阅读说明：本技术 旋转电机 (Rotating electrical machine ) 是由 赖纳·索伊弗特 罗尔夫·福尔默 于 2018-12-18 设计创作，主要内容包括：本发明涉及一种旋转电机(1),具有定子(2)和能够围绕旋转轴线(6)相对于定子(2)旋转的转子(4)。转子(4)具有环形的反应元件(5),其沿反应元件圆周(11)围绕旋转轴线(6)延伸,并且具有多个沿着反应元件圆周(11)连续地布置的可磁化区域(25),其中,在两个相邻的可磁化区域(25)之间分别布置有非磁性区域(23)。定子(2)具有至少一个两个有源部件部段(7、9)中的部段对(3),使得反应元件圆周(11)的圆弧在两个部段之间延伸,其中,每个部段对(3)的第一有源部件部段(7)具有多个圆弧走势连续地布置的电磁体(13),并且部段对(3)的第二有源部件部段(9)具有多个沿圆弧周向连续地布置的永磁体(21)。(The invention relates to a rotating electrical machine (1) having a stator (2) and a rotor (4) that can rotate relative to the stator (2) about a rotational axis (6). The rotor (4) has an annular reaction element (5) which extends along a reaction element circumference (11) around the axis of rotation (6) and has a plurality of magnetizable regions (25) which are arranged consecutively along the reaction element circumference (11), wherein a non-magnetic region (23) is arranged between two adjacent magnetizable regions (25). The stator (2) has at least one segment pair (3) of two active-part segments (7, 9) such that an arc of the reaction-element circumference (11) extends between the two segments, wherein a first active-part segment (7) of each segment pair (3) has a plurality of electromagnets (13) arranged in succession in the circumferential direction of the arc and a second active-part segment (9) of the segment pair (3) has a plurality of permanent magnets (21) arranged in succession in the circumferential direction of the arc.)

1. A rotating electrical machine (1) having a stator (2) and a rotor (4) rotatable relative to the stator (2) about an axis of rotation (6), wherein,

-the rotor (4) has an annular reaction element (5) which extends along a reaction element circumference (11) around the axis of rotation (6) and which has a plurality of magnetizable regions (25) arranged consecutively along the reaction element circumference (11), wherein one nonmagnetic region (23) is arranged between each two adjacent magnetizable regions (25),

-and the stator (2) has at least one segment pair (3) comprising two active component segments (7, 9) between which the arc of the reaction element circumference (11) extends, wherein a first active component segment (7) of each segment pair (3) has a plurality of electromagnets (13) arranged consecutively along the arc trend and a second active component segment (9) of the segment pair (3) has a plurality of permanent magnets (21) arranged consecutively along the arc trend.

2. Rotating electric machine (1) according to claim 1, characterized in that the active component sections (7, 9) of each pair of sections (3) are arranged at the sides of the reaction element (5) diametrically opposite with respect to the reaction element circumference (11).

3. Rotating electric machine (1) according to claim 1 or 2, characterized in that the stator (2) has a plurality of said segment pairs (3) arranged in an equally spaced manner from each other along the reaction element circumference (11).

4. Rotating electric machine (1) according to any of the preceding claims, characterized in that the stator (2) has an even number of said segment pairs (3) and that the first active component segments (7) of every two adjacent segment pairs (3) are arranged on different sides of the reaction element (5).

5. Rotating electric machine (1) according to any of the preceding claims, characterized in that bearing means (37) are provided for supporting the reaction element (5) on the stator (2).

6. Rotating electric machine (1) according to any of the preceding claims, characterized in that the reaction element (5) is supported in a movable manner relative to the stator (2) in a plane perpendicular to the axis of rotation (6).

7. Rotating electric machine (1) according to any of the preceding claims, characterized in that cooling means (29) are provided for cooling all the first active component sections (7) and/or all the second active component sections (9).

8. Rotating electric machine (1) according to any of the preceding claims, characterized in that each two adjacent permanent magnets (13) of each second active component section (9) have opposite poles.

9. Rotating machine (1) according to any of the preceding claims, characterized in that each electromagnet (13) of the first active component section (7) of each segment pair (3) is opposite to the two adjacent permanent magnets (21) of the second active component section (9) of the segment pair (3).

10. Rotating electric machine (1) according to any of the preceding claims, characterized in that the first active component section (7) of each segment pair (3) has twelve electromagnets (13).

11. Rotating electric machine (1) according to claim 10, characterized in that the reaction element (5) has seventeen or nineteen magnetizable regions (25) in the region of each segment pair (3).

