DE102006048561A1 - Transverse flux machine, has stator composed of ring segment-shaped sections in its circumferential direction, where sections stay in force-fit connection with one another and are mechanically connected with one another - Google Patents

Abstract

The flux machine has a ring-shaped stator (2) and a rotor arranged in a rotatable manner opposite to the stator, where a coil runs around the stator in a circumferential direction. The stator is composed of ring segment-shaped sections (2a-2f) in the direction. The ring segment-shaped sections stay in force-fit connection with one another, and are mechanically connected with one another. Teeth (14a-14f) are provided at the stator. Mechanical connections between the sections are clamp joints, press fittings, welded connections, clip connections and screw connections. An independent claim is also included for a method for the production of a transverse flux machine.

Description

The The present invention relates to a transverse flux machine (hereinafter also referred to as TFM for short).

such TFM are known in the art. Unlike normal electric machines, such as induction machines, TFM's have no diameter winding but a circumferential winding. Thus, the magnetic flux is transverse to the plane of rotation.

such TFM have several advantages. So is a decoupling of the magnetic and electrical circuit possible and also an omission of the winding heads, which do not contribute to the moment generation. In this way is a much finer pole pitch possible or can a smaller speed with big Moment can be achieved, which in turn can be omitted transmission.

The Disadvantages of such TFM's are a very elaborate mechanical construction, which also with correspondingly high production costs is connected and a high torque ripple. The torque ripple However, it can be countered by a suitable current control.

Of the The present invention is therefore based on the object, the production a transverse flux machine, in particular under production engineering Aspects, to simplify. In particular, a simplification the transverse flux machine can be achieved in the joining process and a smaller amount of sheets, which after punching as waste remain.

This is inventively a transverse flux machine according to claim 1 and a method for producing a transverse flux machine according to claim 12 reached. Advantageous embodiments and further developments are the subject of the dependent claims.

The Transverse flux machine according to the invention has an annular Stator on and a rotatably arranged relative to the stator Rotor and at least one circumferentially extending around the stator Kitchen sink.

According to the invention annular Stator in its circumferential direction composed of at least two ring-segment-shaped sections and these ring segment-shaped sections are in at least non-positive Connection with each other.

By the construction according to the invention is the joining together the individual ring segments or sections and the respective coil the transversal flux machine designed very simple. simultaneously the waste can be greatly reduced on stamped sheets, because in contrast to the prior art no circular elements but only circular segment-shaped or ring segment-shaped Sections are punched out. In other words, the stator segments become the TFM or their sheets split into subareas, these Subdivisions simply joined can be.

Preferably For example, the stator has a plurality of stator laminations attached to each other are arranged. It is possible to punch out individual stator plates during production and then add these together when assembling the stator.

Preferably the ring segment-shaped sections are mechanical connected with each other. It would be but also possible that the frictional over other elements, for example, a housing surrounding the sections manufactured becomes.

In order to there is a splitting of the circular segment of a TFM in at least two pieces, which joined together around a coil become. Preferably, the mechanical connection between the sections selected from a group of mechanical compounds which Clamp connections, press connections, Welds, Clamp connections, screw connections, combinations thereof and the like.

at a further preferred embodiment the transversal flux machine has a housing into which the ring segment-shaped sections are pressed are. By this pressing or shrinking into the housing is also achieved a mechanical stability between the individual ring segment-shaped sections. Preferably show the cuts Engagement elements, which with engagement elements of the respective adjacent sections cooperate, so as to effect an engagement of the sections with each other. Through these interlocking engagement elements, such as Recesses, a firmer mechanical connection between the individual sections reached.

Preferably, the sections each comprise a first engagement element and a second engagement element, wherein the first engagement element cooperates with a second engagement element of a first adjacent section and the second engagement element cooperates with a first engagement element of a second adjacent section. In this case, the sections preferably have a first engagement element at one end section and a second engagement element at the respective second or opposite end section ment. In this way, it is possible to produce all sections with a single process, such as a stamping process, and then join together. These two engagement elements correspond to each other or are complementary to each other.

In addition, in particular on the outer circumference of the sections, Recesses may be provided which facilitate the manufacturing process for the cuts. In addition, you can in the assembled state of the engine also cooling tubes in these recesses to be ordered. These cooling pipes are thus after the joining process between a housing and the joined together Sections. By this arrangement results - in particular under consideration of the joining process - a very favorable thermal coupling between the segments and the cooling tubes in the Stator, so that the power loss can be dissipated better and thus one higher Torque density and power density is possible.

Preferably the first engagement elements are projections and the second engagement elements are recesses, in which the mentioned projections intervention. These projections can have rounded or edged shapes.

