CN203984218U - Linear electric motors, disk rotary motor and motor platform - Google Patents

Abstract

The utility model discloses a kind of linear electric motors, disk rotary motor and motor platform (X-Y-Theta platform).These linear electric motors are U-shaped hollow linear electric motors preferably, and its magnet array comprises multiple magnet units, and each magnet unit comprises two or more magnet.The coil of this disk rotary motor and magnet quantity are than between 0.8 to 1.3.This motor platform adopts above-mentioned linear electric motors as directions X electric machine assembly, adopts the U-shaped hollow linear electric motors of decoupling zero as Y-direction electric machine assembly, adopts above-mentioned electric rotating machine as Theta electric rotating machine.Linear electric motors of the present utility model and disk rotary motor both can reduce height dimension, can ensure that again larger actuating force, motor platform of the present utility model have reduced the total height dimension of platform effectively.

Description

Linear electric motors, disk rotary motor and motor platform

Technical field

The utility model relates to linear electric motors, disk rotary motor and motor platform.

Background technology

For laser cutting wafer, the equipment of Wafer Dicing, solar silicon wafers attenuate etc. is usually had to strict restriction to the height dimension of X-Y-Theta motor platform, and this class motor platform requires very high dynamic response and operating accuracy simultaneously, this class platform of Design and implementation is more difficult.

Especially, directions X (first direction) is the direction that whole platform drives load maximum, it is the load of demand motive working platform not only, also to drive motor relevant portion and the motion of various structural member of Y-direction (second direction) and Theta direction (rotation direction), need very large power.

As is known to the person skilled in the art, in the motor drive efficiency of unit volume, iron core linear electric motors and hollow cylinder linear electric motors are better than hollow linear electric motors, but iron core linear electric motors are because the impact of iron core and intrinsic teeth groove power is difficult to reach very high dynamic response (setting time is less than 5ms) and high precision (such as positioning precision is less than 0.1um), and the limited space that hollow cylinder linear electric motors can further reduce on height dimension.

Figure 1A and 1B are respectively schematic isometric and the diagrammatic side view of conventional U-shaped hollow linear electric motors.

As shown in Figure 1A and 1B, magnet assemblies (stator) 10 inner sides are provided with U-shaped groove, two groups of magnet arrays 15,16 are arranged on the both sides of U-shaped groove face to face, and space is left in centre, so that coil block (mover) 20 can be moved betwixt.Coil block 20 can only move in one direction.

As shown in Figure 1B, each magnet the 17, the 18th in magnet array 15,16, individual layer magnet.

Fig. 2 A and 2B show respectively along the profile of A-A line in Figure 1B and B-B line, wherein show the polarity arrangement at the apparent surface place of two groups of magnet arrays 15,16.

As shown in Figure 2 A and 2B, the magnet 17 surface polarity of magnet array 15 be (from left to right) N, S, N ..., S, the magnet 18 surface polarity of magnet array 16 be (from left to right) S, N, S ..., N.Magnet surface place alternating polarity in each magnet array changes.The surface polarity of the magnet of facing mutually in two groups of magnet arrays is contrary.

By reducing the height of magnet 17,18 in magnet array 15,16 and the height of coil, can reduce the height of whole U-shaped hollow linear electric motors.But along with reducing of coil height, actuating force is corresponding reducing also.

As everyone knows, the power that electrified wire is subject in magnetic field is:

$F=I\stackrel{\→}{L}\×\stackrel{\→}{B}$

In the time that the height of coil and magnet reduces, in coil, the effective length L of the wire of cutting magnetic line is corresponding reduces, and remain unchanged, and magnetic field intensity B changes in little situation in electric current I, and actuating force F is corresponding to be reduced.

Similarly, also there is the contradiction between height and actuating force in the design of Theta electric rotating machine.

The height of common electric rotating machine is difficult to further reduction, and the actuating force of existing disk rotary motor is short of to some extent.

