DE102016222481A1 - Rotor for high speeds with coil arrangement and winding carrier - Google Patents

Abstract

There is provided a rotor (1) for an electric machine (21) comprising at least one electric coil assembly (3i), at least one winding support (5, 5i) mechanically supporting the at least one coil assembly (3i) and these on a radially outer side the coil arrangement at least partially surrounds, wherein the rotor (1) has a central support element (6) and the at least one winding support (5i) is mechanically connected to the central support element via an anchoring element (4) embedded in the support element (6) in a form-fitting manner.Furthermore an electric machine (21) is provided with such a rotor (1) and a fixedly arranged stator.

Description

The present invention relates to a rotor for an electric machine, wherein the rotor comprises at least one electrical coil arrangement and at least one winding carrier, which mechanically carries the at least one coil arrangement. Furthermore, the invention relates to an electrical machine with such a rotor.

According to the state of the art, the coil arrangements in the rotors of electrical machines are typically mechanically held on a radially inner winding carrier. These radially inner winding carriers are often lathed iron cores which completely fill the interior space and on the outside of which the windings are applied. To be able to mechanically support the coils, such iron cores often have a stepped profile on their radially outer side, so that the radially outwardly projecting projections of the iron core can reach into the center of the individual coil arrangements and hold them from their center. The iron of such a winding carrier serves at the same time for magnetic flux guidance in the rotor.

In order to cool the electrical coil arrangements of the rotor, these are often coupled by means of a complex cooling structure to a cooling system. Such a cooling structure typically comprises, in particular for superconducting rotor windings, a plurality of thermally highly conductive elements, by means of which the heat arising in the coil arrangements can be dissipated to a coolant which circulates away from the space. These thermally conductive elements often contain a large amount of copper. The circulating coolant may, for example, flow in a cavity in the interior of the coil carrier and be recooled outside the rotor. Such a cooling structure and cooling system are particularly important to the operation of the rotor when the coil assemblies have superconducting windings whose conductor material during operation must be cooled to a cryogenic temperature below the critical temperature of the superconductor. Especially in such a superconducting rotor, the weight contribution of the cooling structure is often relatively large. But even with a normal-conducting rotor, a heavy weight contribution can come about due to the heavy, highly thermally conductive cooling structure.

Another disadvantage of such a known rotor is that the high densities of the iron and copper-containing materials used during operation of the rotor high centrifugal loads come about. As a result, the maximum rotational speeds of conventional machines, in particular superconducting machines, are severely limited.

The object of the invention is therefore to provide a rotor which overcomes the disadvantages mentioned. In particular, a rotor is to be made available, which has a comparatively low mass and can simultaneously achieve high speeds. Another object is to provide an electric machine with such a rotor.

These objects are achieved by the rotor described in claim 1 and the electric machine described in claim 13.

The rotor according to the invention is designed as a rotor for an electric machine. It comprises at least one electrical coil arrangement and at least one winding carrier, which mechanically carries the at least one coil arrangement and at least partially surrounds it on a radially outer side of the coil arrangement. The rotor has a central support element and at least one anchoring element, wherein the at least one winding support is mechanically connected to the central support element via the anchoring element embedded in the support element in a form-fitting manner.

It is essential that the rotor has at least one electrical coil arrangement, by means of which an electromagnetic field can be formed when an electric current flows. In particular, the rotor may even have at least two radially opposite coil arrangements, which together form a magnetic pole pair. Such a plurality of coil assemblies together form the rotor winding. Each of the coil arrangements may comprise either only one winding layer or a plurality of winding layers. The individual, axially extending conductor regions of such a coil arrangement can be electrically connected to one another, for example, via winding heads in the axial end regions. The rotor winding as a whole can be formed either from a continuous conductor or from a plurality of individual conductors, which can be at least partially subsequently contacted to a parent winding with each other.

Regardless of the exact configuration of the rotor winding from one or more coil arrangements, it is essential for the invention that the at least one coil arrangement is mechanically held by at least one radially outer winding carrier. In other words, the mechanical support of the coil arrangement (s) is achieved via an exoskeleton-like structure. This exoskeletal structure is said to be the Coil arrangement (s) radially outwardly at least partially surrounded - in other words, the winding support with more than one surface to rest against the at least one coil assembly in order to support them in several directions can. In particular, the winding carrier may adjoin the coil arrangement (s) both radially on the outside and in the circumferential direction in order to be able to support it against forces acting both in the radial outward direction and in the azimuthal direction. Thus, during a rotation of the rotor, the coil arrangement can be supported both against the outwardly acting centrifugal forces and against the forces acting in the circumferential direction.

The described anchoring of the at least one winding carrier on the central support element ensures that the winding support is supported in particular in the radial direction against the centrifugal forces acting during operation. A torque transmission from the winding support on the central support element can be done via this at least one anchoring element. Insbesondre in the presence of a plurality of coil arrangements and / or a plurality of winding carriers may advantageously be present more such anchoring elements. This plurality of anchoring elements can be distributed in the circumferential direction and / or in the axial direction along the outer surface of the central support element.

It is essential in connection with the present invention that the central support element and the at least one anchoring element be present as separate, subsequently (ie according to their respective manufacture) composite elements. The mechanically strong connection between these elements is ensured by a positive connection. In particular, this positive connection is designed such that it counteracts a relative movement between the central support element and the anchoring element in the radial direction. In addition, it can also advantageously counteract a relative movement in the azimuthal direction. If relative movements in the radial and / or azimuthal direction are prevented in this way, a mechanical support in the radial direction and / or a transmission of torques during rotation about a central axis is conversely made possible. In other words, the at least one anchoring element enables a support of the winding carrier (and thus indirectly the coil arrangement) on the central support element against radial forces (in particular centrifugal forces). At the same time a transfer of torque between the winding support (and thus in turn indirectly the coil assembly) and the central support element allows.

• - Zum einen ist die Fertigung durch die nachträgliche Verbindung erleichtert, da die einzelnen Elemente weniger komplex geformt sind als die daraus gebildete übergeordnete Tragstruktur.
• - Zum anderen ermöglicht die mehrstückige Ausführung eine Wahl von unterschiedlichen Materialien für die einzelnen Elemente. So kann durch die Auswahl von jeweils angepassten Materialdichten und Zugfestigkeiten eine insgesamt in Bezug auf geringe Masse und mechanische Festigkeit optimierte Tragestruktur zur Verfügung gestellt werden.
• - Weiterhin kann die Spulenanordnung vor der Verbindung des Verankerungselements mit dem zentralen Tragelement in den zugehörigen Wicklungsträger eingebettet werden. Dies ermöglicht geometrische Anordnungen und Abmessungen, die insbesondere bei einstückiger Ausführung von Wicklungsträger und Verankerungselement sonst nicht möglich wären.

