wherein the winding device is divided into two floors, wherein the winding material Vorratsungsrolle (s) in the upper floor of the winding device or vice versa are arranged.

In a further exemplary embodiment, a transformer is provided, wherein at least one winding material storage roll with conductor material and at least one second winding material storage roll with insulation material for the simultaneous, layer-wise winding of conductor material and insulation material are provided on the winding support, or three, four or five winding material storage rollers for simultaneously winding a winding carrier, wherein two, three or four, the winding material storage rolls of conductor material and a third, fourth or fifth winding material storage roll carries insulation material for insulation.

In a further embodiment, a transformer is provided, wherein the rolling elements are sprung for adaptation to the diameter and / or the outline of different winding support and are preferably also supported damped.

The invention also relates to the low-voltage winding of a toroidal distribution transformer, as well as their manufacturing process, a closed multi-stage transformer core high stability, electrically insulated to the outside, as well as on its manufacturing process, for distribution transformers in cast resin technology, from a power of 100 kVA and a voltage from 6000 V, based on the ring core technology.

Low-voltage windings for distribution transformers have very large cross-sections, for example, for 1,000 kVA this is about 1,500 mm2. Such cross sections are made for conventional distribution transformers in the leg construction with wide electrically conductive bands. In a toroidal distribution transformer, no such bands can be used due to the geometric conditions. The undervoltage winding would have to be produced in a very complex form by parallel connection of electrically insulated flat wires. Ring cores for toroidal transformers are today only produced for low power and low voltage in one-stage form. Multistage closed high strength toroidal transformer cores and insulated to the outside for distribution transformers and their manufacturing processes are not known.

There is the problem of mounting a low-voltage winding with a high-section electrical conductor around a closed ring core in order to realize a high-power toroidal distribution transformer (from 100 kVA up to the megawatt range). It is an object to provide a low-voltage winding with a high-section electrical conductor around a closed ring core and a closed multi-stage high-strength toroidal transformer core electrically insulated from the outside and providing a rational machine manufacturing process to enable the production of toroidal distribution transformers ,

The achievement of this object is that a turn of the low-voltage winding of an electrically conductive material is preformed in two halves, these two halves are electrically connected to each other around the closed ring core, wherein at least one half has a floor, so that a spiral winding, consisting is formed from several turns on the closed ring core, for the toroid, a thin magnetically conductive material is wound into a multi-stage closed toroidal transformer core, between the magnetically conductive material is an adhesive which mutually isolated the material (to avoid eddy currents) and the toroidal core solidified and the electrical insulation is obtained with respect to the low voltage winding with spacers or spacers made of electrically non-conductive material. To increase the strength and electrical insulation to the outside, the toroidal transformer core can be completely cast with an electrically non-conductive casting resin high strength.

A further embodiment provides that the electrical insulation (core for undervoltage winding) is realized by at least three spacer rings or in each case three spacers per turn, which are fixedly mounted in the steps of the toroidal core. Subsequently, the toroidal core is coated with a varnish for insulation and protection against corrosion.

One turn of the undervoltage winding is preformed from two halves with electrically conductive material, for example aluminum with a cross-section of 1500 mm ² . At least one half has a floor, so that from the individual halves a turn and from the turns a continuous spiral winding is formed, the shape of the floor sets the distance to the isolation of the turns against each other. The individual halves can be screwed and / or welded.

This makes it possible to realize a low-voltage winding with arbitrarily large cross section in a relatively short time.

The advantage of the toroidal core technology is that it allows toroidal distribution transformers to be realized in the highest power range, which are extremely low-loss and only about 50% of the operating costs of conventional distribution transformers in casting resin technology. As a result, the toroidal distribution transformer refinances in a few years and, in addition, a significant amount of primary energy, for the conservation of resources and the environment, can be saved.

