DE102009011410A1 - Coil i.e. drive coil, for magnetizing permanent magnet, has slots and/or recesses provided in single-piece coil body, and conductor sections forming single piece conductor, where cross-sections of conductor sections are square-shaped - Google Patents

Abstract

The coil (11) has a single-piece coil body (12) and a coil base body, where the coil is formed right-angled and made of an electrically conductive material e.g. silver, aluminum, copper, or alloy of silver, aluminum, or copper. Slots and/or recesses are provided in the coil body. Conductor sections form a single piece conductor, where the cross-sections of the conductor sections are square-shaped. The single-piece coil body has regions with different pole adjustment.

Description

The The invention relates to a coil, in particular for magnetizing of permanent magnets, with several conductor sections.

A Such coil can be approximately in a magnetizing coil for generating the Magnetic field serve and is constructed, for example, of individual, U-shaped bent conductors. The conductors are individually to a soft magnetic core placed or inserted into holes in the core. The free ends of the ladder are bent over and electrically connected to each other, for example by soldering or Welding. The whole device is used to fix the conductor inside the housing potted or overmoulded with a plastic.

At the Connecting the individual conductors can be done by bending over to mechanical Tensions between the conductors come, causing individual conductors can slip out of their position.

moreover can through an incomplete bending process or by elastic relaxation, the two legs of the U-shaped ladder not exactly parallel, that is crooked, or curved in itself be. The coil is usually inside the case of a Magnetizing coil with plastic encapsulated or with a potting compound cast around. When casting or Can overmold single ladder through the liquid Plastic are displaced from their position.

Therefore It may be that individual conductors in the finished magnetizing coil stand crooked and / or have a wrong position, that is, the geometric poles of the coil are uneven and / or unbalanced.

Farther The core of the coil is usually stacked from individual sheets. The individual sheets can production-related have a preferred magnetic direction, which can not be compensated by twisted stacking. Thereby can Also, the magnetic poles are pronounced different degrees. In the worst case are individual magnetic poles not congruent with their geometric Poland.

at a magnetizing coil with a coil according to the prior art occur all of these effects mostly in any and unpredictable Combination on. Since the individual work steps are difficult to automate are, the coil is largely crafted, which can increase the defectiveness even more.

One Permanent magnet that has been magnetized with such a coil, therefore has unbalanced and / or unequal poles. In the Use of such a single-ended magnet, for example in an electric motor, this is done by the rotor, a reduced efficiency and increased noise, in particular through higher harmonic vibrations, noticeable. Such an engine can thereby, for example outside the specification and thus be reject.

in the The prior art, it is therefore also known, the coil in one piece from a piece of wire to bend so that the individual conductor loops of the coil do not need to be connected separately. This will reduce the risk that the location of the ladder when bending and connecting is changed, still can but individual ladder by incomplete bending or by relaxation not be parallel or bent and / or individual Head of the one-piece coil when casting or molding in their Location changed become.

task The invention is therefore to provide a coil in which the individual Poles of the coil are geometrically and magnetically equal and symmetrical.

These Task is inventively characterized solved, that the coil is a one-piece bobbins has and produced by removal of material from a massive coil body is.

The coil according to the invention has a massive bobbin, by which the basic shape of the coil is given. recesses, which are worked by material removal in the bobbin limit while individual conductor sections. That is, the coil is in one piece trained and is composed neither of individual ladders still bent out of a ladder. It also contains no soft magnetic Core.

The Accuracy of the coil is therefore only dependent on the accuracy of the material removal process. Within this accuracy is the geometric and magnetic poles the coil congruent, symmetrical and equal.

In addition is the coil completely mechanically and therefore much cheaper and more accurate to produce.

There the coil is absolutely symmetrical, is also a more accurate alignment the coil to a blank magnet possible. A magnet can therefore symmetric in very close tolerances and magnetized with the same poles become.