The inventive design of the central support element and the / the anchoring element (s) as a separate, subsequently form-locking connected elements has several advantages over a one-piece design:

• - Firstly, the production is facilitated by the subsequent connection, since the individual elements are less complex than the formed from this parent support structure.
• - On the other hand, the multi-piece design allows a choice of different materials for each element. Thus, through the selection of respectively adapted material densities and tensile strengths, a total support structure optimized with regard to low mass and mechanical strength can be made available.
• - Furthermore, the coil assembly can be embedded in the associated winding carrier before the connection of the anchoring element with the central support element. This allows geometric arrangements and dimensions, which would otherwise not be possible in particular in one-piece design of winding support and anchoring element.

In the rotor according to the invention, the function of the mechanical support of the coil assemblies is divided stepwise into at least two elements: The or the winding support or the coil arrangement (s) radially outward and hold them from there. On the other hand, the at least one anchoring element supports and holds the winding carrier or carriers from a radially inner region of the rotor. The central support element can form a kind of internal skeleton together with the (advantageously several) anchoring elements. This can have cavities in order to keep the weight contribution to the total weight of the rotor as low as possible.

Overall, the embodiment according to the invention thus enables a support structure for the coil arrangement (s), which is suitable for high speeds due to their mechanical strength in the radial and azimuthal direction. At the same time it can be advantageously realized by low density materials and made relatively easy.

The electric machine according to the invention has a rotor according to the invention and a stationary stator. The advantages of the machine according to the invention are analogous to the described advantages of the rotor according to the invention.

Advantageous embodiments and further developments of the invention are based on those of Claims 1 and 13 dependent claims and the following description. In this case, the described embodiments of the rotor and the electric machine can be advantageously combined with each other.

The rotor is expediently designed for rotation with respect to a central axis of rotation. The central support element can then extend in particular along this axis of rotation. The rotor may particularly preferably have an overall cylindrical basic shape, and the central support element may be arranged centrally on the cylinder axis and thus on the axis of rotation.

The at least one anchoring element and the at least one winding carrier can advantageously be formed in one piece. Such an embodiment may facilitate manufacture since fewer individual components are needed. In addition, the mechanical strength of the entire rotor is so particularly high because the one-piece design ensures a particularly good transmission of force between the region of the component which forms the anchoring element and the region of the component which forms the winding carrier.

Alternatively, however, it is also possible for the at least one anchoring element and the at least one winding carrier to be present as separate components and subsequently connected to one another. Such a connection can in turn be formed as a positive connection. Alternatively or additionally, in principle, however, a cohesive and / or non-positive connection is possible. In one embodiment with separately formed elements is advantageously the choice of different materials and a separate adaptation to the required strength and / or other material properties at the same time possible low density possible. Such a subsequent connection between the anchoring element and the winding carrier can be created for example by screws, bolts and / or a tongue and groove system.

The rotor advantageously has an internal cavity in which a fluid coolant can be circulated. It is preferably designed so that the at least one coil arrangement can come into contact with the coolant at least on its radially inner side.

The internal cavity allows the fluid coolant to circulate so that it can vent the coil assembly from a radially inward side. For this purpose, the coil arrangement can be at least partially exposed on its radially inward side-that is to say not be surrounded by the winding carrier-so that the coolant can flow to the coil winding on this side. In particular, it can thus come into direct contact with the coil arrangement. In this case, in particular, the conductor winding of the coil arrangement itself can be flowed through or flowed around by coolant. Either the conductor itself or else an electrical insulation, impregnation and / or protective layer surrounding the conductor can be in direct contact with the coolant such that the coil arrangement can dissipate the heat generated during operation to the coolant. It is essential that the thermal coupling of the coolant to the coil arrangement (s) is not achieved by additional heat-conducting cooling structures over a spatial distance, but that the coolant is in direct contact with a component of the coil assembly. However, it should not be ruled out that there is additionally a thermally conductive cooling structure. For example, in addition to the direct contact of the coolant with the coil assembly, there may be a circumferentially extending heat-conducting ring to cool the azimuthal regions of the coil assembly that are not in contact with the coolant in a stall of the rotor. Essential in the context of this embodiment is only that at least a part of the coil assembly is in direct contact with the coolant at a certain time.

The described features of the thus designed rotor ensures that the rotor can be designed with comparatively low mass and that nevertheless effective cooling of the coil arrangement (s) can take place. As a result of the above-described mounting of the coil arrangement (s) from the outside in the manner of an exoskeleton, a cavity for circulating coolant can be arranged radially inwardly next to the coil arrangement. Such an open structure not only allows for efficient heat dissipation, but also low average density of the rotor, because the refrigerant is typically less dense than the supporting parts of the outer coil carrier. In this case, either larger parts of the cross section may be designed as a cavity in the axially inner region of the rotor and / or one or more further solid elements may be provided which additionally support the at least one winding carrier. It is essential that the rotor by the support of the coil assembly (s) to the outside can be made substantially lighter overall, as if the coil assembly (s) is / are supported on an internal solid support. Due to the comparatively lower density or lower mass of the rotor, particularly advantageous rotational speeds can be realized by this configuration.

The electric coil arrangement can advantageously have a superconducting conductor material. The advantages of the invention are particularly evident in such a superconducting rotor, since the effective cooling of the conductor to a cryogenic temperature is then particularly important. For achieving a machine with a high power density and / or a high speed, it is particularly advantageous that the necessary structures for cooling without a high weight contribution are created.

Particularly advantageously, the electric coil arrangement may comprise a high-temperature superconducting material. High-temperature superconductors (HTS) are superconducting materials with a transition temperature above 25 K and in some classes of materials, such as the cuprate superconductors, above 77 K. In these conductors, the operating temperature can be achieved by cooling with cryogenic materials other than liquid helium. However, it should not be ruled out that helium can nevertheless be used for cooling in order to set an operating temperature which is significantly lower than the critical temperature. HTS materials are also particularly attractive because these materials can have high upper critical magnetic fields as well as high critical current densities, depending on the choice of operating temperature.

The high-temperature superconductor may comprise, for example, magnesium diboride or an oxide-ceramic superconductor, for example a REBa ₂ Cu ₃ O _x (REBCO) compound, where RE represents a rare earth element or a mixture of such elements.

