DE102016224071A1 - MULTIPLE STATOR FOR AN ELECTRIC MOTOR, METHOD FOR MANUFACTURING A MULTIPLE STATUS, ELECTRIC MOTOR AND HEAT PUMP - Google Patents

Abstract

A stator for an electric motor has a first stator element (10) having a first connection region (14) to which a first group of at least two pole feet (12a-12d) is attached and a second stator element (20) having a second connection region (24) on which a second group of at least two pole feet (22a-22d) is mounted, wherein coils (16a-16d) are wound around each pole leg of the first and second groups, and wherein the first stator element (10 ) and the second stator element (20) are joined such that a pole leg (12a) of the first group is adjacent to a pole leg (22a, 22b) of the second group, and in a pole leg gap (31, 32) between the adjacent pole legs Part of a coil (16a-16d), which is wound around the pole leg of the first group, and a part of another coil, which is wound around the pole leg of the second group, are arranged.

Description

The present invention relates to electric motors and more particularly to stators for such electric motors.

The EP 2 549 113 A2 discloses a magnetic rotor and a rotary pump with a magnetic rotor. The rotor is for driving a fluid in a pump housing within a stator of the rotary pump magnetically non-contact drivable and storable. In addition, the rotor is encapsulated by means of an outer encapsulation comprising a fluorinated hydrocarbon. Within the encapsulation, the rotor comprises a permanent magnet encased in a metal jacket. The rotary pump includes a pump housing having an inlet for supplying a fluid and an outlet for discharging the fluid. The fluid is, for example, a chemically aggressive acid with a proportion of a gas, e.g. As sulfuric acid with ozone. To convey the fluid, a magnetic rotor is magnetically non-contact in the pump housing. The rotor is further provided with a magnetic drive having electric coils. The stator is formed with laminated iron, which is in magnetic operative connection with the permanent magnet of the rotor. The drive is designed as a bearingless motor in which the stator is designed as a bearing stator and drive stator at the same time. The rotor is designed as a pancake, wherein the axial height of the rotor is less than or equal to half the diameter of the rotor.

The dissertation ETH No. 12870, "The bearingless disk motor", N. Barletta, 1998 , discloses magnetically supported disc motors. Magnetic bearings work completely free from contact, wear, maintenance and lubricant. For the active stabilization of a degree of freedom, two controllable electromagnets including electronic control are required. The bearingless disc motor is used within a bearingless blood pump as a bearingless disc motor with active axial bearing, as a miniature disc motor, or as a bearingless bioreactor. By a combination of passive reluctance magnetic bearings and bearingless motor, it is possible to completely support a disc rotor with only two actively stabilized radial degrees of freedom. Requirements for a large air gap, which is necessary in hermetic systems are suitable by the selection of a bearingless for driving an axial pump for cardiac support, is designed for speeds of 30,000 revolutions per minute, resulting in a smaller size.

Commercial electric disc motors are also known by the name "Pan Cake Motor" ("pancake motor"). The engine concept illustrated in the two preceding references is characterized in that the stator extends around the rotor. Such engines are also referred to as internal rotor.

In the case of the internal rotor concept, there is the problem that the stator always has to be larger than the rotor, that is, the size and design of the rotor is always limited by the stator housing or that the rotor dominates the formation of the stator. Thus, the field of application of such a disc motor, which is designed as an internal rotor, limited.

In addition, disk motors generally have the problem that the rotor, regardless of whether it is designed as an internal rotor or external rotor, pressure differences or pressures in certain directions is exposed. These pressures cause a bearing to be loaded in the direction of pressure acting on the rotor, thus increasing wear, or, if rotor deflection is allowed, the rotor is deflected in that direction and thus leeway for this deflection must be provided. In particular, when the pump is used to pump a medium from a pressure area at a first pressure to a pressure area at a second pressure, or to generate such a pressure difference at all, complex design measures must be taken to either a required To achieve wear resistance, or to provide a margin for an occurring deflection.

The smaller the engines are and the closer the engines are to be packed, d. H. the closer together the individual pole feet and coils are to be arranged around the pole feet, the more problematic the question arises as to how the individual motors or the windings can be produced in the stator. On the one hand you want to have a lot of coils in a very small space. In addition, all stator concepts, even if they are packed so tightly, at some point in the manufacturing process with coils are provided, so be wound.