12. Rotating electric machine (1) according to any of the preceding claims, characterized in that the electromagnets (13) of the first active component section (7) of each segment pair (3) are fed with a three-phase current system, wherein each electromagnet (13) is assigned to one phase (U, V, W) of the current system.

13. Rotating electric machine (1) according to claim 12, characterized in that the electromagnets (13) of each phase of the current system form magnet pairs of two adjacent electromagnets (13) having different magnetic poles from each other, and one magnet pair of each of the other two phases (U, V, W) is provided between two magnet pairs of each phase (U, V, W), respectively, and each two adjacent electromagnets (13) of the phases (U, V, W) different from each other have the same magnetic pole.

14. Rotating electrical machine (1) according to any of the preceding claims, characterized in that the non-magnetic region (23) of the reaction element (5) is made of a ceramic material.

15. Rotating electric machine (1) according to any of the preceding claims, characterized in that the magnetizable regions (25) of the reaction element (5) are made of soft magnetic material.

Technical Field

The present invention relates to a rotating electric machine.

Background

The rotating electric machine has a stator and a rotor rotatable about a rotation axis with respect to the stator. The stator and/or the rotor have magnets for generating a magnetic field. The magnets are electromagnets and/or permanent magnets and are typically arranged on the stator and/or rotor along a circle about the axis of rotation. In the case of large rotating electrical machines, that is to say in the case of circles having a large radius, correspondingly more and/or larger magnets are required. This results in high costs for magnet assembly of such machines.

Disclosure of Invention

It is an object of the present invention to provide a rotary electric machine that is improved, particularly in terms of the cost of magnet assembly.

This object is achieved by the features of claim 1.

Advantageous embodiments of the invention are the subject matter of the dependent claims.

A rotating electrical machine according to the present invention has a stator and a rotor rotatable about a rotation axis with respect to the stator. The rotor has an annular reaction element which extends along a reaction element circumference around the axis of rotation and has a plurality of magnetizable regions arranged consecutively along the reaction element circumference, wherein a non-magnetic region is arranged between two adjacent magnetizable regions. The stator has at least one segment pair of two active component segments between which an arc of the circumference of the reaction element extends. The first active component section of each section pair has a plurality of electromagnets arranged consecutively in a circular arc run, and the second active component section of the section pair has a plurality of permanent magnets arranged consecutively in a circular arc run.

In the rotating electrical machine according to the invention, only the stator has active magnetic components, i.e. electromagnets and permanent magnets, while the rotor has no such magnetic components and only has reaction elements with magnetizable regions.

In addition, interacting electromagnets and permanent magnets are arranged on different sides of the reaction element. With this arrangement of the electromagnet and the permanent magnet, the permanent magnet does not reduce the installation space for the winding coil of the electromagnet in the active part of the stator. By optimizing the slot geometry of the slots in which the winding coils extend, this enables an improved geometric arrangement of the winding coils of the electromagnets and thus an improved efficiency of the magnetic circuit and the electric machine compared to an arrangement of the electromagnets and permanent magnets in the same active part of the electric machine.

Furthermore, since the permanent magnet is arranged on the other side of the reaction element at a distance from the electromagnet, the permanent magnet does not heat up significantly due to the electromagnet. Thereby, the efficiency of the motor is improved, because losses through heating of the permanent magnets are reduced, or in order to achieve the desired efficiency low-cost permanent magnets are used, for example permanent magnets with relatively light rare earths, compared to the case where electromagnets and permanent magnets are arranged in the same active part of the machine.

Arranging the electromagnet and the permanent magnet on different sides of the reaction element also reduces the attraction force of the stator on the reaction element compared to arranging the electromagnet and the permanent magnet on the same side of the reaction element. Thereby, the load of the bearing of the reaction element is reduced or a low-cost support of the reaction element can be used compared to arranging the electromagnet and the permanent magnet on the same side of the reaction element.

Furthermore, the electromagnet and the permanent magnet are arranged in active part segments, which are each arranged only in the region of a circular arc of the circumference of the reaction element, that is to say only in a partial region of the circumference of the reaction element. The stator can thus be assembled in a modular manner with active component sections, the number and arrangement of which can be flexibly adapted to the respective requirements of the electric machine. In particular, the electromagnets and the permanent magnets are not generally arranged along the entire circumference of the reaction element, and therefore, the number of magnets and the cost of magnet assembly of the stator can also be reduced as compared to arranging the magnets along the entire circumference of the reaction element.