The superconducting conductor of the coil arrangement can generally advantageously be a strip conductor, in particular a high-temperature superconducting strip conductor. The strip conductor can advantageously be a flat strip conductor, in particular with an approximately rectangular cross-sectional profile. In this case, for example, several successive turns of the strip conductor lie flat on each other. Ribbon conductors in which a normally-conductive substrate is coated with an HTS layer are particularly advantageous for the manufacture of superconductive coil windings for electrical machines.

In particular, in the presence of such a superconducting rotor, this can be designed for an operating temperature of the coil arrangement (s) in a temperature range of 90 K or lower, in particular in a temperature range of 77 K or lower. For example, the operating temperature may be in the range of about 30K.

The rotor may have a plurality n of coil arrangements, wherein each of the n coil arrangements is arranged on or held by a separate winding support assigned to it. In other words, the structure for mechanical retention of the individual coil arrangements can be segmented into individual winding carriers. These individual winding carrier segments can in particular be arranged on different circumferential positions of the rotor. The advantage of such an embodiment lies in particular in a simplified producibility of the entire mechanical support structure of the coil arrangements. Each of these individual winding carriers can advantageously be assigned at least one anchoring element embedded in a form-fitting manner in the supporting element. In this embodiment, therefore, all such segment-like winding support are individually supported against the central support member. In other words, the respective winding carrier and / or its associated anchoring element (s) then together form a circumferential segment of the entire supporting structure of the rotor. This support structure of the rotor is then assembled accordingly by connecting a plurality of such circumferential segment. Such an embodiment allows the formation of a relatively complex overall support structure and facilitates their production.

As an alternative to the segmented embodiment described, however, each of the n coil arrangements can also be arranged on or held by a peripheral segment of a higher-order common winding carrier assigned to it. In this embodiment, therefore, there is a continuous over the entire circumference of the rotor exoskeleton within which the individual coil assemblies are arranged distributed in the circumferential direction. Such a higher-order winding carrier may in particular have a cylindrical basic shape with an annular cross-section. An advantage of such a higher-order winding carrier is that a stable mechanical hold between the peripheral segments of the winding carrier is ensured, without the need for a subsequent connection. Such a superordinated, radially outer winding carrier can be mechanically supported by a and particularly advantageous by a plurality of corresponding anchoring elements against the central support member. Also in this embodiment, the at least one anchoring element can in principle be designed either in one piece with the winding carrier or it can be present as a separate element and subsequently connected to it.

When the rotor has a plurality n of coil arrangements, the support element can and / or the anchoring elements have in particular essentially an n-fold rotational symmetry. In such a symmetrical design, the distribution of forces is particularly favorable, and the support member and the anchoring elements can be carried out particularly easily given predetermined speed requirements.

In general, the winding support (s), the central support element and / or the anchoring elements may be formed from a non-magnetic material. In this case, different materials can be selected in particular for the different elements. In particular, when using superconducting coil assemblies, the magnetic flux guide within the supporting structures of the rotor is not necessary and not desirable. In particular, a cryolabelling which is cold-strength at the operating temperature of the rotor can be used for at least one of the mentioned elements, for example a titanium, aluminum, nickel or iron alloy (or the corresponding Rheinmetall). Alternatively, a fiber composite material can be used. Titanium and aluminum alloys and fiber composites are particularly preferred because of their low weight. Titanium or a titanium-containing alloy are particularly preferred as materials for the central holding element. In particular, the materials for the individual elements mentioned can also be chosen differently by the embodiment according to the invention.

The at least one anchoring element may, for example, extend over a majority of the axial length of the rotor. It then advantageously supports the winding support (s) over most of that length towards the center of the rotor. Alternatively, however, the anchoring element can also be formed only in axial subregions. Then, the interior of the rotor in the axially intermediate regions may either be hollow or at least have a relatively large proportion of cavities. This can be particularly advantageous in order to form a rotor with the lowest possible mass. Particularly in the case of the embodiment with a coherent, higher-order winding carrier, it may be advantageous to design the anchoring elements only in axial subregions, because then a support over the entire axial length is not necessary. But even with the use of separate winding carrier segments, it may be advantageous to provide anchoring elements only on a part of the axial length. For example, gaps between a plurality of anchoring elements distributed in the axial direction may be provided in order to insert the prefabricated coil arrangement into the winding carrier between them. After inserting the coil assembly then the positive connection between anchoring elements and central support element can be created.

The rotor may have a plurality of cavities, which adjoin the support element on its radially inner side and on the radially outer side thereof to the at least one coil arrangement and / or to the at least one winding support. In particular, it is advantageous if a plurality of such cavities are distributed in the azimuthal direction over the rotor, and these cavities adjoin the coil arrangement assigned to the respective angle segment. Then the respective coil arrangement can advantageously be cooled directly via circulating coolant in the respective cavity, without additional and possibly heavy elements for thermal coupling by heat conduction are required. In addition to this desired contact of the respective cavity with the coil arrangement, the cavity can also be adjacent to parts of the winding support in order, for example, also to de-heat it. It is not excluded that the respective cavity is also adjacent to other elements to be Entwärmende, for example to power supply lines, which are provided for connection of the coil assembly (s) with an external circuit, or to contacts that can be provided to individual, for example Winding layers of the coil assembly (s) to connect together or to connect the individual coil assemblies of the rotor with each other. Especially for the cooling of such contact points or power supply lines, it is advantageous if these conductive areas of coolant can be flowed directly, so if they are adjacent to the respective cavities of the rotor.

The individual cavities can advantageously be fluidly connected to one another. In other words, they can be configured as parts of a superordinate coolant space. For this purpose, for example, openings in different areas of the central support element and / or the anchoring elements may be provided, which connect the individual cavities and thus the individual parallel coolant channels with each other. For example, the central support element may generally be formed as a support tube through which coolant can flow. This support tube may be provided with window-like recesses, can pass through the coolant into the cavities between the individual anchoring elements. These anchoring elements may, for example, have gaps or at least windows in the axial direction, through which coolant can pass into an adjacent cavity.

The at least one winding carrier can, relative to the circumferential direction of the rotor in its center be connected to the associated anchoring element. In other words, the at least one anchoring element assigned to the respective winding carrier then sits centrally (in the azimuthal direction) in the winding carrier. This embodiment is particularly advantageous in order to support the respective winding carrier in a particularly symmetrical manner against the central supporting element. In principle, however, it is not excluded that alternatively two anchoring elements (or another even row number of anchoring elements) are arranged on both sides of the winding support and support it together inwardly. Such support by lateral anchoring elements can in principle also be provided in addition to the centrally arranged anchoring element.