The object is also achieved by a transformer, in particular a spiral undervoltage winding high cross-section and their manufacture, a multi-stage closed toroidal transformer high stability, from magnetically conductive and mutually insulated material, electrically insulated for undervoltage winding, and its manufacturing method, preferably a support frame with at least 3 Vorratsrollenvorrichtungen, each with a braking device, with at least 2 different widths of magnetically conductive material, at least three Klebersprühvorrichtungen, and at least three Aufwickelvorrichtungen with a drive system, at least three guide devices, a guide rail, and a cutting device is provided.

In a preferred embodiment, a transformer is provided, wherein each supply roll device, as well as each take-up device is equipped with a drive and brake device.

In a preferred embodiment, a transformer is provided, wherein at least three spacer rings or three spacers per turn, are firmly attached in the gradations of the toroidal core.

In a preferred embodiment, a transformer is provided, the toroidal core being coated with a varnish for insulation and for protection against corrosion.

In a preferred embodiment, a transformer is provided wherein the toroidal transformer core is encased in a high strength cast resin.

The object is also achieved by a transformer, in particular a spiral low-voltage winding of high cross-section and their manufacture, a multi-stage closed toroidal transformer high stability, from magnetically conductive and mutually insulated material, electrically insulated for undervoltage winding, and its manufacturing process, wherein a turn of the low-voltage winding an electrically conductive material is preformed in two halves, these two halves are electrically conductively connected to each other around the closed ring core, wherein at least one half has a floor, so that a spiral winding, consisting of several turns on the closed ring core is formed.

In a preferred embodiment, a method is provided, wherein the winding halves are screwed together or / and welded.

Fig. 1

zeigt in schematischer Darstellung einen seitlichen Schnitt durch einen Mehrphasentransformator mit drei in axialer Richtung benachbart angeordneten Ringkernen.

Figur 2

zeigt in schematischer Darstellung ein Ausführungs-beispiel eines Wicklungsträgers und des Wickelvorgangs gemäß der vorliegenden Erfindung.

The invention is explained in more detail with reference to figures.

Fig. 1

shows a schematic representation of a lateral section through a multi-phase transformer with three axially adjacent arranged ring cores.

FIG. 2

shows a schematic representation of an embodiment of a winding support and the winding process according to the present invention.

In FIG. 1 is a generally designated with 101 polyphase transformer having three stacked axially in the axial direction of ring cores 102. In each case adjacent ring cores 102 carry phase windings of different phases, wherein the phase windings are respectively applied to the ring cores 102 annularly enclosing bobbins 103. In this case, bobbin 103 may be alternately arranged with primary and secondary windings next to each other or one above the other. It is also possible for primary and secondary windings to be applied together to a bobbin 103.

The ring cores 102 are arranged in a holding device 104 which has outer and inner guide rails 105a, 105b for forming a receiving region for the toroidal cores 102. The guide rails 105a, 105b are each made of insulating material, so that the ring cores 102 and the phase windings on the bobbin 103 of the ring cores 102 are laterally outwardly insulated.

The holding device 104 has on its underside a bottom part 107, which likewise consists of insulating material. On the bottom part 107 insulating support elements 108 are provided for the lower ring core 102. In this case, a plurality of spaced bearing elements 108 may be provided, or it is a continuous ring as a support element 108 is provided. Spacers 109 are respectively provided between the individual ring cores 102 with which the ring cores 102 or the coil cores 103 respectively assigned to the toroidal cores 102 are fixed relative to one another in their position. Insulating support elements 108 are again provided above the upper ring core 102, on which a cover part 110 rests and the toroidal cores 102 are also insulated on the upper side towards the outside.

The Indian FIG. 1 shown polyphase transformer 101 is formed as a three-phase transformer. The connection points of the individual phase windings of the toroidal cores 102 or of the spool bodies 103, which are not illustrated in more detail, are each offset by 120 ° relative to one another. The phase windings are thereby mechanically offset from one another by an angle which corresponds to the electrical phase shift or the electrical phase angle between the voltage signals of these phase windings.