The coil can be shaped almost arbitrarily, the shape only by the Materialab contract procedure is limited. In one embodiment of the invention, the coil is formed by a plurality of slots and / or recesses in the bobbin.

permanent-magnet Electric motors often have two separate ring magnets with different number of poles on: a drive magnet and a magnet with much larger number of poles for position detection and commutation.

to Production of these magnets are two different in the prior art Magnetizing required. In a development of the invention The coil has several areas with different number of poles on. This makes it possible a permanent magnet with several areas of different Poling magnet number, so for the application described above only one magnet and only one magnetizing coil are necessary. The Making the magnets is much faster and cheaper.

In another version According to the invention, the coil has several regions with different ones Pole alignment on. This makes it possible, for example, a Partially magnetize radially and axially magnets.

For the power line The conductor sections of the coil are manufactured without interruption. The individual conductor sections thus form a one-piece conductor which, in the simplest case, resembles a meander. In addition, the meandering ladder formation increases the mechanical stability the coil.

This can be achieved in particular by a right-angled connection between the individual axially aligned conductor sections, what the stiffness compared to U-shaped bent Ladders significantly improved.

It It is understood that the invention is not limited to a simple meander shape is limited. A combination of several bodies connected together are close not the invention.

The Coil is, for example, hollow cylindrical and the recesses run mostly radially to this cylinder, so that the cross section of the conductor sections for example, is quadrangular. By suitable post processing is the cross section of the ladder also changeable. The shape of the cross section the conductor sections is determined by the desired form of magnetization given. The surfaces the conductor sections opposite the magnetic blank, are crucial for the magnetization, since the currents over the Surfaces flow. The Take shape of the surfaces facing away from the magnetic blank no influence on the shape of the magnetization. They influence only the resistance of the conductor. But the shape of the Magnet blank facing surfaces the conductor sections, or the change of the air gap between the surfaces and the magnetic blank correlates directly with the magnetic field, which imprinted on the magnet blank becomes.

So can the shape of the surface straight, convex, concave, wavy, jagged and the like more be, depending on the desired Form of magnetization. Also, it is conceivable the surfaces of To make ladder sections different.

In a particularly simple embodiment of Invention, the recesses are axial, oblique, curved slots or a combination of it. In particular, for example, in the bobbins alternately distributed at the two coil ends on the circumference several, arranged axial recesses that limit conductor sections. This results in a hollow cylindrical coil with straight, parallel Conductor sections for radially magnetizing ring magnets.

In order to needed for magnetizing high electrical currents can be achieved it is advantageous if the coil is made of an electrically highly conductive material, such as silver, aluminum, copper, or alloys made of it.

The coil according to the invention may preferably be used in a magnetizing coil, such as it is used for magnetizing permanent magnets use. To the coil is in a housing arranged and together with an insulation for the conductors in a plastic embedded. In order to be able to dissipate the resulting heat well, can additionally a cooling device to be embedded in the plastic.

apart Of these, the coil of the invention but also for other applications are used, for example as a drive coil for one Electric motor. The skilled person understands that the above-mentioned form the surfaces the conductor sections corresponds to the generated field of the drive coil. The versatility of the design results for a drive coil therefore as well and is limited only by the manufacturing process.

The coil according to the invention is preferably produced in a method in which the coil is manufactured in one piece from a massive coil base body by material removal. That is, the conductor portions are machined out of the massive coil base body and are not made by forming or the like processes. The material removal from the spu lengrundkörper can be done completely by machine, which is why very low tolerances are possible.

Of the Material removal can be achieved by various methods such as Drilling, cutting, milling and / or eroding done. Especially by wire erosion to make particularly narrow recesses and slots. One Another advantage of erosion is that the coil body during the Manufacturing process exposed to low mechanical stress and therefore keeps its shape at all times.

The Production of the coil is not limited to the mentioned methods. Much more are any available to the skilled person Techniques conceivable. For example, the coil base body is also through a copper casting, or about produced by an aluminum die-cast and by the mentioned Techniques of material removal reworkable to the desired Form of the conductor sections to arrive.