The positive connection of the at least one anchoring element with the central support element may preferably be formed by inserting a root-like structure of the anchoring element into a matching recess in the central support element. Alternatively, however, in principle an inverse embodiment for this purpose is possible and may also be advantageous, in which therefore a root-like structure of the central support element engages in a matching recess in the respective anchoring element.

In general, the positive connection between the anchoring element and the central support element can be achieved in different ways. Particularly advantageous here is a connection in the manner of a tongue and groove system. As described above, in principle, the groove can be arranged either on the side of the central support element or on the side of the anchoring element. The groove and the matching spring can for example be designed as a simple groove and a simple spring. Alternatively, however, more complex shapes are possible, for example, floors annular designs of tongue and groove, whose cross-section is formed fir-tree-like.

In general, such a positive connection can be configured by a tongue and groove system in such a way that the two parts to be connected can be connected to one another by insertion along the axial direction of the rotor. In order to achieve a predetermined orientation of these parts relative to one another, an axial stop can optionally be provided.

Alternatively or in addition to the described tongue and groove systems but also a positive connection can be created by inserting a thread or a bolt in a matching recess of the respective other associated element.

The rotor can generally advantageously have at least one bandage, by means of which the at least one winding carrier is fixed in the rotor and thus is additionally supported in particular. In particular, the winding carrier or the plurality of winding carriers can be fixed on the inner support structure of the rotor, which is formed by the central support element and the anchoring elements attached thereto. Such bandaging is particularly advantageous for either fixing a plurality of segmental winding carriers distributed over the circumference of the rotor against each other or additionally fixing them on the inner support structure, or both. In particular, such a band rate can relieve the fastening of the anchoring element on the central support element and / or on the winding support. Thus, in particular a load distribution between tongue and groove system and bandaging can be effected. Such a bandage may expediently be arranged radially outside the at least one winding carrier. In this way, it can fix this winding carrier or even the plurality of winding carriers similar to a belt or a corset. The bandage may for example be formed from a band-shaped element. This may be wound in the form of a spiral winding around the circumference of the rotor or in the form of a ring surrounding the rotor band or more such bands. Such a band-shaped element may comprise, for example, as a material a fiber composite material, in particular a glass fiber reinforced plastic and / or a carbon fiber reinforced plastic. In general, it is in any case advantageous if the material of the bandage has a high rigidity and a high tensile strength in the tangential direction of the rotor. This can advantageously be a material with anisotropic strength, but depending on the design, materials with an isotropic strength can also be used. As an alternative to the embodiment in the form of a band-shaped winding, such a bandage can also be provided by a cylinder which is shrunk onto the internal elements of the rotor, for example a metallic cylinder, in particular a titanium alloy cylinder. For example, such shrinkage may be due to thermal shrinkage upon cooling to a cryogenic operating temperature.

Generally and independently of the exact design of the bandage, it may be advantageous if it is arranged with a bias around the inner elements of the rotor - ie in particular around the or the winding support, the anchoring elements and the central support element. Particularly advantageously, this bias is chosen so that it remains at least partially even with a cooling of the rotor to its operating temperature. The advantage of such under A bias held bandage is that they are converted by the mechanical stresses occurring in operation in the rotor in a tangential tensile stress in the bandage, which can be particularly easily absorbed by the beneficial materials of the bandage.

The fluid coolant of the rotor may be particularly advantageous hydrogen. Hydrogen is particularly suitable because, on the one hand, it has a sufficiently low boiling point to act as a cryogenic coolant in the liquid state. On the other hand, it has a low density, which has a favorable effect on the total weight of the rotor including coolant. Such low density coolant is also particularly suitable for providing rotors for large diameter, high speed machines. Due to the low density also caused by the hydrostatic pressure boiling point shift is small.

As an alternative to the abovementioned embodiment with hydrogen, other liquids or even gases can be used as the coolant. Further advantageous cryogenic coolants are liquid helium, liquid neon, liquid nitrogen, liquid oxygen and / or liquid methane. In this case, when using all these cryogenic coolant in principle, the liquid form in addition to the gas form, and it can be achieved by evaporating the liquid in the region of the components to be cooled, an additional cooling effect. Thus, it is possible that the cryogenic coolant circulates inside the rotor, in particular according to the thermosiphon principle and / or in the manner of a heat pipe.

In principle, it is also possible that water or oil or another non-cryogenic cooling liquid is used as the coolant. These coolants are particularly suitable for cooling rotors with normal-conducting coil arrangements. It may be advantageous to circulate the coolant in the cavity by means of a pump in order to achieve an effective cooling effect in the region of the coil arrangement. In principle, it is possible that the respective coolant is designed either as part of the rotor or else that the rotor is alternatively designed only for operation with such a coolant and does not include the coolant itself.

Regardless of the exact choice of coolant, it may be generally advantageous to recool the coolant through an additional cooling system. For example, for this purpose, a chiller can be arranged outside the rotor, or it can be arranged either on the rotor itself or outside the rotor, a heat exchanger to efficiently transfer the heat from the coolant to the external environment.

The rotor may include an electrically conductive damper shield which radially surrounds the at least one coil assembly. Such a damper screen is advantageous in order to reduce the coupling of electromagnetic alternating fields in the coil arrangement (s) of the rotor and thus to reduce corresponding AC losses in the rotor. Such a damper shield may in particular be arranged as an electrically conductive cylindrical jacket around the coil arrangement (s) of the rotor.

Alternatively or additionally, the rotor may have an outer cryostat wall which radially surrounds the at least one coil arrangement. Such a cryostat wall is advantageous for encapsulating the internal elements of the rotor against the warmer external environment. In combination with a superinsulation and / or an insulating vacuum, a thermal separation of the interior space from the external environment also occurs. This is particularly advantageous in connection with superconductive coil arrangements and a cryogenic operating temperature of these coil arrangements. Such a cryostat wall can either be a single outer cryostat wall or, alternatively, a combination of an inner and an outer cryostat wall can be present, wherein an insulating vacuum is advantageously provided between these two cryostat walls.

The said radially outer elements - ie damper screen, inner Kryostatwand and / or outer Kryostatwand - can in a plurality of coil arrangements, in particular all these coil arrangements radially surround. All these radially outer elements can, insofar as they are present in the relevant embodiment, advantageously be cylindrical, in particular circular-cylindrical.