In particular, in the region of the spacers 109, that is, where adjacent ring cores have the smallest distance from each other, there is practically no potential difference at two opposite regions of two ring cores 102 or bobbin 103. Voltage flashovers between adjacent toroidal cores 102 are thus not possible even if the toroidal cores 102 are arranged close together. The multi-phase transformer 101 can thereby be constructed compact and with reduced space requirements. In addition, between the individual ring cores 102, in the region of the spacers 109, no or only little insulation measures are required, whereby costs are saved and the construction is simplified.

The ring cores 102 are formed with their respective bobbins 103 like a module. In the event of a defect in one of these modules, the affected toroidal core can be exchanged for a replacement module or the defective module is electrically disconnected and a replacement module is provisionally connected to the polyphase transformer 101. Thus, it is not necessary to keep ready a complete transformer as a backup device, but it is sufficient to keep ready a ring core with the coil windings supporting the phase windings as a reserve module. As a result, costs are saved and the space required for a reserve device is reduced.

In FIG. 2 a winding device, generally designated 201, for winding winding carriers 202 is shown. The winding device for winding winding carriers 202 with winding material 204a, 204b stored on rotatably mounted winding material storage rollers 203a has two winding stations 205, which are arranged at 90 degrees from one another, on a ring core 6 indicated as an option. The winding stations 205 each have a support frame 207, with a holding and pivot bearing 208, for each one winding support 202. The winding supports 202 are each arranged concentrically around the ring core 206, wherein an air gap 20 9 remains free between the ring core 206 and the winding supports 202. The ring core 206 is held with a holding device, not shown, in the position shown.

The holding and pivot bearings 208, three each have on a roller holder 211, rotatably mounted rollers 210 as rolling elements, which act on the winding support 202. Two of the rollers 210 support the winding support 202 while from below and thus form a stable support and the third roller 210 acts on the winding support 202, from above, so that the winding support 202 is practically pinched by three rollers 210 and accidentally releasing the winding support 202 of the Holding and pivot bearing 208 is avoided. The rollers 210 are connected to a drive and brake device, not shown, with which the rollers are rotated in the direction of the arrows. Between the rollers 210 and the winding support 202, a frictional drive and braking device is provided, so that when rotating the rollers 210 in a clockwise direction, the winding support 202 is rotated in opposite directions. As a result of the rotational movement of the winding carrier 202, the winding material 204a, 204b is detached from the rotatably mounted winding material storage rollers 203a, 203b and wound onto the winding carrier 202. In this case, the winding carriers 202 of the individual winding stations 205 can be wound simultaneously.

The winding carriers 202 are made of a high-strength insulating material, each coil-like with the winding space 213 and laterally defining flanges 214 are formed. The insulation material is required for dielectric strength, in particular with respect to the low-voltage winding. The high strength is needed for the winding process, as well as the holding of the relatively heavy winding material. The outer edges of these side flanges 214 serve as loading surfaces for the rollers 210. The winding material 204a, 204b can be guided between the side flanges 214 on the winding support 202 without hindering the supply of the winding material 204a, 204b by the rollers 210. In addition, the side flanges 214 form an insulation to adjacent coil carriers, as well as lateral boundary for the coil material 204a, 204b.

The rollers 210 are spring-loaded and damped at their roller holder 211, respectively. This allows the rollers 210, a holding and pivot bearing 208 move apart to use a winding support 202, in the holding and pivot bearing and remove again. In addition, it is possible to wind winding carriers of different sizes.

At each winding station 205, a first winding material storage roll 203a, with conductor material 4a, and a second winding material storage roll 203b with insulating material 204b, for simultaneously, layer by layer wrap the conductor and the insulating material, on a winding support 202 are provided.

The invention relates to a high-voltage winding of a toroidal transformer, as well as their method of manufacture, for distribution transformers, based on toroidal technology.

The winding station with one on the winding carrier, consisting of two voltage-resistant half-shells with side flange High-strength insulating material, which is assembled to form a voltage-resistant round unit around the closed ring core, for receiving the segments of the high-voltage winding of the transformer, consisting of at least one electrical conductor and at least one insulating material with a holding and pivot bearing engaging on the winding support for rotatably supporting the winding support is, so that the electrical conductor and the insulating material can be wound onto a closed ring core.

