DE4217357A1 - Linear motor e.g. for machine tool or warp loom - has stator of toroidal coils alternating with annular laminations and rotor of conductor rings alternating with laminations - Google Patents

Abstract

The linear motor with a cylindrical air gap, ring-shaped coils in the stator grooves and conductor rings in the rotor grooves has the stator core made from a stack of annular disks, alternating with the coils, retained by a cylindrical yoke. The rotor is also made from a stack of alternating disks and conductor rings, arranged around a cylindrical inner yoke. The stator and rotor disks are formed from laminations, the stator ones having a radial slit. The stator yoke may comprise several sets of laminations arranged longitudinally in discrete packets around the periphery of the stator core. The laminations are all made from soft magnetic iron or steel. ADVANTAGE - Ease of manufacture and assembly.

Description

The invention relates to a linear motor with zy Lindrischen air gap, ring-shaped coils in the grooves of the stand and ladder rings in the grooves of the runner.

Such a solenoid motor has a single comb or double-comb linear motor has the advantage that no winding heads are needed and therefore the coils and conductors ring-shaped and inserted in ring grooves can. On the other hand, there are disadvantages in manufacturing technology Terms, both in terms of manufacture of stands and runners as well as in terms of insertion gens the coils or conductor rings in the grooves. thats why Such an engine has not yet been put into practice has been conducted.

The invention has for its object a linear specify the engine of the type described at the beginning can be made much easier.  

This object is achieved in that the stand made of washers in a stratification alternate with the coils, and one on the outside Stator yoke and / or the rotor from ring disks, the alternate in one layer with the conductor rings, and an inner runner yoke.

Only the washers are required during production with the coils or conductor rings to a stack to be tet, which is then turned on by the outside or inside put Joch to the stand or runner in a simple way is completed. The air gap at the joint between the washers and the yoke plays in the magnetic circuit in the Only a subordinate to the working air gap Role and can therefore be accepted. Furthermore it can be kept small by appropriate processing.

This procedure does not only eliminate the difficult Insert the coils and conductor rings in the slots, but also punching grooves. In particular, there are none complicated and elaborate groove cuts as with comb motors. The tooth width, slot pitch or pole pitch leaves simply by using rings of different thicknesses discs and change coils or conductor rings. All parts are simple and can be mass-produced inexpensively be put.

It is favorable that the washers each consist of one There are stacks of annular sheets. This leads to a simple design with low groove spread. Eddy currents play no essential role in the axial direction and in the circumferential direction only at higher frequencies at many applications, for example in the axial adjustment of machine elements in machine tools, Textile machines u. Like. are not necessary at all,  because with 10 Hz a speed of 1 to 2 m / s can be achieved.

In the event that eddy currents are avoided in the circumferential direction the ring disks or sheets can be slotted one or more times.

It is also expedient that the stator yoke and / or that Läuferjoch at least one is approximately in the axial direction separating joint. This parting line just prevents if eddy currents running in the circumferential direction.

This parting line is achieved especially when the stand derjoch and / or the Läuferjoch ver over the circumference shared sheet metal packages is formed from in Achsrich sheet. In addition, easily assemble the yoke from these sheets.

An alternative is that the stator yoke and / or the runner yoke made of solid, soft magnetic iron or steel. This leads to a simple stabi len construction, in which the solid yokes the support structure take over for the stand or the runner. she is particularly applicable at low frequencies, esp especially when the penetration depth of the magnetic Field is greater than the yoke height.

It is particularly favorable that the stator yoke and / or the Läuferjoch has a solid tube. Because of the uniform wall thickness, which is also relatively small can be kept, there is a small carrier unit moment in the direction of movement.

With the stand there is a possibility that the stand yoke has a double jacket and the jacket space is connected to a coolant supply and discharge line. Similarly, the runner can the interior of the tubular rotor yoke with a cooling  to connect medium supply and discharge line, so that one the linear motor with a liquid or gaseous cooling can cool medium. Hereby the strength and lei density increases and thereby ver the motor size diminishes. At very low temperatures, the electri resistance of the conductors can be reduced.