The damper shield may in particular be provided by the winding carrier itself or by the plurality of winding carriers. This is particularly advantageous in the presence of a non-segmented, one-piece winding carrier. But even individual winding carrier segments can be electrically conductively connected to each other so that they can act together as a damper screen.

Alternatively or additionally, the damper screen can also be provided by one of the cryostat walls or by both cryostat walls. So it is also possible that a plurality of said elements together fulfill the function of the damper screen. Advantageous materials for the damper screen are metallic materials (for example Aluminum alloys) or carbon nanotube-containing materials.

The at least one cryostat wall can also be provided in particular by the winding carrier itself or by the plurality of winding carriers. Alternatively or additionally, the cryostat wall can be identical to the damper screen, without this element being given by the winding carrier or carriers. In general, and irrespective of which elements are combined with one another in the respective embodiment, the at least one cryostat wall can be formed particularly advantageously from a metallic material. Aluminum and iron-containing alloys are particularly advantageous here, but in principle any other vacuum-tight material is also suitable.

In embodiments having a nested arrangement of inner and outer cryostat walls, it is advantageous if at least the inner cryostat wall is both dense and resistant to the coolant used. In particular, the inner wall of the cryostat can be formed of a material that is robust to the action of hydrogen. In such an embodiment, inner and outer cryostat wall can be advantageously formed of different materials, since the requirements are different here. Thus, the inner wall of the cryostat can then advantageously comprise a hydrogen-resistant titanium alloy, aluminum alloy or iron alloy, in particular a so-called super-austenitic alloy.

The at least one winding carrier can advantageously be made ironless. In particular, all winding carriers present in the rotor can be made ironless. They can even be designed entirely free of magnetic flux-conducting materials. Also, the central support element and / or the at least one anchoring element may be free of such magnetic flux-conducting materials. Such a design without soft magnetic materials in the interior of the rotor is particularly advantageous in connection with superconducting coil arrangements, since magnetic flux conduction through the other rotor elements is not necessary or not effective due to the high magnetic flux densities and the resulting saturation. Another advantage of the ironless design is that lighter materials can be used and thus a lower density of the rotor can be achieved.

The rotor preferably has an average material density of at most 8 g / cm ³ , based on its total volume. More preferably, the average material density is at most 5 g / cm ³ or even at most 3 g / cm ³ . The total volume should be understood to mean the entire volume enclosed by the rotor, that is, for example, the entire cylinder volume, including internal cavities.

The described open construction of the rotor, in which the coil arrangement (s) are held by one or more winding carriers embodied as an exoskeleton, can be created particularly advantageously on a high proportion of internal cavities. Even if these cavities are partially or even completely filled with fluid coolant, a much smaller contribution to the average density is nevertheless created than with conventional materials for the winding carrier such as steel. If, in addition, relatively light materials such as aluminum or titanium alloys or carbon fiber composites are used for the at least one outer winding support, the central support element and the at least one anchoring element, a very low average density can be achieved overall in the areas described. The density of the materials used for winding carrier, anchoring element (s) and / or central support element can generally be advantageously below 5 g / cm ³ . If the average volume in terms of the total volume in the above-described areas, so can be provided with the rotor advantageously a machine with a particularly high power density, which can have very favorable especially in the application in vehicles, in particular in aircraft ,

The material of the at least one winding carrier preferably has a coefficient of thermal expansion that is greater than the effective thermal expansion coefficient of the electrical conductor. Such an embodiment is particularly advantageous in connection with superconducting coil arrangements, since then the coil support or bodies shrink more when cooled from room temperature to a cryogenic operating temperature than the coil arrangement embedded therein. Thus, during cooling, the winding carrier shrinks onto the coil arrangement and compresses it. It is characterized by a bias state in which predominantly compressive stresses act on the superconducting conductor. These conductors are generally less sensitive to compressive stresses than to tensile stresses because tensile stresses can more easily result in delamination of the superconducting material from an underlying carrier. This is especially true for the superconducting layer in a superconducting band conductor.

The rotor can generally be designed advantageously for the formation of a p-pole magnetic field, wherein the number of poles p can be particularly advantageously between 2 and 12, particularly advantageously between 6 and 12, in particular at exactly 8. For this purpose, the pole number p may advantageously be identical to the number n of coil configurations distributed in the rotor and distributed in the circumferential direction.

The rotor may have a rotor shaft for rotation of the rotor about a rotation axis. In particular, this shaft may be a segmented shaft, which may have, for example, at least one solid segment and at least one hollow segment. In connection with the present invention, it is advantageous for the rotor shaft to be hollow at least in an axially inner region of the rotor in order to guide and / or guide fluid coolant into the interior of the rotor.

The at least one coil arrangement is preferably inserted as a prefabricated form coil in the winding carrier. Such a prefabricated preformed coil should in particular be understood to mean a self-supporting, dimensionally stable coil, as can be achieved, for example, by wet-winding with an impregnating agent and subsequent curing of the impregnating agent. Alternatively, the coil can also be wound dry and subsequently impregnated with an impregnating agent and / or potted with a casting agent. After hardening of this impregnating agent and / or casting agent, a self-supporting coil-shaped coil arrangement is likewise obtained.

The at least one anchoring element can advantageously be used to guide other elements in the radial direction between the central support element and the winding carrier. In particular, a cable and / or a line (or advantageously several cables and / or lines) can be guided on the at least one anchoring element in the radial direction to the region of the coil winding (s), in order to allow an electrical connection of the coil to an external circuit ,

The electric machine with the rotor according to the invention can advantageously be designed for a power density of at least 5 kW / kg, particularly advantageously it can even be designed for a power density of at least 10 kW / kg. In a machine with such a high power density, the advantages of the rotor described are particularly significant. On the other hand, machines with such high power densities are a basic prerequisite for fully electric powered aircraft. However, they are also beneficial in the field of others - especially other mobile applications. Under the said power density, the rated power of the machine based on their total weight to be understood, so based on the weight of the stator, rotor, housing, cooling system plus any additional components present.

The machine is preferably designed for a rated power of at least 5 MW, in particular at least 10 MW. With such a high performance, it is basically suitable for driving a vehicle, in particular an aircraft. Alternatively, with such a powerful machine but also when operating as a generator of the electrical power required for the drive can be generated on board the vehicle. In principle, the machine can be designed either as a motor or as a generator or optionally be designed for both operating modes. In order to achieve the described high powers and / or power densities, superconducting coil arrangements are particularly suitable because they allow particularly high current densities.