The JP 2001119874 A discloses a stator of a rotary electric machine. A stator core is divided into an annular yoke portion and a magnetic-wheel-shaped magnetic-wheel part. In particular, a connection part which connects the radiation wheel to the yoke part is provided with short-circuit coil windings.

The CN 202888986 U discloses a stator core consisting of a plurality of stator core units mounted on a stator hub by fasteners. The core unit forms a magnetic pole. Furthermore, cooling sections are provided.

The US 2006/0071114 A1 discloses a stator core winding apparatus that can continuously generate windings on each one of a correspondingly split core element of a single stator core. In particular, each individual stator core has narrow spaces between large claws of adjacent core elements.

A disadvantage of the procedure described is that the assembly is very expensive. So each Polfuß is present individually, must be taken individually to wrap it, and then each Polfußfuß must be individually attached to a corresponding fastener, or it must be a complex mechanically challenging individual attachment of the individual pole feet together. In particular, the orientation of the individual pole feet and the handling are problematic to ultimately get a stator for an electric motor that rotates, and is designed for high speeds. Furthermore, the handling of many small parts is cumbersome when an electric motor is to be produced whose dimensions are in the decimeter range.

The object of the present invention is to provide an improved stator concept for an electric motor.

This object is achieved by a stator for an electric motor according to claim 1, a method for producing a stator according to claim 16, an electric motor according to claim 19 or a heat pump according to claim 22.

The present invention is based on the recognition that a stator consists of two or more stator elements. Then the individual pole feet can be wrapped well, d. H. are well provided with coils, because they have a greater distance from each other as compared to a situation in which the stator is integrally formed as a whole. On the other hand, however, each stator element is formed so as to have at least two, and preferably three, four or five pole feet in total, already aligned with each other by the fabrication themselves, because they are integrally formed with a connection region which is also part of a stator element , Thus, the pole feet, which belong to a stator element, are already aligned optimally with one another. However, if a stator element is not formed integrally with the pole feet, but provided with pole feet after production, then already the pole feet of a stator element can be aligned optimally for itself. The stator elements can be in the disassembled state, so if they are not mated, yet cheap and efficient with a coil winding each around a pole around around, since the distances between the individual pole feet are much larger than in a comparison case in which a stator integrally formed is and all pole feet are arranged side by side, before a winding would be performed.

Then, after the winding of a coil around each pole leg, the stator elements are joined together with the coil feet already wrapped with coils, such that a pole leg of the first group is adjacent to a pole leg of the second group, and that in a Polfußfußraum between the adjacent Polfüßen a part of a coil, which is wound around the pole leg of the first group, and a part of another coil, which is wound around the pole leg of the second group, are arranged.

By this nested or "interleaving" arrangement ensures that the pole feet actually have a comparatively large distance before joining, because then by joining, between two pole feet of a connecting element another pole leg of the other connecting element is inserted. Even with relatively small stators, this space is so large that not only can a free winding be made around, ie around the pole feet, but even a so-called orthocyclic winding can be made around each pole leg. This orthocyclic winding ensures that an optimal fill factor greater than 90% can be achieved.

Thus, the inventive integration of the coil winding in the Statorherstellungsprozess on the one hand creates a way to produce optimal windings around the individual pole feet around with limited effort, while on the other hand ensures that the assembly effort compared to the use of each individually wrapped individually Pole feet is greatly reduced. The provision of two or preferably three, four or even more pole feet per stator element also considerably reduces the alignment effort because, compared to the single assembly, as known in the art, only two stator elements, each of which has a plurality of pole feet, already are wound with coils, must be aligned with each other, while in the prior art, each individual Polfuß must be aligned to all other pole feet.

In addition, the joint handling of several pole feet in the winding and the assembly is easier to handle when the dimensions of the stator or the electric motor in dimensions in the decimeter range.