Furthermore, it is advantageous that the conductor rings of the Are inclined. The levels of the washers are therefore opposite to the cross-sectional plane of the rotor inclined. The slope of the conductor rings leads to a uniform drive torque during axial movement.

In a preferred embodiment, it is ensured that that coils are wound so that two are next to each other other arranged windings result in the inside over a Winding are interconnected and the two outside Have connection ends. This special type of wrap ensures to ensure that the washers and the coils fit tightly together can be stratified because the connection ends are outside and therefore no connecting wire to Inside the coil must be performed.

It is also favorable that the coils are part of the inner circumference reject by guide rings made of soft magnetic material are covered. These are due to the ring washers of the stand derjochs or are formed in one piece with them. This will result in a better distribution of the magnetic flux achieved in the air gap analogously to the use of slot slot zen with rotating asynchronous motors. This leads to a Improvement of the Carter factor and a higher engine power.

The invention is illustrated below in the drawing illustrated preferred embodiments he closer purifies. Show it:  

Fig. 1 shows a longitudinal section through a linear motor,

Fig. 2 shows a section along the line AA in Fig. 1,

Fig. 3 is a schematic representation of the essential components of the linear motor,

Fig. 4 shows a modified embodiment in the presen- tation of FIGS . 3 and

Fig. 5 shows another embodiment of a coil.

The linear motor of FIGS. 1 to 3 has a stator 1 and a rotor 2 , which form a cylindrical air gap 3 between them. The rotor 2 is provided at both ends with hollow pins 4 and 5 , which 6 and 7 are preferably guided in bearings 8 and 9 of the stator by means of Wälzla. Via a screw thread 10 on the pin 5 , the element to be driven, for example the support of a machine tool or the laying rail of a warp knitting machine, can be connected. The stator 1 has a stack of layered ring disks 11 , between each of which there is an annular coil 12 . This stack is covered on the outside by a yoke 13 , which is formed here from a plurality of axially parallel strips 14 and 14 a. Axial grooves 15 remain between the strips. The stator yoke strips 14 are formed in FIGS . 1 and 2 by laminated cores, the laminations of which are arranged next to one another in the circumferential direction and extend in the axial direction. This gives a good magnetic table conclusion without 13 eddy currents to be feared at the stator yoke. In Fig. 3 the strips are made of solid soft iron or steel.

In the present exemplary embodiment, 33 coils 12 , each with 66 turns, are provided. The stator winding is designed as a three-phase winding. The stand 1 can also be provided with a rib body 16 for better heat dissipation, as is indicated in FIG. 2.

The rotor 2 also has a stack which is composed of annular disks 17 which alternate with conductor rings 18 . The conductor rings 18 are preferably made of copper and the washers 17 from packages of ring-shaped sheets. A solid tube made of soft iron serves as the rotor yoke 19 , the hollow pin 4 being screwed to the ends of the hollow pin 5 and the hollow pin 5 being welded on. As a result of the inner cavities 20 , 21 and 22 , a runner with low mass and correspondingly low inertia results.

A coolant supply line 23 and a coolant discharge line 24 are schematically illustrated, which allow internal cooling of the rotor by means of a gaseous or liquid coolant.

The assembly of this linear motor is very simple. It only needs the parts of the stand 1 axially joined to each other and the outside with the yoke strip 14 to be hen. In the same way, the parts of the rotor 2 are axially joined together and provided with the yoke 19 on the inside. Then the rotor is pushed into the stand, which is still open on one side, and finally the bearing bush 8 is added.

In the embodiment according to FIG. 4, a stand 101 is provided with ring disks 111 , which consist of slotted ring-shaped sheets, so that there is a parting line 115 in the circumferential direction. The stator yoke 113 consists in this case of a solid tube 114 made of soft iron or steel.

The rotor 2 also has annular discs 117 , which receive a parting line 115 a by slotting. The Läu ferjoch 119 is again designed as a tube, but has two axial joints 115 b to suppress the eddy currents.