The machine may preferably be designed for a rotational speed of the rotor of at least 1000 revolutions per minute, in particular even for at least 3000 revolutions per minute or even at least 6000 revolutions per minute. By the described embodiment of the rotor with comparatively low density such high speeds can be realized particularly well. With conventional rotors, they can not be achieved in part at a size required for the mentioned power ranges. On the other hand, the power densities that are advantageous for the applications described may not even be achieved with slower rotating machines.

• 1 eine schematische Querschnittsdarstellung eines Rotors nach einem ersten Beispiel der Erfindung zeigt,
• 2 eine schematische Teilansicht des Querschnitts aus 1 zeigt,
• 3 eine perspektivische Darstellung eines Wicklungsträgers aus einem Rotor ähnlich wie in 1 zeigt,
• 4 eine schematische Querschnittsdarstellung eines Rotors nach einem weiteren Beispiel der Erfindung zeigt und
• 5 einen schematischen Längsschnitt einer Maschine nach einem weiteren Beispiel der Erfindung zeigt.

In the following, the invention will be described by means of some preferred embodiments with reference to the appended drawings, in which:

• 1 a schematic cross-sectional view of a rotor according to a first example of the invention,
• 2 a schematic partial view of the cross section 1 shows,
• 3 a perspective view of a winding carrier of a rotor similar to in 1 shows,
• 4 a schematic cross-sectional view of a rotor according to another example of the invention shows and
• 5 shows a schematic longitudinal section of a machine according to another example of the invention.

1 shows a rotor according to a first embodiment of the invention in a schematic cross-section perpendicular to the axis of rotation A. The Rotor has eight coil arrangements in this example 3i on, which are connected to a parent rotor winding. This rotor winding is designed to generate an eight-pole magnetic field. The individual coil arrangements 3i In this example, they are each separate from a winding carrier assigned to them 5i mechanically held. These eight winding carriers 5i support their respective associated coil assembly 3i from a radially outer side. They border on the radially outer sides of these coil arrangements 3i at. In addition, they also border with their lateral surface, ie in the azimuthal direction of the coil arrangements 3i so that these coil assemblies are surrounded and held on several sides by the respective winding carrier. Only their respective radially inner side limit the individual coil arrangements 3i not on the winding carriers 5i but to an internal cavity 7 , These cavities can be traversed by a fluid coolant, liquid hydrogen in the present example, around the coil arrangement adjoining the cavities 3i to cool. The in cross section between the individual anchoring elements 4 marked cavities 7 can be advantageously connected in particular by not shown here openings to a common parent cavity, which also fluidly with the interior 8th of the central support element 6 can be connected. This central support element 6 is formed in this example as a hollow support tube, through the interior of the coolant, for example, from an axial end of the rotor can be fed from. Alternatively, however, it is also possible in principle that the central support element is designed solid and has no such inner cavity.

The eight winding carriers 5i support the eight coil arrangements 3i from the outside, in the manner of an exoskeleton. In the example shown the 1 the eight winding carriers are realized as separate elements. They are each individually by one or more anchoring elements 4 against the central support element 6 supported. In the example shown, the anchoring elements 4 integral with the winding carriers 5i educated. In other words, the winding carriers go 5i on its radially inner side in the anchoring elements 4 above. In this case, in the axial direction not shown here in each case a plurality of such anchoring elements in a row on such a winding support 5i be arranged. The individual anchoring elements 4 each have at their inner end a thickening, acting as a spring 10 is formed and in a correspondingly shaped groove of the central support element 6 intervenes. This results in a positive connection between the anchoring elements 4 and the central support element 6 through which the winding carriers 5i against this support element 6 be supported. By this support can in the winding support 5i embedded windings 3i be supported against the centrifugal forces acting during operation of the rotor. In addition, by means of these mechanically load-bearing connections, the torques acting during operation of the machine between the coil arrangements and the central support element 6 be transmitted. The illustrated tongue and groove system is to be understood as an example of a positive force transmitted connection between these elements. The eight grooves of the central support element shown 6 extend each axial direction of the rotor. They are expediently open at least at one axial end of the rotor, so that the spring-like thickenings of the anchoring elements 4 can be inserted from this side from the axial direction. Since in this example the winding carriers 5i integral with the anchoring elements 4 are formed, here are the spring-like thickening 10 shaped so that the individual coil arrangements 3i over the anchoring elements 4 pushed away and so past them in the corresponding recesses of the winding support 5i can be inserted.

The structure of the rotor cross section of 1 is even more detailed in for a quadrant 2 shown. Through the areas that run in the circumferential direction between the individual anchoring elements 4 lie, each are internal cavities 7 given, in which coolant the respectively associated coil arrangements 3i can flow to. These individual inner cavities 7 are fluidly connected to a superordinate coolant space. They are also with the pipe interior 8th of the central support element 6 connected. For this purpose, the anchoring elements 4 each openings 12a on, and the central support element 6 has a plurality of openings 12b on. These openings 12a and 12b are in 2 indicated by dashed lines. They do not extend over the entire axial length of the rotor 1 but may be distributed over its length at regular or irregular intervals. It is essential only that an exchange of cooling fluid between the individual subspaces 7 and 8th can take place, and that at the same time the anchoring elements 4 a sufficient support of the radially outer elements 5i and 3i guarantee. Instead of the openings indicated by dashed lines 12a in the anchoring elements 4 Alternatively, corresponding gaps between a plurality of axially adjacent anchoring elements 4 on a winding carrier 5i be arranged. In other words, then in the area of the spring 10 formed such a gap. It is only important that the circumferentially adjacent coolant spaces 7 fluidly connected to each other.

Im in the 1 and 2 shown axial portion of the rotor 1 So this has a hollow shaft, through the central support element 6 given is. Through the pipe interior 8th can cold, in particular liquid coolant in the radially outer cavities 7 arrive and there the coil arrangements 3i cool. In the case of the use of liquid hydrogen and other liquid cryogenic coolant may result in a partial evaporation of this cooling liquid. Then lies in the cavities of the rotor 1 both liquid and gaseous cooling fluid next to each other before. If the liquid volume is so small that it only fills a part of the void volume, then at a standstill of the rotor 1 not all components cooled evenly. Such a stoppage is in 1 by the horizontal liquid level of the cooling liquid 9 indicated. But if it comes to a rotation of the rotor 1 so that becomes the liquid coolant 9 by the centrifugal forces substantially uniformly over the individual cavities and the individual coil arrangements 3i distributed. This results in a uniform cooling effect of the individual components during operation of the electrical machine, which is equipped with such a rotor. Even if this machine is not in operation, however, a cooling effect can basically be achieved. If the liquid volume and / or the cooling effect of the gaseous coolant is insufficient for cooling to a predetermined temperature, then the rotor can be rotated slowly, for example, in a cooling phase. This rotation need not be so high that the coolant is evenly distributed over the circumference of the rotor 1 distributed. For example, it may be sufficient to cool down to a predetermined operating temperature when the rotor 1 is rotated so slowly that the individual coil arrangements 5i alternately in contact with the coolant 9 come and be cooled so over time overall.