By the use of stator elements with connecting areas on the one hand and a plurality of pole feet on the other hand, preferably a somewhat automatic alignment of the two stator elements is achieved, to the effect that the two elements are formed positively, so that they are already aligned by the assembly and to some extent "jammed" are, so when they are assembled, no longer "wobble". This further ensures that the stator elements, which are indeed made of ferromagnetic sheet metal stacks, are in good contact with each other, such that the magnetic flux through the coil carrier, by the two stator elements, when the stator has exactly two stator elements, or by a plurality of stator elements if the stator has more than two stator elements, is formed, is favorable.

• 1a eine Seitenansicht eines ersten Statorelements mit einem Verbindungsbereich und wenigstens zwei Polfüßen;
• 1b eine Querschnittsansicht durch ein Statorelement mit durchgeschnittenen Polfüßen und einer Draufsicht auf den Verbindungsbereich;
• 2 eine Draufsicht auf ein Statorelement mit vier Polfüßen mit jeweils aufgewickelten Spulen vor dem Zusammenbau;
• 3 eine Ansicht von zwei Statorelementen mit jeweils vier Polfüßen in auseinandergebautem Zustand;
• 4 eine perspektivische Darstellung der zwei Statorelemente von 3 in teilweise zusammengebautem Zustand, ohne dass Spulen aufgewickelt sind;
• 5a eine Draufsicht auf einen Stator mit zwei zusammengebauten Statorelementen, wobei jedoch keine Spulen aufgewickelt sind;
• 5b eine schematische Darstellung einer orthozyklischen Wicklung auf einem Polfuß;
• 6 ein Flussdiagramm eines bevorzugten Ausführungsbeispiels eines Verfahrens zum Herstellen eines Stators;
• 7 eine schematische Darstellung eines Magnetlagers am Beispiel eines Innenläufers mit außenliegendem Stator und Permanentmagneten am innenliegenden Rotor; und
• 8 einen schematischen Querschnitt durch eine Wärmepumpe mit einem Elektromotor, der den erfindungsgemäßen Stator aufweist.

Preferred embodiments of the present invention will be explained below in detail with reference to the accompanying drawings. Show it:

• 1a a side view of a first stator with a connecting portion and at least two pole feet;
• 1b a cross-sectional view through a stator element with cut-through pole feet and a plan view of the connection region;
• 2 a plan view of a stator element with four pole feet with each wound coils before assembly;
• 3 a view of two stator elements, each with four pole feet in disassembled state;
• 4 a perspective view of the two stator elements of 3 in partially assembled condition, without coils being wound up;
• 5a a plan view of a stator with two assembled stator elements, but with no coils are wound;
• 5b a schematic representation of an orthocyclic winding on a pole base;
• 6 a flowchart of a preferred embodiment of a method for producing a stator;
• 7 a schematic representation of a magnetic bearing on the example of an internal rotor with external stator and permanent magnets on the inner rotor; and
• 8th a schematic cross section through a heat pump with an electric motor having the stator according to the invention.

1 shows a view of a stator, from which, together with another different or the same stator element, a stator for an electric motor consists. In particular, the stator element comprises 10 , this in 1a shown is a first pole foot 12a and a second pole foot 12b , Furthermore, both are pole feet 12a . 12b over a connection area 14 connected with each other. A stator for an electric motor further comprises a second stator element which is similar to the stator element in FIG 1a formed in preferred embodiments of the present invention. Further, around each pole leg of a first group of two pole feet 12a one coil each 16a . 16b wrapped as it is in the 1b shown schematic cross section is shown. 1 shows a plan view of a stator element, such as the first stator element 10 with wound coils. In particular, the first stator element included in 2 shown is the first connection area 14 , where a first group of at least two pole feet, here four pole feet 12a . 12b . 12c . 12d , is appropriate. Further, around each pole leg of the shown first group of pole feet 12a to 12d one coil each 16a . 16b . 16c . 16d wound. At the in 2 embodiment shown is the pole leg 12a a coil 16a wound. It is also around the pole foot 12b a coil 16b wound. In addition, around the pole foot 12c a coil 16c wrapped, and is around the pole foot 12d a coil 16d wound. All four pole feet are with the connection area 14 connected.

According to the invention, the first and second stator elements are joined such that a pole leg of the first group is adjacent to a pole leg of the second group, and in a pole leg gap between the adjacent pole feet a part of a coil wound around the pole leg of the first group, and a part of another coil wound around the pole leg of the second group.