Preferably is provided on the stator a plurality of teeth. Show these teeth preferably has a radially inwardly projecting projection. Besides Advantageously, the individual teeth recesses, in which the individual cuts can intervene.

advantageously, the number of teeth is the same the number of cuts or is at each section exactly one tooth arranged. If the number of cuts equals the number of teeth a TFM, it is especially easy to pre-set the segments To equip the connection process with a tooth and then from to put the respective sides on the coil.

Preferably are the individual teeth each mechanically connected to the individual sections, these mechanical connection done for example via recesses can, in which intervene the respective sections.

Also Is it possible, the mechanical connection between the sections and the teeth, for example by clamping, pressing or shrinking produce. The The present invention is further directed to a method of making a Transverse flux machine with a stator and a rotatable relative to this Stator arranged rotor directed.

at a further preferred embodiment the stator has a multiplicity of double segments or double sections, each of two sections put together. Two teeth are arranged on each of these double segments. these two teeth are preferably mutually arranged mutually. Here is this double segment in particular in one piece executed. These Double segments will follow added to the TFM.

Farther the present invention is also directed to a method of manufacture a stator for a Transverse flux machine directed. In each case, the stator from at least two ring segment-shaped sections composed, these ring segment-shaped sections immovable across from be arranged one another. Advantageously, the overall connection, d. H. the joining together over to the stator a shrinking in a housing. To For this purpose, the housing is preferably heated and in the heated state of the housing Stator with the coil wound thereon introduced into the housing.

at In another preferred method, the individual sections are each equipped with a tooth, whereby this equipping especially by clamping, pressing or shrinking done can.

Advantageous become the cuts with the teeth attached attached to a coil. Here are particularly advantageous the put on teeth alternately from different sides on the spool attached.

Further Advantages and embodiments emerge from the attached Drawings: showing:

1a a schematic representation of the sections of a stator according to the invention prior to assembly;

1b a perspective view of the schematic representation 1a ;

2a a schematic representation of the stator segments 1 , wherein the individual sections are already arranged on a coil;

2 B a perspective view for illustrating 2a ,

1a shows a schematic representation of six ring segment-shaped sections 2a - 2f before the joining process. The individual ring-segment-shaped sections each have a first engagement element 11 and a second engagement element 12 on. These two engagement elements are each formed complementary to each other, so that they can interlock. More specifically, for example, the first engagement element engages 11 of the ring segment-shaped section 2 B in the second engagement element 12 of the ring segment-shaped section 2a in order to produce a mechanically stable connection in this way.

At the same time, however, this type of engagement elements also permits a shrink-in process, since the individual sections can slide into one another in the circumferential direction. It should be noted that the distance between the individual sections 2a - 2f to one another substantially lower before the shrinking process, as in

1a shown. In addition, in reality, the individual sections are joined when the coil is inserted, so that the 2a and 2 B in that respect only serve to illustrate the manufacturing process.

Also results from 1a that the individual cuts 2a - 2f each having the same geometric shape. This allows the entire stator 2 from a variety of similar sections 2a - 2f be assembled, which simplifies the manufacturing process.

At the individual ring segment-shaped sections 2a - 2f are each teeth 14a - 14f arranged. In this case, these teeth each have projections 9 which extend in a direction perpendicular to the plane of the figure. These projections 9 fit in appropriately adjusted recesses 6 which are in the ring segment-shaped sections 2a - 2f are provided, a.

As in particular in 1b it can be seen standing thereby the projections 9 slightly above the corresponding recess 6 (which is hidden in the figures) out. In addition, the teeth each have recesses 15 on, in which the coil can be inserted. More precisely, the recess 15 between an inner wall 4 the individual cuts 2a - 2f and a second projection 13 the teeth formed. Also this second projection 13 extends into 1a essentially perpendicular to the figure plane. It is in 1a to recognize that the individual projections 13 each mutually protrude in opposite directions. The projections on the sections 2a . 2c and 2e are not visible, but protrude into the plane of the figure.

The reference number 7 refers to recesses in the sections, which serve to facilitate the manufacturing process for the sections. In addition, as mentioned in the introduction, cooling tubes can be inserted in these recesses in order to enable a more favorable dissipation of the power loss.

2a shows the sections of the stator 1a , where here the cuts already on the coil 8th are arranged. This coil 8th here, as in particular 2 seen, the same width, as the individual sections 2a - 2f of the stator 2 , However, this choice of the width of the coil is not mandatory. The coil may also have a smaller or higher width than the sections. Also it is possible to set the width coil to the width of the teeth 14a - 14f adapt. Particularly preferably, the width of the coil is equal to the width of the respective section 2a - 2f plus the width of the back of each tooth 14a - 14f (so-called window width). The individual sections have a circular segment-shaped inner circumference or a circular segment-shaped inner surface. Also the individual teeth 14a - 14f have circular segment-shaped inner surfaces 4 on. By a shrinkage process, the sections are joined together, so that the individual engagement elements 11 . 12 mesh. This leaves a small gap 16 between the inner circumference of the coil 8th and the outer circumference 13a the projections 13 , By joining the sections 2a - 2f with the previously inserted coil, the segments or sections are pressed more strongly against the outer circumference of the coil. This leads to an improvement of the thermal transition between the coil and the segment. In this way, we increase the dissipated power loss and thus increase the torque density or

power density reached the engine. Especially in interaction with cooling pipes or generally a liquid cooling can here's an increase the torque density or power density can be achieved.