The geometric poles of the coil can be matched with the corresponding Accuracy of the chosen Produce manufacturing process. Therefore, the symmetry of the geometric Pole determined only by the tolerances of the manufacturing process.

The Invention is described below with reference to various embodiments closer to the drawings explained.

It shows:

1 an oblique view of a magnetizing coil according to the invention,

2 a longitudinal sectional exploded view of a magnetizing coil according to the invention,

3 a longitudinal section through the magnetizing coil of 1 .

4 a side view of a hollow cylindrical coil with axial, parallel conductor sections, for

5 an oblique view of the coil of 4 .

6 an oblique view of a hollow cylindrical coil with oblique, parallel conductor sections,

7 an oblique view of a hollow cylindrical coil with axial, parallel conductor sections and a ring conductor,

8th a schematic representation of the peripheral surface of a coil with two areas with different number of poles,

9 a schematic representation of the peripheral surface of a coil with zig-zag-shaped recesses,

10 a schematic representation of the peripheral surface of a coil with sinusoidal recesses,

11 a schematic representation of a disc-shaped coil as a drive coil for a pancake,

12 a perspective view of a coil main body and

13 a side view of the coil body of the 12

1 shows one as a whole 1 designated magnetizing coil according to the invention.

The magnetizing coil 1 has a cylindrical housing 2 , with an end face 3 , On the face 3 is a plastic magnetic pad 4 , For example, made of PEEK, on which a magnetic blank to be magnetized (not shown) can be placed. Coaxial to this support surface 3 is a cylindrical coil extension 5 arranged on which the ring magnet to be magnetized is placed.

To protect against mechanical damage is the coil extension 5 through a protective sleeve 6 completely covered. The protective sleeve 6 is made of a non-magnetic material so that the magnetizing field is influenced as little as possible.

The housing 2 is made of a material, such as an aluminum alloy, so that the heat generated during magnetization can be quickly absorbed and dissipated. In addition, the magnetizing coil 1 a cooling device, whose connections 7 on the side of the housing 2 are arranged.

At the bottom of the magnetizing coil 1 are the power supply 8th and the connection 9 an internal temperature sensor 10 ( 2 ) arranged.

The exact structure of the magnetizing coil 1 is based on the 2 and 3 explained in more detail.

Main component of the magnetizing coil 1 is the coil 11 for generating a Magnetisierfeldes. The sink 11 is hollow cylindrical and has a solid bobbin 12 on, in that alternately distributed at the two coil ends on the circumference several recesses 13 are arranged, which are the conductor sections 14 limit.

Two adjacent conductor sections 15 are through a continuous recess 37 completely disconnected and used to connect the power supply 8th ,

On the outer circumference of the coil 11 covers a protective sleeve 6 from the case 2 protruding part 5 the coil 11 and protects the coil extension 5 thereby against mechanical damage. In the example has the protective sleeve 6 a wall thickness of about 95 microns.

Between coil 11 and protective sleeve 6 is on the outer circumference of the coil 11 a Kapton foil 16 arranged for isolation by a short circuit of the individual conductor sections 14 through the protective sleeve 6 to prevent.

To a sparkover between adjacent conductor sections 14 are also in the recesses 13 between the conductor sections 14 Kapton films 17 used.

Inside the coil 11 is a cooling shaft 18 arranged in the coil 11 derived heat dissipates. Between cooling shaft 18 and the inner circumference of the coil 11 is also a Kapton foil as insulation 19 arranged. In order to allow the best possible heat transfer, there is a cooling wave 18 , inner Kapton foil 19 and coil 11 a direct contact. The cooling shaft 18 is made of a good heat conducting material, such as aluminum, and has a central through hole 20 for receiving a temperature sensor 10 , The temperature sensor 10 sits inside the cooling shaft 18 in the area of the upper third of the coil 11 ,

At the top of the coil 11 is a cylindrical upper centering collar 21 with one opposite the bobbin 12 arranged reduced diameter. At both ends 22 the coil 11 In addition, there are several centering holes 23 arranged in the centering pins 24 are used. On the upper centering collar 21 is an upper centering crown 25 made of plastic, with the centering pins 24 in corresponding openings in the centering crown 25 intervention. The centering crown 25 is through a central upper clamping screw 26 at the cooling shaft 18 attached. The upper clamping screw 26 is through an opening 29 in the protective sleeve 6 accessible.