Hereinafter, referring to the 3 . 4 and 5 an embodiment of the present invention is shown in which exactly two stator elements are present, each stator element each having four pole feet, and wherein the two stator elements are formed identical to each other. In particular shows 3 left in the picture the first stator element 10 and on the right in the picture the second stator element 20 , In particular, the second stator element comprises 20 a second connection area 24 , on which a second group of at least two pole feet, in which case for example four pole feet are shown, is attached. The four pole feet are the pole feet 22a . 22b . 22c . 22d , The second stator element 20 in 3 is identical to the first stator element in this embodiment 10 left in 3 trained, but vice versa represented, namely in the position as it is joined together. A situation where the second stator element 20 is connected to the first stator element 10 already partially interlocked, is in 4 shown. In particular, it is shown how a Polfuß, for example, the Polfuß 12a the first group of pole feet, to a pole foot, such as the pole foot 22a or the pole foot 22b the second group of pole feet is adjacent to the second stator element. Furthermore, in 4 shown how results from the joining of the two stator each Polfußfußraum between two adjacent pole feet of different groups. Such Polfußzwischenraum is z. At 31 or 32 in 4 shown. It should be noted, however, that in the in 4 shown illustration to illustrate the stator is shown a situation in which the coils are not wound around the respective pole feet. In fact, around each pole leg of the two stator elements 10 . 20 even before they are partially and then completely assembled, the individual coils are wound up as it is in 2 based on the first stator element 10 is shown.

5a shows a bobbin with two stator elements in the assembled state. In particular, in the in 5a embodiment shown, the two stator elements 10 . 20 completely pushed into each other, so that results in a flat surface. It should be noted that the in 3 . 4 and 5a shown respective stator element is only an existing pattern of sheet metal stacks. In particular, in a stator for an electric motor, each of the two stator elements is formed from respectively stacked thin sheets of ferromagnetic material, as is known and is the case with typical electric motors.

6 shows a preferred embodiment of a method for producing the stator for an electric motor. In one step 60 For example, the two or more stator elements are provided separately for themselves, such as by cutting sheet metal stacks.

In one step 62 Insulation sheathing is attached around the individual pole feet as it is in 5a also not shown. This is how it works in one step 64 a coil is wound around each pole leg and in particular around each insulation sheath. In one step 66 the two stator elements are then joined together with respective wound coils, as shown in FIG 5a is shown when 5a is still supplemented by the insulation sheath and the coils. In one step 68 The stator is then overmolded with an encapsulating material to hold the elements and coils in shape.

The attachment of the two stator elements to each other takes place depending on the implementation by a press fit. The two stator elements are thus designed accordingly so that the two stator elements typically at the respective pole feet, ie in a region which in 1a 17, touch. Due to the structural stability of the respective stator elements, a force is applied to the corresponding surface when compressed 17 instead, so that the two stator elements are held in position. Alternatively or additionally, an adhesive may be used to permanently fix the two stator elements. However, this is typically not necessary, because at the latest by the encapsulation of the stator with encapsulation material in the step 68 the two stator elements are firmly attached to each other.

Hereinafter, preferred embodiments of the stator are shown. Preferably, the pole feet 12a to 12d the first group has a greater thickness D than the connection area. The same preferably also applies to the second stator element 20 , so that the two stator elements can be joined together well, and thus in particular at the corresponding Polfußflächen 17 when joining a corresponding force acts, which contributes to a structural stability of the two stator elements.

As with the in 5a In the embodiment shown, the number of pole feet in each group of pole feet is preferably the same for each stator element. However, depending on the implementation, this may not necessarily be the case. However, it contributes to the symmetry of the stator, which is particularly advantageous when the stator is used for an electric motor that runs at very high speeds, such as at speeds greater than 50,000 revolutions per minute.

Preferably, further, a thickness d of the connection area 14 of the first stator element equal to a thickness of the connection region 24 of the second stator element. In addition, preferably, a thickness D of the pole feet of the respective stator elements for the two stator elements is identical.