One embodiment of the invention provides that: the active component sections of each section pair are arranged at the sides of the reaction element which are diametrically opposite with respect to the circumference of the reaction element. In contrast to, for example, an arrangement of the active component sections at axially opposite sides of the reaction element with respect to the axis of rotation, the configuration of the invention generally enables a simpler coupling of the rotor to the element to be driven by the electric machine, since the arrangement of the active component sections at the radially opposite sides of the reaction element enables a direct axial connection of the reaction element to the element to be driven.

Another embodiment of the invention provides that: the stator has a plurality of segment pairs arranged in an equally spaced manner from each other along the circumference of the reaction element. This embodiment of the invention makes the effect of the active component segments on the reaction element more uniform than the arrangement of a segment pair or a plurality of segment pairs, for example in only one region of the circumference of the reaction element.

Another embodiment of the invention provides that: the stator has an even number of segment pairs, the first active component segments of each two adjacent segment pairs being arranged on different sides of the reaction element. In other words, the design of the invention provides: the first active component sections are alternately arranged on different sides of the reaction element along the circumference of the reaction element, and the second active component sections are likewise alternately arranged on different sides of the reaction element along the circumference of the reaction element. In this way, the attractive forces of the active component sections on the reaction element are counteracted, which also relieves the load of the support of the reaction element.

Another embodiment of the invention provides a bearing arrangement for supporting a reaction element on a stator. In this way, a small air gap between the reaction element and the active part of the stator can be set and maintained by the bearing arrangement, as a result of which a high torque can advantageously be applied to the reaction element by the active part.

Another embodiment of the invention provides that: the reaction element is supported in such a way as to move relative to the stator in a plane perpendicular to the axis of rotation. In other words, this embodiment of the invention provides: the reaction element is not only rotatably about the axis of rotation but is also slidably supported in a plane perpendicular to the axis of rotation, in which plane small displacements can also be achieved, for example by means of the aforementioned bearing arrangement. In this way, manufacturing tolerances and thermally dependent expansion changes of the reaction element and/or the active component can be advantageously compensated.

A further embodiment of the invention provides a cooling device for cooling all first active component sections and/or all second active component sections. This advantageously reduces losses due to heating of the electromagnets and/or permanent magnets of the active component section, thereby increasing the efficiency of the electric machine.

Another embodiment of the invention provides that: the two adjacent permanent magnets of each second active component section have opposite magnetic poles. Thereby, magnetic driving can be advantageously achieved by the permanent magnet.

Another embodiment of the invention provides that: each electromagnet of the first active component segment of each segment pair is opposed to two adjacent permanent magnets of the second active component segment of the segment pair. Thereby, the arrangement of the permanent magnets of the second active component is advantageously adapted to the arrangement of the electromagnets of the first active component.

Another embodiment of the invention provides that: the first active component section of each section pair has twelve electromagnets. For example, the reaction element has seventeen or nineteen magnetizable regions in the region of each segment pair. The arrangement of twelve electromagnets in the first active component section and the arrangement of seventeen or nineteen magnetizable regions of the reaction element in the region of these twelve electromagnets surprisingly proves to be particularly effective.

Another embodiment of the invention provides that: the electromagnets of the first active component section of each section pair are fed with a three-phase current system, wherein each electromagnet is assigned a phase of the current system. Advantageously, this enables the use of a three-phase current system for operating the electric machine. In this case, for example, the electromagnets of each phase of the current system form in this case every two adjacent pairs of electromagnets with mutually different poles, between which there is in each case one pair of magnets of each of the other two phases, and the two adjacent electromagnets of the mutually different phases have the same pole. An electromagnet of a phase of the current system is understood here as an electromagnet assigned to this phase. The aforementioned allocation of the phases of the electromagnets and their polarities has proved to be particularly advantageous.

Another embodiment of the invention provides that: the non-magnetic region of the reactive element is made of a ceramic material. Due to its magnetic and mechanical properties, ceramic materials are particularly suitable for the production of the non-magnetic regions of the reaction element.

Another embodiment of the invention provides that: the magnetizable regions of the reaction element are made of a soft magnetic material. The soft magnetic material can be easily magnetized in a magnetic field and is therefore particularly advantageously used for producing the magnetizable regions of the reaction element.