At the other end of the coil 11 is a lower centering crown 27 at a lower centering collar 28 arranged and by several centering pins 24 fixed in the position. The lower centering crown 27 is also made of plastic and has a central passage opening for performing a centering cone 30 made of aluminum, by a lower clamping screw 31 at the cooling shaft 18 is attached. The lower clamping screw 31 also has a central passage opening through which the temperature sensor 10 in the cooling shaft 18 can be inserted.

Through the two centering crowns 25 and 27 is the location of the coil 11 in relation to the housing 2 established. In addition, the location of the coil 11 through the upper clamping screw 26 visible from the outside, whereby an accurate coaxial alignment of the magnetic blanks is facilitated.

The sink 11 forms with the remaining components described above a functional unit, which as a whole in the housing 2 is used. As a holder is a sleeve 33 on the outer circumference of the coil 11 is pushed on and on the inner circumference of the housing 2 is applied.

At the housing 2 are two opposite, radial connections 7 arranged for a cooling medium. The cooling medium is in a circumferential groove 34 on the sleeve 33 guided. Because the sleeve 33 in contact with the coil 11 is, thus a heat dissipation via the cooling medium is possible. The groove 34 inside the sleeve 33 is opposite to the rest of the housing 2 through two O-rings 35 sealed, so no cooling medium in the housing 2 arrives.

In addition, there is a contact between the centering cone 30 and the housing 2 , through which heat from the coil inside over the cooling shaft 18 can be derived by the cooling medium.

For electrically contacting the coil 11 are at the bottom of the case 2 two contact pins 8th led to the outside, as well as the connection line 9 for the temperature sensor 10 ,

As in 3 It can be seen, are the coil 11 and all parts inside the case 2 in a plastic 36 embedded. This will cause the magnetizing coil 1 fixed as a unit. The plastic can be injected or poured or a casting resin can be used.

In the 4 and 5 is the coil 11 shown closer. The sink 11 has a massive, hollow cylindrical bobbin 12 on. The individual conductor sections 14 the coil 11 are by axial recesses 13 bounded and formed alternately at both ends of the coil 11 distributed around the circumference.

The slot 37 is carried out continuously, so that two adjacent conductor sections 15 be completely separated. These two conductor sections 15 serve as contact points for the power supply of the coil 11 , For connecting the supply lines 8th are at the two contact conductor sections 15 drilling 38 arranged, can be used in the cable. The supply lines 8th can, with suitable contact means, for example soldering, screwing, jamming or the like, more with the contact conductor sections 15 get connected.

From the contact conductor sections 15 starting from the coil 11 formed at a right angle meandering. The individual conductor sections 14 have due to the straight, radial slots 13 a square profile that corresponds to a ring segment.

At both ends has the coil 11 cylindrical centering collars 21 . 28 , At the front ends are centering openings 23 for inserting the centering pins 24 arranged.

This coil is in a magnetizing coil 1 suitable for magnetizing ring magnets on the inner circumference. To create other magnet shapes or pole patterns is another coil 11 necessary. The structure of the magnetizing coil 1 but remains essentially the same.

The 6 shows a further coil according to the invention 11 , which is also hollow cylindrical. Unlike the coil of 5 are the slots 43 but not arranged in the axial direction, but obliquely to the longitudinal axis 44 of the bobbin 12 , The slots 43 however, they are still straight, leaving the conductor sections 14 are aligned in parallel.

Such a coil 11 generates a magnetization in a magnet, which can reduce the cogging torque in an electric motor, but which also causes a force component in the axial direction.