Claims (15)

Device for producing the high voltage winding of a toroidal transformer, characterized in that at least one winding station (205) with a holding and pivot bearing (208) for rotatably supporting a winding support (202) of the toroidal transformer is provided, which holding and pivot bearing (208) several, Rolling elements (210) or the like on the winding support (202), at least one of which is connected to a drive and brake device, to drive and decelerate the winding support (202), so that the electrical conductor with the insulation material to a closed Ring core (206) can be wound, being used as a winding material flat belts. Apparatus according to claim 1, characterized in that the winding support (202) consists of two voltage-resistant shells with side flange (214) made of high-strength insulating material, which are joined together to form a voltage-resistant unit around the closed ring core (206). Device according to one of claims 1 or 2, characterized in that the winding support (202) is integrally located around the closed ring core (206). Device according to one of claims 1 to 3, characterized in that for simultaneously winding a plurality of winding carriers (202) a plurality of circumferentially juxtaposed winding stations (205) are provided. Device according to one of claims 1 to 4, characterized in that the winding support (202) or the winding support in each case concentrically around the toroidal core (206) is arranged / are. Device according to one of claims 1 to 5, characterized in that the holding and pivot bearings (208) each have three on a roller bearing (211) rotatably mounted rollers (210) as rolling elements which act on the winding support (202), in particular two the rollers (210) support the winding carrier from below and the third roller (210) acts on the winding carrier (202) from above, so that the winding carrier (202) is practically clamped by the three rollers (210) and accidental release of the winding carrier (202 ) is avoided by the holding and pivot bearing (208). Device according to one of claims 1 to 6, characterized in that at least one winding material storage roll (203a) with conductor material (204a) and at least one second winding material storage roll (203b) with insulation material (204b) for the simultaneous, layer-wise winding of conductor material and insulation material are provided on the winding support (202). Device according to one of claims 1 to 7, characterized in that three, four or five winding material storage rollers for simultaneously winding a winding support (202) are provided, and that two, three or four of the winding material storage rollers conductor material and a third, fourth or fifth winding material storage roll carries insulation material for insulation. Device according to one of claims 1 to 8, characterized in that rolling elements (212) are provided for mounting of the winding support (202), for adaptation are in the diameter and / or the outline different winding support (202) sprung and / or damped. Device according to one of claims 1 to 9, characterized in that each supply roll device and each take-up device is equipped with a drive and brake device. Method for producing a transformer, characterized in that it is used for winding a winding carrier (202) into a holding and pivoting mounting (206) of a device (201) according to one of claims 1 to 10, in that the winding material (204a, 204b) Winding support (202) is supplied from the winding material storage roll (s) (203a, 203b) arranged at a distance from the holding or pivot bearing (206) such that at least one rolling element (210) is driven or braked by a drive and braking device, whereby the winding support (202) on which this rolling body (210) engages circumferentially, in rotation, wherein as a winding material flat strips are used. A method according to claim 11, characterized in that the winding support (202) is filled after or during the application of the high-voltage winding with solid, liquid or gaseous insulating material. Method according to one of claims 11 to 12, characterized in that a divisible mold for producing the winding support (202) is placed around the closed ring core (206) and / or the winding support (202) is manufactured in a Druckgelierverfahren and / or the winding support (202) is wound after removing the mold. Method according to one of claims 11 to 13, characterized in that the winding support (202) with a casting resin under atmospheric conditions, a Gießharzfüllung under vacuum, a Gießharzfüllung by a Druckgelierverfahren or in a dense execution with gaseous or liquid insulating materials, in particular nitrogen or a insulating oil is filled during or after the winding process. Method according to one of claims 11 to 14, characterized in that conductor material (204a, 204b) and insulation material (204a, 204b) are simultaneously wound in layers on the winding support (202).

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