Drawings

The above features, characteristics and advantages of the present invention and methods and modes for achieving them will be more clearly understood from the following description of embodiments, which is explained in more detail in conjunction with the accompanying drawings. The figures show that:

fig. 1 shows a sectional view of a first embodiment of a rotating electric machine, the sectional view having a section perpendicular to the axis of rotation of the machine;

fig. 2 shows a sectional view of a segment pair of two active component segments and a reaction element of a rotating electrical machine;

fig. 3 shows a perspective view of a segment pair of two active component segments and a reaction element of a rotating electrical machine;

fig. 4 shows a cross-sectional view of a first active part of the rotating electrical machine;

fig. 5 shows a sectional view of a second embodiment of the rotary electric machine, with a section in which the axis of rotation of the electric machine is located.

In the figures, corresponding parts are provided with the same reference numerals.

Detailed Description

Fig. 1 schematically shows a first embodiment of a rotating electric machine 1. The electric machine 1 has a stator 2 and a rotor 4 which is rotatable relative to the stator 2 about a rotational axis 6. Fig. 1 shows a sectional view with a section perpendicular to the axis of rotation 6.

The rotor 4 has an annular reaction element 5 which extends along a reaction element circumference 11 around the axis of rotation 6.

The stator 2 has three segment pairs 3 of two active component segments 7, 9 each arranged equidistantly spaced along the reaction element circumference 11. The two active component sections 7, 9 of each section pair 3 are arranged on diametrically opposite sides of the reaction element 5 with respect to the reaction element circumference 11, such that an arc of the reaction element circumference 11 extends between the two active component sections 7, 9.

Fig. 2 and 3 show a segment pair 3 and a part of a reaction element 5 of the rotating electric machine 1 shown in fig. 1, respectively. Fig. 2 shows a sectional view and fig. 3 shows a perspective view.

The first active component section 7 of each section pair 3 has a plurality of electromagnets 13 which are arranged continuously along an arc of the reaction element circumference 11 which extends between the two active component sections 7, 9 of the section pair 3. The electromagnets 13 each have a winding coil 15 of an electrical winding. The first active component 7 also has an active component lamination stack 17 with teeth 18 facing the second active component section 9 and grooves 19 extending between the teeth 18, wherein a winding coil 15 is wound on each tooth 18 such that the winding coils 15 of the two electromagnets 13 extend through each groove 19. In other embodiments, instead of having only one active component lamination stack, the first active component section 7 can have a plurality of active component lamination stacks 17 for one electromagnet 13 each or for a plurality of electromagnets 13.

The second active component section 9 of each section pair 3 has a plurality of permanent magnets 21 arranged consecutively along a circular arc extension on a permanent magnet carrier 20, wherein each electromagnet 13 of the first active component section 7 of a section pair 3 is opposite to two adjacent permanent magnets 21 of the second active component section 9. Each two adjacent permanent magnets 21 of each second active component section 7 have opposite magnetic poles.

The first active component sections 7 are each arranged on a side of the reaction element 5 facing away from the axis of rotation 6, and the second active component sections 9 are each arranged on a side of the reaction element 5 facing the axis of rotation 6.

The reaction element 5 has a plurality of non-magnetic regions 23 and a plurality of magnetizable regions 25. The non-magnetic regions 23 and the magnetizable regions 25 are arranged alternately along the reaction element circumference 11 such that a non-magnetic region 23 is arranged between every two adjacent magnetizable regions 25 and a magnetizable region 25 is arranged between every two adjacent non-magnetic regions 23.

The nonmagnetic regions 23 are each made of a nonmagnetic material, for example of a ceramic material or of a fiber-reinforced synthetic material.

The magnetizable regions 25 are each at least partially made of a magnetizable material, for example of a soft magnetic material. Preferably, the magnetizable regions 25 each have a lamination stack of electrical steel sheets.

The extension of the magnetizable region 25 along the reaction element circumference 11 is for example between 80% and 120% of the extension of the non-magnetic region 23.

Fig. 4 shows a cross-sectional view of the first active component section 7. The electromagnets 13 of the first active component section 7 are fed with a three-phase current system, wherein each electromagnet 13 is assigned to one phase U, V, W of the current system. Here, the electromagnets 13 of each phase U, V, W of the current system form a magnet pair consisting of two adjacent electromagnets 13 having different magnetic poles, one magnet pair of each of the other two phases U, V, W between the two magnet pairs of each phase U, V, W, and each two adjacent electromagnets 13 of the mutually different phases U, V, W have the same magnetic pole.

In the embodiment shown in fig. 2 to 4, each first active component section 7 has twelve electromagnets 13 and each second active component section 9 has twenty-four permanent magnets 21. The reaction element 5 has seventeen magnetizable regions 25 in the region of the segment pair 3. In other embodiments, the segment pairs 3 can have a different number of electromagnets 13 and permanent magnets 21, and the reaction element 5 can have a different number of magnetizable regions 25 and non-magnetic regions 23 in the region of the segment pairs 3. Furthermore, in other embodiments, electromagnet 13 can be provided with a different distribution than that of phase U, V, W from that of fig. 4.