All Features disclosed in the application documents are considered to be essential to the invention as long as they are individually or in combination with respect to State of the art are new.

2

stator

2a-2f

Ring segment-shaped sections

4

Inner wall of the sections 2a - 2f

6

Recess for teeth 14a - 14f

7

recess in the sections

8th

Kitchen sink

9

head Start the teeth

11

first engaging member

12

second engaging member

13

second projection of the teeth 14a - 14f

13a

Outer periphery of the projections 13

14a-14f

teeth

15

Recess for coil 8th

Claims (16)

Transverse flux machine ( 1 ) with an annular stator ( 2 ) and a rotatably arranged relative to the stator rotor and at least one circumferentially extending around the stator coil ( 8th ), characterized in that the annular stator ( 2 ) in its circumferential direction of at least two annular segment-shaped sections ( 2a . 2 B . 2c . 2e . 2f . 2g ) and these ring segment-shaped sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) are in at least non-positive connection with each other. Transverse flux machine according to claim 1, characterized in that on the stator ( 2 ) a variety of teeth ( 14a . 14a . 14c . 14d . 14e . 14f ) is provided. Transverse flux machine ( 1 ) according to at least one of the preceding claims, characterized in that the stator ( 2 ) a plurality of a plurality of stator laminations ( 5 ), which are arranged together. Transverse flux machine according to at least one of the preceding claims, characterized in that the ring segment-shaped sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) are mechanically interconnected. Transverse flux machine according to claim 4, characterized in that the mechanical connection between the sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) is selected from a group of mechanical connections including clamp joints, press joints, weld joints, clamp joints, screw joints, combinations thereof, and the like. Transverse flux machine according to at least one of the preceding claims, characterized in that the transversal flux machine has a housing into which the ring-segment-shaped sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) are pressed. Transverse flux machine according to at least one of the preceding claims, characterized in that the sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) have recesses on their outer circumference. Transverse flux machine according to at least one of the preceding claims, characterized in that the sections engagement elements ( 11 . 12 ) provided with engaging elements ( 11 . 12 ) of the respective adjacent sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) cooperate so as to engage the parts ( 2a . 2 B . 2c . 2d . 2e . 2f ) to effect each other. Transvesselalflussmaschine according to claim 8, characterized in that the sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) a first engagement element ( 11 ) and a second engagement element ( 12 ), wherein the first engagement element ( 11 ) with a second engagement element ( 12 ) of a first adjacent section ( 2a . 2 B . 2c . 2d . 2e . 2f ) and the second engagement element ( 12 ) with a first engagement element ( 11 ) of a second adjacent section ( 2a . 2 B . 2c . 2d . 2e . 2f ) cooperates. Transverse flux machine according to claim 8, characterized in that the first engagement elements ( 11 ) Projections ( 11 ) and the second engagement elements ( 12 ) Recesses ( 12 ) are. Transversalflussmaschine according to at least one of the preceding claims, characterized in that the stator has a plurality of double segments, each consisting of two sections ( 2a . 2 B . 2c . 2d . 2e . 2f ), on each of which two teeth ( 14a . 14b . 14c . 14d . 14e . 14f ) are arranged, these two teeth are preferably mutually arranged. Transverse flux machine according to at least one of the preceding claims, characterized in that the number of teeth ( 14a . 14b . 14c . 14d . 14e . 14f ) equal to the number of cuts ( 2a . 2 B . 2c . 2d . 2e . 2f ). Transversal field machine according to at least one of the preceding claims, characterized in that the individual teeth ( 14a . 14b . 14c . 14d . 14d . 14f ) with the individual sections ( 2a . 2 B . 2c . 2d . 2e . 2f ) are each mechanically connected. Method for producing a transverse flux machine with a stator ( 2 ) and a rotatable relative to this stator ( 2 ) arranged rotor, characterized in that the stator ( 2 ) of at least two ring segment-shaped sections ( 2a . 2 B . 2c . 2d . 2e . 2f ), wherein these ring-segment-shaped sections are arranged immovably with respect to each other. A method according to claim 14, characterized in that the sections each with a tooth ( 14a . 14b . 14c . 14d . 14e . 14f ). Method according to claim 14, characterized in that that the cuts with the teeth attached be attached to a coil.