The solid tube 114 is supplemented by a further cylinder 125 to form a double jacket. The jacket space 126 is provided with a schematically drawn coolant supply line 123 and a schematically illustrated coolant discharge line 124 , so that the stator 101 can also be cooled by a gaseous or liquid cooling medium.

While an annular coil 12 with round wires is shown in FIG. 1, FIG. 5 illustrates a coil 212 which is wound from flat conductors 227 . There are two coils 228 and 229 arranged side by side, which are connected to one another on the inside by a winding 230 . This makes it possible to provide both connection ends 231 and 232 on the outside of the coil, so that the connection wires do not hinder the assembly of the stack.

The inner circumference 233 of the coil 212 is partially covered by two guide rings 234 and 235 made of soft magnetic iron or steel, so that a gap 236 remains between them, the axial width of which is considerably smaller than the coil width. After assembly of the stack, the guide rings rest on the ring disks 11 with their end faces facing away from each other, for this purpose they have a radial extension which is equal to the sum of the radial extensions of the guide ring and coil. As a result, the magnetic conditions in the air gap are significantly improved.

There can be many deviations from the illustrated exemplary embodiments without departing from the basic idea of the invention. For example, the annular disks 11 can be formed in one piece with the guide rings 234 or 235 .

If you arrange the washers 17 in Fig. 3 such that their end faces have an inclined to the cross-sectional plane of Läu fers end face, you can use diagonally posed conductor rings that cause an equalization of the driving force in the axial direction.

Claims (12)

1. Linear motor with a cylindrical air gap, annular coils in the grooves of the stator and conductor rings in the grooves of the rotor, characterized in that the stator ( 1 ; 101 ) from annular disks ( 11 ; 111 ), which are in a stratification with the coils ( 12 ; 212 ) alternate, and an externally adjacent stator yoke ( 13 ; 113 ) and / or the rotor ( 2 ) from annular disks ( 17 ; 117 ), which alternate in a stratification with the conductor rings ( 18 ), and an internally adjacent rotor yoke ( 19 ; 119 ) is composed. 2. Linear motor according to claim 1, characterized in that the annular discs ( 11 , 17 ; 111 , 117 ) each consist of a stack of annular sheets. 3. Linear motor according to claim 1 or 2, characterized in that the annular discs ( 111 ) or sheets are slotted one or more times. 4. Linear motor according to one of claims 1 to 3, characterized in that the stator yoke ( 13 ) and / or the rotor yoke ( 119 ) has at least one approximately in the axial direction joint ( 15 ; 115 b). 5. Linear motor according to claim 4, characterized in that the stator yoke ( 13 ) and / or the rotor yoke is formed from strips ( 14 ) distributed over the circumference in the form of laminated cores which consist of sheets running in the axial direction. 6. Linear motor according to one of claims 1 to 4, characterized in that the stator yoke ( 13 ; 113 ) and / or the rotor yoke ( 19 ; 119 ) consists of solid soft magnetic iron or steel's. 7. Linear motor according to one of claims 1 to 6, characterized in that the stator yoke ( 113 ) and / or the rotor yoke ( 19 ) has a solid tube ( 114 ; 19 ). 8. Linear motor according to claim 7, characterized in that the stator yoke ( 113 ) has a double jacket ( 114 , 125 ) and the jacket space ( 126 ) with a coolant supply and discharge line ( 123 , 124 ) is connected. 9. Linear motor according to claim 7, characterized in that the interior ( 20 ) of the tubular rotor yoke ( 19 ) with a coolant supply and discharge line ( 23 , 24 ) is connected. 10. Linear motor according to one of claims 1 to 9, characterized characterized in that the conductor rings of the rotor obliquely are posed. 11. Linear motor according to one of claims 1 to 10, characterized in that coils ( 212 ) are wound such that there are two coils ( 228 , 229 ) arranged next to one another, which are connected to one another internally via a turn ( 230 ) and externally have the two connection ends ( 231 , 232 ). 12. Linear motor according to one of claims 1 to 11, characterized in that the coils ( 212 ) on the inner circumference ( 233 ) are partially covered by guide rings ( 234 , 235 ) made of soft magnetic material.