The individual winding carriers 5i be in the example shown the 1 and 2 in addition to the internal support by the anchoring elements 4 held together by the fact that they by means of a radially outer bandage 13 under prestress against the anchoring elements 4 be pressed. In other words, here are the individual elements of the exoskeleton 5i additionally strapped to the inner support structure. Radially outside of this bandage 13 is an inner cryostat wall 15a arranged, in turn, by an outer cryostat wall 15b is surrounded. At least the outer wall of the cryostat 15b acts in the example shown at the same time as an electromagnetic damper screen. Between the cylinder jacket-shaped inner wall of the cryostat 15a and the likewise cylinder jacket-shaped outer cryostat wall 15b an annular vacuum space is formed. This becomes the inside of the cryostat walls 15a and 15 lying area of the rotor 1 thermally insulated against the external environment. Both cryostat walls 15a and 15b are vacuum-tight. The inner cryostat wall 15a is made of a material that is dense and robust to the coolant at the same time.

The in the 1 and 2 shown rotor 1 Overall, it is very light, because it has a comparatively large volume of internal cavities 7 and 8th has, and since the anchoring elements 4 , the central support element 6 and the winding carriers 5i may be formed of low density materials. On additional heavy copper elements for indirect cooling of the coil assemblies 3i can be omitted here, since the coil arrangements 3i through the open structure in direct contact with the coolant 9 are.

3 shows a schematic perspective view of one of the eight coil carriers 5i a rotor that is similar to 1 is trained. On the radially inner side, shown here below, this winding support 5i a recess into which a raceway-shaped coil assembly 3i is inserted. Also on this radially inner side extend from the winding support 5i in this example five anchoring elements 4 in the direction of the axis of rotation. Two of the axial gaps between these anchoring elements 4 are necessary in the example shown, between the two outer anchoring elements 4 the coil arrangement 3i to be able to insert. The gaps between the 3 inner anchoring elements 4 are useful in this example, so that liquid coolant between the adjacent cavities arising during assembly of the rotor 7 can circulate. In this area would also be a connection of these 3 anchoring elements in the sense of a continuous spring 10 possible. Regardless of the exact configuration of the gaps or openings between / in the anchoring elements 4 It is essential for this embodiment of the invention that the individual springs 10 the axially adjacent anchoring elements are arranged in a line so that they successively in a common, extending in the axial direction recess of the central support element 6 can be inserted.

4 shows an alternative embodiment of a rotor 1 according to a second example of the invention, also in schematic cross-section perpendicular to the axis of rotation A. Again, there are eight coil arrangements 3i with which a total of eight-pole magnetic field can be generated. In contrast to the previous example, here lies a common ring-shaped or jacket-shaped winding carrier 5 before that the individual coil assemblies 3i from a radially outer side carries. Due to the self-supporting structure of this winding support ring which are the individual coil arrangements 3i assigned areas of the winding support already supported radially together. To further improve the support against the centrifugal forces occurring and to a transfer of torque between the coil assemblies 3i and to enable a central rotor shaft is the parent winding carrier 5 also here with several anchoring elements 4 mechanically fixed with an internal support element 6 connected. This support element 6 is also designed here as a hollow support tube. In contrast to the previous embodiment, however, this support tube has no circular, but an octagonal cross-section. The cross-sectional shape can be chosen arbitrarily as a whole, and in particular, the cross-sectional shapes of the inner and the outer boundary surface can be chosen differently.

Also in this example, those are the eight coil arrangements 3i belonging areas of the winding carrier 5 by a total of eight anchoring elements against the central support element 6 supported. To the shape of the associated recesses 11 and 14 to clarify, however, one of these loosening elements (top right) is not shown. The illustrated anchoring elements 4a . 4b . 4c Some have different shapes and configurations to illustrate different possible variants. In a real rotor, however, the support elements of the individual eight segments are expediently designed to be equal to one another.

The five illustrated anchoring elements of the type 4a each have a spring-like thickening both at the radially outer end and at the radially inner end. In this case, the radially inner spring engages similar to the embodiment of the 1 into a corresponding groove 11 of the inner support element 6 to make the described positive connection with this. By contrast, the radially outer spring engages in a groove of the higher-order winding carrier that is shaped to match it 5 one. In contrast to the embodiment of 1 So here is the winding support is not formed with the anchoring elements in one piece, but it is subsequently connected from several elements. Also, this connection is generated here by a positive connection. The multi-piece embodiment shown here can in principle also be realized in a winding carrier which is similar to FIG 1 from a variety of individual segments 5i is composed. Regardless of the exact configuration, an advantage of the subsequent connection may be that the winding carrier and the anchoring element can be made of different materials. Another advantage may be that the coil arrangement 3i in the winding carrier 5 or 5i can be inserted before it is connected to the corresponding anchoring element. In such a case, the dimensioning of the anchoring element need not be adapted to the fact that the coil assembly can be inserted past her in the winding support.

In the case of the reference numeral 4b Marked variant of the anchoring element is the positive connection with the central support tube 6 not realized by a simply shaped groove (with matching spring), but tongue and groove each have a more complex shape with multiple floors. The advantage of such an embodiment is that the surface pressure is reduced under radial load, as an applied radial force is distributed to a plurality of bearing surfaces in the different floors. Such a "multi-level groove" is for the anchoring element 4b shown only as an example and there are different variants possible. For example, the groove and the matching spring may have a fir-tree-like cross-section.

In the case of the reference numeral 4c Marked variant of the anchoring element is the positive connection with the central support tube 6 not realized by a tongue and groove system, but by a screw connection between a thread and a matching threaded hole. For this purpose, the winding support 5 at the appropriate location in the region between the legs of the associated coil assembly 3i provided with an outwardly through hole. Through this hole, the bolt-like anchoring element 4c pushed through from the outside and with a thread formed in its inner end region in a matching bore of the central support element 6 be screwed. Such a bolt can also be connected to the winding carrier 5 be positively connected, for example, by a mounted in this area (not shown here for clarity) further thread and / or mounted on the inside of the winding support nut or another corresponding retaining element.