Preferably, the first connection area comprises 14 or the second connection area 24 or both connection areas 14 . 24 a polygonal shape with a respective number of corners, with a pole leg attached to each corner. If, for example 5a is considered, the polygonal shape is a quadrilateral and in particular in 5a a square, with a pole leg attached to each corner. A square has four corners, and therefore the stator element comprises four pole feet. For an embodiment in which a total of three Pole feet are used per stator element, the polygonal shape would be a triangle. If five pole feet are used, the polygonal shape would be a pentagon. In any case, it is always ensured, if at least two stator elements are put together, that enough free space remains to wind a coil on a pole leg, but at the same time, when the two pole feet are pushed onto each other with wound coils, a relatively small clearance is created , such as the gap 31 or 32 in 5a , in which a high fill factor is achieved.

Preferably, the number of turns per coil wound around a pole leg is greater than or equal to 15 and less than or equal to 50, with particularly preferred numbers of turns between 20 and 30.

Further, each coil wound around a pole leg of the first or second group comprises a winding having at least two layers, wherein a second layer wound on a first layer is mounted so that always a wire of the second layer is between two Wires of the first layer is arranged, wherein an axis of a wire of the upper layer is disposed substantially midway between two axes of two adjacent wires of the lower layers, and wherein adjacent wires in a position to touch. Such a winding is also referred to in the art as orthocyclic winding and results in an optimum degree of filling of over 90%. This orthocyclic winding can be readily applied because there is enough space between the individual pole feet. In contrast, it would not be possible or only with great effort, in the composite stator element, as in 5a is shown, after assembly to wrap the individual pole feet coils, because too little space remains.

5b shows a schematic representation of a Polfußes, such as the Polfußes 12c on which an orthocyclic winding is wound, which is a lower layer 50 and an upper layer 51 having. In particular, a wire of the upper layer is always arranged between two wires of the lower layer, wherein in each case, as in 5b 5, an axis of a top layer wire, the axis being shown schematically at 52, between two axes of the adjacent wires shown in FIG 5b at 53 are shown schematically, and which relate to the lower layer, is arranged. In particular, this arrangement is substantially centered so that the orthocyclic winding results in an optimum and maximum degree of filling in the interstitial space 31 . 32 and especially for the entire coil.

As it is in 5a is shown, the stator comprises a total of eight pole feet. Preferably, other numbers are constructed, such as 12 pole feet, 16 pole feet, 20 pole feet or preferably a number of pole feet, which is divisible by four, since then the division into two stator elements is particularly favorable and particularly symmetrical executable, and then always at least four pole feet per stator element are each arranged at a connection region and thus already aligned with each other.

Preferably, the first connection area 14 and the second connection area 24 a disk-like shape, wherein a first surface of the first connecting portion 14 , and especially those in 3 illustrated lower surface of the first connection area 14 of the first stator element defines a first surface of a coil carrier of the stator, which is obtained by the two stator elements. Further, the second surface of the first connection region is located 14 , so in 3 , left image, the upper surface, on the first surface of a second connection area 24 of the second stator element, wherein this first surface of the second stator element, the in 3 shown lower surface is. It also defines the second surface, ie in 3 , right picture, the top of the connection area 24 , a second surface of the bobbin.

In addition, the first connection area include 14 , Preferably, the second connection region, in each case between two points at which a Polfuß is attached, ie at 15 in 3 , left picture, a flat face, with this flat face 15 abuts a respective side of a Polfußes of the second stator, at which the respective Polfuß 22a to 22d not with the second connection area 24 connected is. This pole foot is for example in 1a at 17 shown. By pushing together thus lies the flat front 15 on the flat side 17 of the pole leg, to thereby provide structural stability, and at the same time to achieve a somewhat automatic alignment between the first stator element and the second stator element.

While at the in 3 to 5 an external rotor is shown 7 an implementation of the present invention as an internal rotor. There are the stator 200 outside and the rotor 1 formed inside, being between the two elements of the motor gap 40 is arranged.