The sink 11 of the 7 essentially corresponds to the 5 , In addition, the coil points 11 starting from the two contact conductor sections 15 a ring conductor 45 on, once around the bobbin 12 leads around. The sink 11 thus has a first area 46 with radial pole alignment and a second area 47 with axial pole alignment. Thus, a magnet having a radial and an axial range can be magnetized.

The 8th shows in a planar representation schematically the unrolled peripheral surface of a coil according to the invention 11 with two axially superimposed areas with the same Polausrichtung but different number of poles. This can be used, for example, to magnetize a drive magnet for an electric motor, which has an area at one axial end 52 having substantially larger number of poles in which, for example, speed or position sensors can be arranged.

The 9 schematically shows a coil circumferential surface of a coil 11 with zig-zag shaped conductor sections 48 passing through a zig-zag arrangement of slots 49 arise. As well as the coil 11 in 6 this generates a magnetization in a magnet, which can reduce the cogging torque in an electric motor, but without a force component in the axial direction. This embodiment is particularly advantageous since no additional effort has to be made to produce such a coil according to the invention. In comparison, with conventional manufacturing methods of magnetizing coils, a zigzag magnetization can not be easily generated; Although the hammerheads of a prior art magnetizing coil could be zig-zagged, the winding wires would directly connect the end faces of the hammerheads and would not deform into the zigzag.

Finally is it possible to form the slots as desired, depending on the desired magnetization.

The 10 schematically shows a peripheral surface of a coil 11 with sinusoidal slots 50 , This shows all the more that the shape of the slots is freely selectable.

In addition, there are many more forms of the coil 11 conceivable. For example, to magnetize a ring magnet on the outer circumference, the inner diameter of the coil may also be much larger. The coil may also be non-cylindrical, for example to magnetize bar magnets.

In addition to use in a Magnetisierspule, a coil according to the invention 11 also be used as a drive coil for an electric motor. In 11 is schematically such a drive coil 11 for a pancake shown. The sink 11 has two completely separate conductors 51 on, which are interleaved and each form a separate winding of the drive coil. Also this drive coil 11 is from a massive coil body 39 produced by material removal.

in the Below is a possible Production method described.

12 and 13 show a coil body 39 from which the coil 11 will be produced. The coil main body 39 is essentially a solid, in this example cylindrical rotary part made of copper, on the later outer dimensions of the coil 11 is turned. At the bottom remains a disk-shaped widening 40 standing to hold the coil body 39 during processing. On the cylinder itself are two circumferential grooves 41 introduced later the upper one 21 and lower 28 Form centering collar. The hollow cylindrical bobbin 12 is through a coaxial through hole 42 through the coil main body 39 produced.

As start and end points for the slots 13 are distributed over the circumference several holes 32 appropriate. Starting from these holes 32 be the slots 13 performed by, for example, wire erosion in the axial direction. In this case, the wire in the radial direction completely through the coil body 39 be guided so that two opposite slots 13 can be produced simultaneously.

By doing that, above and below the start and end points 32 the coil main body 39 over the entire circumference remains, can the coil body 39 be securely and firmly fixed during processing. When wire erosion is the coil 11 in itself is not exposed to mechanical stress.

The already worked out ladder sections 14 are not touched during further processing and therefore can not be bent. As a result, overall a very accurate production with tight tolerances is possible.

After all the slots 13 The coil can be machined 11 in the area of the two grooves 41 from the coil main body 39 be separated. To get a possible deformation of the coil 11 can prevent a core (not shown) in the center hole during the separation 43 be introduced and / or shed

The finished coil 11 can now with Kaptonisolation 16 . 17 . 19 equipped with the centering crowns 25 . 27 and the other components are provided. If the bobbin has been cast prior to separation, Kapton insulation can be dispensed with. The unit already described above is in a last step within the housing 2 embedded in a plastic.