However, it has proved to be particularly advantageous: if the first active component section 7 has twelve electromagnets 13 and the second active component section 9 has twenty-four permanent magnets 21, the reaction element 5 has seventeen or nineteen magnetizable regions 25 in the region of the segment pair 3, and the electromagnets 13 are assigned to the phase U, V, W as in fig. 4.

Fig. 5 shows a second embodiment of the rotary electric machine 1. The electric machine 1 has a stator 2 and a rotor 4 which is rotatable relative to the stator 2 about a rotational axis 6. Fig. 5 shows a sectional view with a section in which the axis of rotation 6 is located.

The rotor 4 has an annular reaction element 5 which extends along a reaction element circumference 11 around the axis of rotation 3 and is constructed like the reaction element 5 of the exemplary embodiment described in fig. 1 to 4.

The stator 2 has a plurality of segment pairs 3 of two active component segments 7, 9 arranged spaced apart from one another along the reaction element circumference 11. The two active component sections 7, 9 of each section pair 3 are arranged on the section carrier 27 on the diametrically opposite side of the reaction element 5 with respect to the reaction element circumference 11, such that the arc of the reaction element circumference 11 extends between the two active component sections 7, 9. The two active component sections 7, 9 of each section pair 3 are constructed like the active component sections 7, 9 of the exemplary embodiment described in fig. 1 to 4, wherein, on the other hand, the first active component section 7 of each section pair 3 has an electromagnet 13 and the second active component section 9 has a permanent magnet 21.

However, in contrast to the exemplary embodiments described with reference to fig. 1 to 4, the first active component sections 7 of the exemplary embodiment shown in fig. 5 are each arranged on a side of the reaction element 5 facing the axis of rotation 6, and the second active component sections 9 are each arranged on a side of the reaction element 5 facing away from the axis of rotation 6. Furthermore, the stator 2 of this exemplary embodiment has an even number of segment pairs 3, wherein each two segment pairs 3 are diametrically opposite to one another with respect to the reaction element circumference 11.

The electric machine 1 also has a cooling device 29 for cooling the active component sections 7, 9. The cooling device 29 has a coolant circuit in which coolant (e.g. cooling water) is conducted in a cooling pipe 31 from a coolant reservoir 33 to the active components 7, 9 and from the active components 7, 9 back into the coolant reservoir 33 by means of a pump 35.

The electric machine 1 furthermore has a bearing device 37 for supporting the reaction element 5 on the stator 2. The bearing arrangement 37 has, for example, a plain bearing or a rolling bearing, by means of which the side of the reaction element 5 facing the axis of rotation 6 and the side facing away from the axis of rotation 6 are each supported on the stator 2. Furthermore, the reaction element 5 can be mounted slidably relative to the stator 2 by means of a bearing arrangement 37 in a plane perpendicular to the axis of rotation 6.

The rotor 4 is connected to a drive stage 39, which is rotatably mounted about an axis of rotation by a bearing 41 and by means of which, for example, a telescope, a turntable, a wind power tower or a flywheel can be rotated together with the electric motor 1. The rotor 4 and the turntable 6 are supported in a movable manner relative to one another in a plane perpendicular to the axis of rotation 6, for example by spring elements 43 which are each elastically deformable in a radial direction with respect to the reaction element circumference 11 and connect the reaction element 5 with the drive table 39.

The embodiment of the electrical machine 1 described with reference to fig. 1 to 5 can be varied in different ways. For example, the exemplary embodiments described with reference to fig. 1 to 4 can also have a cooling device 29 and/or a bearing device 37 like the exemplary embodiment described with reference to fig. 5. Furthermore, the two active-component sections 7, 9 of the section pair 3 can also be arranged opposite one another instead of in the radial direction with respect to the reaction element 11. For example, the two active component sections 7, 9 of the section pair 3 can be opposite in the axial direction with respect to the axis of rotation 6, so that the two active component sections are arranged on different sides of a plane in which the reaction element circumference 11 extends. Furthermore, the stator 2 can have an even number of segment pairs 3, wherein the first active-component segments 7 of every two adjacent segment pairs 3 are arranged on different sides of the reaction element 5.

Although the invention has been shown and described in detail by means of preferred embodiments, the invention is not limited by the disclosed examples and other variants can be derived therefrom by the person skilled in the art without departing from the scope of protection of the invention.