Preferably, the rotor is supported relative to the stator by a magnetic bearing, as exemplified in US Pat 7 is shown. In 7 the two directions are axially 250 and radially 260th located. There is again a motor with a motor gap 40 and the rotor is held axially with respect to the stator due to the permanent magnets on the side of the rotor and the electrical coils on the side of the stator and not specifically regulated. Furthermore, in 7 a radial detection device 270 and a radial control device 280 intended. The radial detection device 270 includes the position of the rotor with respect to the stator and vice versa via detection lines 271 , The result of the radial detection is via a sensor line 272 the radial control / regulation device 280 communicated. This generates correspondingly the actuator signals via Aktorsignalleitungen 273 on the rotor or the stator depending on the implementation. However, it is preferred to drive only the rotor to position it relative to the stator due to the actuator signal, such that the motor gap 40 around the entire rotor has a similar size and the rotor does not touch the stator.

At the in 7 embodiment shown is the rotor 1 inside and the stator 200 is arranged outside. This is thus an internal rotor in contrast to, for example 3 . 4 , or 5. The appropriate control / regulation by the elements 270 . 280 . 271 . 272 . 273 However, this can also happen with an outrunner. In principle, however, the magnetic bearing on the example of in 7 In both cases, the reluctance bearing shown similar in that an axial control does not take place, while a radial control by the radial detection means 270 and the radial controller 280 takes place.

8th shows a preferred application of the pancake motor on the example of a heat pump. The heat pump includes an evaporator 300 , a compressor 400 and a liquefier 500 , where the compressor 400 having the electric pancake motor, the reference to the 1a to 5 has been described.

In addition to the elements of the pancake motor illustrated, for example, with reference to one of the preceding figures, the compressor further comprises a void space 410 which is arranged radially to that of the element to be moved 105 funded working steam coming from the evaporator 300 has been sucked in, further and finally the pressure to the required pressure in the condensation zone 510 in the condenser 500 to increase.

Liquid to be cooled passes through an evaporator inlet 302 in the evaporator. Cooled working fluid passes through an evaporator outlet 304 again from the evaporator. To make sure the radial wheel 105 only steam and not water drops in addition to the steam sucks, is also a mist eliminator 306 intended. Due to the low pressure in the evaporator 300 becomes part of the over the evaporator feed 302 in the evaporator 300 brought working fluid evaporated and through the mist eliminator 306 through the second page 105b sucked the radial wheel 105 and conveyed upwards and then into the Leitraum 510 issued. From the Leitraum 510 becomes compressed working steam in the condensation zone 510 brought. The condensation zone 510 is also via a condenser feed 512 supplied to be heated working fluid, which is heated by the condensation with the heated steam and a condenser 514 is dissipated. Preferably, the condenser is designed as a condenser in the form of a "shower", so that via a distribution device 516 a liquid distribution in the condensation zone 510 is reached. Thus, the compressed working steam is condensed as efficiently as possible and the heat contained in it is transferred into the liquid in the condenser.

At the in 8th embodiment shown is also a motor housing 110 located at the same time, the upper housing part of the condenser or condenser 500 forms. In addition, a connection cable 80 for the coils of the stator 200 with a controller 600 connected to perform the appropriate speed controls and at the same time the active storage on a preferably used magnetic bearing, as shown by 7 has been described. The controller thus also provides the functions of radial detection 270 and the radial control / regulation 280 ready.

In addition, in 8th an implementation shown in which the pancake motor a fixed potted block 602 made of potting material, which has a sealing ring 603 with respect to the motor housing 110 is sealed so that a pressure-tight separation between the exterior and the interior takes place. Both the bobbin holder and the coils are surrounded by an encapsulation material that is in 8th as integral with the solid block 602 is shown formed. However, this does not necessarily have to be the case. However, it is preferable to cause separation by the encapsulant material extending in the motor gap, so that the coils are not disposed in the low pressure area provided inside the motor housing.

Furthermore, in the in 8th shown embodiment, the stator disposed in a recess which through an upper side 105a is defined. In other embodiments, however, the rotor may be formed without a recess, so that the Area of magnet 201 , Return element 202 and bandage 203 as he is in 8th is shown, is placed on a top flat shaped radial wheel.

Out 8th It can also be seen that the element to be moved, with the rotor 10 is connected, the radial wheel or impeller 105 that is there to work in conjunction with the route 410 To compress and heat the working steam conveyed by the evaporator so that heat is pumped from the evaporator to the condenser.