The bandage 13 is also optional in this example, since the annular winding carrier 5 yourself and the coil 3 itself and therefore does not need to be reinforced by a bandaging from the outside. But it can still be beneficial, by such a bandage 13 an externally applied bias on the winding support 5 to increase its mechanical stability and / or it under additional tension against the internal support structure of anchoring elements and inner support tube 6 support.

Also in the example of 4 can in the internal cavity 7 a fluid coolant 9 flow, where again the liquid form together with the gaseous form in a room 7 may be present. When operating the electric machine with such a rotor 1 equipped, the rotor rotates 1 about the axis A, as indicated by the arrow in the middle. Here, the liquid coolant distributed at sufficiently high speed over the circumference of the rotor, as shown schematically by the annular liquid level.

5 shows an embodiment of an electric machine 21 , which with a rotor 1 equipped according to the present invention. Shown here is a schematic longitudinal section along the axis of rotation A. The machine also has a fixedly arranged stator 23 on, the rotor 1 radially surrounds and that with the machine housing 27 connected is. The rotor 1 is on a rotor shaft 31 rotatably supported about the axis of rotation A, said rotor shaft 31 in the central part of the rotor 1 and in the area shown on the right as a hollow shaft 33 is executed. It is therefore a segmented wave. In the left part of the 4 The shaft can be designed either as a solid shaft, or it can also be designed here as a hollow shaft with a smaller cavity, for example, to be able to arrange power supply lines within the shaft. The rotor shaft 31 . 33 is over camp 29 rotatable in the axial end regions of the machine against the stationary machine housing 27 supported. The torque is in the left part of the rotor 1 between the rotor shaft 31 and the actual rotor 1 transfer. For this purpose is between rotor 1 and rotor shaft 31 a torque transmitting device 39 arranged, which is designed circular cylindrical in the example shown. In addition, on this side of the rotor power supply 41 arranged around the coil arrangements 3i of the rotor 1 with an external circuit via slip rings 43 connect to. From the right side of the rotor 1 is over the hollow shaft 33 fluid coolant 9 fed into the interior of the rotor and led out of here again to the outside. For this purpose, the hollow shaft 33 in its interior a supply line 35a and a return 35b , On the shaft end shown on the right, these lines can be connected to an outside of the shaft cooling system and not shown here to a closed coolant circuit. These lines 35a and 35b are as part of a parent coolant tube 35 inside the hollow shaft 33 fixedly arranged and with this by a rotary feedthrough 37 connected.

The rotor 1 the in 5 For example, as shown in FIG 1 or 4 be configured represented. It can in particular a plurality of coil arrangements 3i have, which are designed to form a p-pole magnetic field. These coil arrangements 3i are in turn over the circumference of the rotor 1 distributed and are from one or more external winding carriers 5 or 5i mechanically held. These bobbins are not shown in detail here for the sake of clarity. In addition to the illustrated therein inner support structure of central support element and the anchoring elements 4 the at least one winding support at the two axial end regions of the rotor by disk-shaped support elements 40 held.

The coil arrangements 3i and thus also not shown here winding carriers are radially from an inner Kryostatwand 15a and then from an outer cryostat wall 15b surround. In between, a vacuum space V is provided for thermal insulation, which in comparison to the examples of 1 and 4 is shown significantly enlarged. However, these size ratios are not true to scale, and the figures are to be understood only schematically so far. Outside the outer cryostat wall 15b are the fixed parts of the stator 23 arranged. In particular, on the stator winding support 25 a stator winding 24 arranged, the axial winding sections in their axial end portions with end windings 24a are connected. The stator winding 24 occurs during operation of the electric machine 21 in electromagnetic interaction with the electromagnetic field of the rotor 1 , This interaction takes place via an air gap 26 Instead, the radial between the rotor 1 and stator 33 lies. The stator winding 24 is in the example shown by an amagnetically shaped stator winding 25 worn, so here it is an air gap winding without iron teeth between the turns of the winding.

Claims (15)

Rotor (1) for an electric machine (21), comprising at least one electrical coil arrangement (3i), at least one winding support (5, 5i) which mechanically supports the at least one coil arrangement (3i) and at least partially surrounds the latter on a radially outer side of the coil arrangement, - Wherein the rotor (1) has a central support element (6) and - Wherein the at least one winding support (5i) is mechanically connected to the central support element via an anchoring element (4) embedded in a form-fitting manner in the support element (6). Rotor (1) to Claim 1 which has at least one internal cavity (7i) in which a fluid coolant (9) is circulatable, such that the at least one coil arrangement (3i) can come into contact with the coolant (9) at least on its radially inward side. Rotor (1) to Claim 1 or 2 in which the electrical coil arrangement (3i) has a superconducting conductor material. Rotor (1) according to one of the preceding claims, comprising a plurality n of coil arrangements (3i), - Wherein each of the coil assemblies (3i) is arranged on a dedicated individual winding support (5i) - And wherein each winding support (5i) is assigned at least one form-fitting in the support element () embedded anchoring element (). Rotor (1) according to one of Claims 1 to 3 which has a plurality n of coil arrangements (3i), - each of the coil arrangements (3i) being arranged on an associated circumferential segment of a higher-order common winding support (5). Rotor (1) according to one of the preceding claims, wherein the at least one winding support is connected in relation to the circumferential direction of the rotor in its center with the associated anchoring element. Rotor (1) according to one of the preceding claims, wherein the positive connection of the at least one anchoring element () with the central support element by inserting a root-like structure of the anchoring element is formed in a mating recess in the central support member. Rotor (1) according to one of the preceding claims, which additionally has at least one bandage (13) by means of which the at least one winding carrier (5, 5i) is fixed in the rotor. Rotor (1) according to one of the preceding claims, which has an electrically conductive damper screen (15b) and / or a cryostat wall (15a, 15b) which radially surround the at least one coil arrangement (3i). Rotor (1) according to one of the preceding claims, in which the at least one winding support (5, 5i) is ironless. Rotor (1) according to one of the preceding claims, which has, based on its total volume, an average material density of at most 8 g / cm ³ . Rotor (1) according to one of the preceding claims, wherein the at least one coil arrangement is inserted as a prefabricated shaping coil in the winding carrier. Electric machine (21) having a rotor (1) according to one of the preceding claims and a stationary stator (23). Electric machine (21) after Claim 13 , which is designed for a power density of at least 5 kW / kg and / or which is designed for a rated power of at least 5 MW. Electric machine (21) according to one of Claims 12 to 14 , which is designed for a speed of the rotor (1) of at least 1000 revolutions per minute.

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