1

magnetizing

2

casing

3

face

4

plastic magnet application

5

Coil extension

6

protective sleeve

7

Cooling medium connection

8th

power supply

9

connection temperature sensor

10

temperature sensor

11

Kitchen sink

12

bobbins

13

Recesses / slots

14

conductor section

15

Contact conductor section

16

Kapton outer periphery

17

Kapton slots

18

cool wave

19

Kapton inner circumference

20

Through hole cooling shaft

21

upper spigot

22

front end (above)

23

centering

24

Pins

25

upper Zentrierkrone

26

upper clamping screw

27

lower Zentrierkrone

28

lower spigot

29

Opening protective sleeve

30

centering cone

31

lower clamping screw

32

drilling (Start-end point)

33

shell

34

groove (Sleeve)

35

O-ring

36

plastic

37

through Recess / slot

38

drilling Contact conductor section

39

Coil former

40

widening (Disc)

41

groove (Cylinder)

42

Through Hole (Cylinder)

43

slots (aslant)

44

longitudinal axis Kitchen sink

45

ring conductor

46

first Area (radial)

47

second Range (axial)

48

conductor section (zigzag)

49

slots (zigzag)

50

slots (Sinusoidal)

51

ladder (Pancake)

52

Area with larger number of poles

Claims (21)

Coil, in particular for magnetizing permanent magnets, with a plurality of conductor sections ( 14 . 15 . 48 . 51 ), characterized in that the coil ( 11 ) a one-piece bobbin ( 12 ) and by removal of material from a massive coil base body ( 39 ) is made. Coil according to claim 1, characterized in that the coil ( 11 ) through several slots ( 13 ) and / or recesses in the bobbin ( 12 ) is formed. Coil according to claim 1 or 2, wherein the conductor sections ( 14 . 15 . 48 . 51 ) Have surfaces with at least one structured surface shape. Coil according to claim 3, characterized in that the surface shapes straight, convex, concave, wavy or jagged. Coil according to one of claims 1 to 4, characterized in that the coil ( 12 ) has several areas with different number of poles. Coil according to one of claims 1 to 5, characterized in that the coil ( 12 ) has multiple regions with different pole orientation. Coil according to one of claims 1 to 6, characterized in that the conductor sections ( 14 . 15 . 48 . 51 ) form a one-piece conductor, which runs meandering. Coil according to one of claims 1 to 7, characterized in that the coil ( 11 ) is formed at right angles meandering. Coil according to one of Claims 1 to 8, characterized in that the cross-section of the conductors ( 14 ) is quadrangular. Coil according to one of claims 1 to 9, characterized in that the recesses ( 13 ) are narrower than the individual conductors ( 14 ). Coil according to one of claims 1 to 10, characterized in that the recesses axial ( 13 ) or oblique ( 43 ) Slots are. Coil according to one of claims 1 to 11, characterized in that in the bobbin alternately at the two coil ends distributed on the circumference a plurality of straight recesses ( 13 ), the conductors ( 14 ) limit. Coil according to one of claims 1 to 12, characterized in that the coil ( 11 ) is made of an electrically conductive material, such as silver, aluminum, copper, or an alloy thereof. Magnetizing coil for magnetizing a permanent magnet, comprising a housing ( 2 ) and a coil arranged therein ( 11 ) according to one of claims 1 to 11. Method for producing a coil according to one of Claims 1 to 13, characterized in that the coil ( 11 ) by material removal in one piece from a massive coil body ( 39 ) will be produced. A method according to claim 15, characterized in that the coil base body ( 39 ) is produced by a casting and is reworked by material removal. Method according to claim 16, characterized in that that the casting by a copper casting or an aluminum die-casting he follows. Method according to claim 15 or 16, characterized that the material removal by drilling, cutting, milling and / or Eroding takes place. Drive coil with at least two separate coil windings, characterized in that each winding is a coil after one the claims 1 to 13. Drive coil according to claim 19, characterized that the coils are nested inside each other. Drive coil according to claim 19 or 20, characterized characterized in that the coils are made of a solid coil body are.