Although certain elements are described as device elements, it should be understood that this description is likewise to be regarded as a description of steps of a method and vice versa.

It should also be noted that a control, for example, by the element 600 in 8th can be implemented as software or hardware. The implementation of the controller may be on a non-volatile storage medium, a digital or other storage medium, in particular a floppy disk or CD with electronically readable control signals which may interact with a programmable computer system such that the corresponding method of operating a heat pump is performed. In general, the invention thus also comprises a computer program product with a program code stored on a machine-readable carrier for carrying out the method when the computer program product runs on a computer. In other words, the invention can thus also be realized as a computer program with a program code for carrying out the method when the computer program runs on a computer.

LIST OF REFERENCE NUMBERS

1

rotor

10

first stator element

12a

Pole foot of the first group

12b

Pole foot of the first group

12c

Pole foot of the first group

12d

Pole foot of the first group

14

first connection area

15

Front side of the connection area

16a

first coil

16b

second coil

16c

third coil

16d

fourth coil

17

Front side of the pole foot

20

second stator element

22a

Polfuß of the second group

22b

Polfuß of the second group

22c

Polfuß of the second group

22d

Polfuß of the second group

24

second connection area

31

Polfußzwischenraum

32

Polfußzwischenraum

40

motor gap

50

lower layer of the winding

51

upper layer of the winding

52

Wire axis of a wire of the upper lower layer

53

Wire axis of an adjacent wire of the upper lower layer

60

Step of providing

62

Step of attaching the insulation

64

Step of winding

66

Step of joining

68

Step of overmolding

80

connecting cables

105

moving element / radial wheel

105a

upper side

105b

lower side

110

motor housing

180

management component

200

stator

201

permanent magnet

202

Return element

203

bandage

250

axially

260

radial direction

270

Radial detector

271

sense line

272

control line

273

actuator cable

280

Radial-control / regulation device

300

Evaporator

302

evaporator feed

304

evaporator flow

306

Droplet

400

compressor

410

route

500

condenser

510

condensation zone

512

Verflüssigerzulauf

514

Verflüssigerablauf

516

Verflüssigerverteiler

600

control

602

stator block

603

sealing ring

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2549113 A2 [0002]
• JP 2001119874A [0008]
• CN 202888986 U [0009]
• US 2006/0071114 A1 [0010]

Cited non-patent literature

• "The bearingless disk motor", N. Barletta, 1998 [0003]

Claims (22)

Stator for an electric motor, with the following features: a first stator element (10) having a first connection region (14) to which a first group of at least two pole feet (12a-12d) is attached, a second stator element (20) having a second connection region (24) to which a second group of at least two pole feet (22a-22d) is attached, wherein a coil (16a-16d) is wound around each pole leg of the first and second groups of at least two pole feet, and wherein the first stator element (10) and the second stator element (20) are joined such that a pole leg (12a) of the first group is adjacent to a pole leg (22a, 22b) of the second group, and in a pole leg gap (31, 32 ) between the adjacent pole feet, a part of a coil (16a-16d) which is wound around the pole leg of the first group, and a part of another coil, which is wound around the pole leg of the second group are arranged. Stator after Claim 1 in which the pole feet (12a-12d) of the first group have a greater thickness (D) than a thickness (d) of the first connection region (14), and wherein the pole feet (22a-22d) of the second group have a greater thickness than the second connection area (24). Stator after Claim 1 or 2 in which a number of pole feet of the first group of pole feet equals a number of pole feet of the second group of pole feet. A stator according to any one of the preceding claims, wherein a thickness of the first connection portion (14) is equal to a thickness of the second connection portion (24), or a thickness of the first group of pole legs is equal to a thickness of the second group of pole legs. Stator according to one of the preceding claims, wherein the first connection region (14) has a polygonal shape with a first number of corners, wherein at each corner a pole leg (12a-12d) is arranged, and in which the second connection region (24) has a polygonal shape with a second number of corners, wherein a pole leg (22a-22d) is arranged at each of the corners. A stator as claimed in any one of the preceding claims, wherein a number of turns per coil wound around a pole leg (12a-12d, 22a-22d) is greater than 15 and less than 50. Stator according to one of the preceding claims, in which the coils (16a-16d) wound around the pole feet of the first or second group comprise a winding with at least two layers, a second layer being wound on a first layer, is arranged such that always a wire of the second layer (51) is arranged between two wires of the first layer (50), wherein an axis (52) of a wire of the upper layer (51) substantially centrally between two axes (52, 53 ) of two adjacent wires of the lower layer (50), and wherein adjacent wires touch in one layer. A stator as claimed in any one of the preceding claims having a total number of pole feet equal to 8, 12, 16, 20 or another number divisible by four. Stator according to one of the preceding claims, in which exactly the first stator element (10) and exactly the second stator element (20) are present and the first and the second group of pole feet having the same number of pole feet, wherein the first stator element and the second stator element are joined together so that the pole feet of the first group are interleaved with the pole feet of the second group, so that a pole leg of the first group is always adjacent to two pole feet of the second group. Stator according to one of the preceding claims, wherein the first stator element (10) and the second stator element (20) are formed substantially the same. Stator according to one of the preceding claims, wherein the first connection portion (14) and the second connection portion (24) each have a disk-like shape, wherein a first surface of the first connection portion (14) is a first surface of a bobbin of the stator which is defined by the first stator member (10) and the first connection member second stator element (20) joined together is formed, wherein a second surface of the first connection portion (14) rests on a first surface of the second connection portion (24), and wherein a second surface of the second connection portion (24) forms a second surface of the coil support. Stator according to one of the preceding claims, in which the first connection region has in each case a flat end face (15) between two points at which a pole leg is arranged, wherein the flat end side (15) on one side (17) of a pole leg of the second connection region is present at the pole leg is not connected to the second connection area. Stator according to one of the preceding claims, wherein each stator element is formed from a sheet stack of ferromagnetic material, wherein the stator elements are formed and joined together so that the stator elements fit together form fit. A stator as claimed in any one of the preceding claims, wherein the pole feet of the first group and the second group are formed to each have an end face (17) projecting over a pole root winding area around which the coil is wound, so that a distance (S) between two end faces (17) of two adjacent pole feet is smaller than a distance (p) of the two pole feet in the respective Polfußwicklungsbereich. A stator as claimed in any one of the preceding claims, wherein each stator element (10, 20) is disk-shaped and has a diameter between 2.5 and 7 cm, and has a pole leg height between 0.5 and 2 cm. Method for producing a stator, having the following features: Providing (60) a first stator element (10) having a first connection region (14) to which a first group of at least two pole feet (12a-12d) is attached, and a second stator element (20) having a second connection region (14). 24) to which a second group of at least two pole feet (22a-22d) is mounted; after providing (60), winding (64) a coil around one pole leg (12a-12d) of the first group and one pole leg (22a-22d) of the second group; after winding (64), assembling (66) the first stator element (10) with the wound coils (16a - 16d) and the second stator element (20) with the wound coils so that a pole leg of the first group becomes a pole leg of the second Group adjacent, and that in a Polfußfußraum between the adjacent pole feet, a part of a coil, which is wound around the pole leg of the first group, and a part of another coil, which is wound around the pole leg of the second group are arranged. Method according to Claim 16 in which an insulation sheath is applied around each pole leg prior to winding (64) (62). Method according to Claim 16 or 17 in that, after assembly (66), spraying (68) of encapsulation material around the assembled stator is performed. Electric motor having the following features: a stator (200) according to one of Claims 1 to 15 ; and a rotor (1) having permanent magnets opposed to pole feet (12a - 12d, 22a - 22d) of the stator (200) via a motor gap (40). Electric motor after Claim 19 in which the rotor (1) is actively magnetically supported radially with respect to a rotational axis of the rotor, or in which the rotor is axially magnetically passive with respect to a rotational axis of the rotor. Electric motor after Claim 19 or 20 wherein the rotor (1) is integrally formed or connected to a member to be moved, wherein the member (105) to be moved is a radial wheel with vanes, the vanes being configured to receive gas from an area upon rotation of the radial wheel To promote lower pressure in an area with a higher pressure. Heat pump having the following features: an evaporator (300); a compressor (400); and a condenser (500), wherein the compressor (400) comprises an electric motor according to any one of Claims 19 to 21 identifies.

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