In disk rotary motor, in order further to reduce height, just need to reduce magnet thickness, at least can not increase magnet thickness.Like this, magnetic field intensity just can not increase, and even also can reduce.As shown in formula above, want to increase actuating force and reduce height simultaneously, still there is certain difficulty.

Therefore, still need to design and a kind ofly not only can reduce height dimension, but also can ensure compared with the linear electric motors of large driving force, disk rotary motor and motor platform.

Utility model content

A technical problem to be solved of the present utility model is to provide a kind of linear electric motors, disk rotary motor and motor platform, and it both can reduce height dimension, can ensure again larger actuating force.

According to an aspect of the present utility model, a kind of linear electric motors are provided, comprise stator and mover, on one in stator and mover, be provided with coil, on another, be provided with magnet array, coil is faced mutually with magnet array, and magnet array comprises multiple magnet units, and each magnet unit is included in towards two or more magnet stacked together in the direction of coil.

Preferably, stator has U-shaped groove, two groups of magnet arrays are separately positioned on two sidewalls of U-shaped groove, on two sidewalls of U-shaped groove, the polarity of relative two magnet units in position is contrary, coil is arranged on mover, and be arranged in U-shaped groove, and the both sides of coil respectively with two sidewalls of U-shaped groove on magnet array face mutually.

Preferably, be provided with many group coils on mover, coil is hollow coil, and linear electric motors are hollow linear electric motors.

According to another aspect of the present utility model, a kind of disk rotary motor is provided, it is characterized in that, comprising: stator and rotor stator have the first annual disk, multiple coils are along the circumferential direction successively set on the first annual disk.Rotor has the second annual disk, and multiple magnet is along the circumferential direction successively set on the second annual disk.The first annual disk and the second annual disk are oppositely arranged, and multiple magnet and multiple coils are faced mutually.The number of the coil on the first annual disk is 0.8 to 1.3 times of magnet number on the second annual disk.

Preferably, the number of the coil on the first annual disk is 1.2 times of magnet number on the second annual disk.

Preferably, on the first annual disk, be provided with 72 coils, on the second annual disk, be provided with 60 magnet.

According to another aspect of the present utility model, a kind of motor platform is provided, comprising: first direction electric machine assembly, drives its mover to move in a first direction, and second direction electric machine assembly, wherein first direction electric machine assembly is above-mentioned according to linear electric motors of the present utility model, second direction electric machine assembly comprises the second stator and the second mover, on the second stator, be provided with the second magnet array, on in the second mover, be provided with the second coil, the second stator and the second mover are provided so that the second mover can move along first direction and second direction, the normal direction of the action face of the second magnet array is third direction, first direction, second direction and third direction are perpendicular to one another, and the second coil and the second magnet array are provided so that the second magnet array does not apply active force to the second coil substantially in the time that the second mover moves along first direction, and in the time switching in the second coil, the second magnet array produces the active force in second direction to the second coil, the second mover is set to can motion in a first direction under the driving of the mover of first direction electric machine assembly.

Preferably, comprise two or more first direction electric machine assemblies, drive its common mover to move in a first direction by the interaction between their coil and magnet arrays separately.

Preferably, the coil of these first direction electric machine assemblies can be together connected in series or in parallel.

Preferably, the polarity of the multiple magnet in the second magnet array is identical in a first direction, and alternately changes in second direction.

Preferably, the action face of the each magnet in the second magnet array is rectangle, its long edge first direction arranges, its shorter edge second direction arranges, be provided with in a first direction one or more groups magnet, in second direction, be provided with many group magnet, thereby form the second magnet array.

Preferably, on the second stator, there is the second U-shaped groove, two group of second magnet array is separately positioned on two sidewalls of the second U-shaped groove, the second coil is arranged in the second U-shaped groove, and the both sides of the second coil respectively with two sidewalls of the second U-shaped groove on the second magnet array face mutually, in two group of second magnet array, on third direction, the polarity of the relative magnet in position is contrary.

Preferably, also comprise: electric rotating machine, electric rotating machine comprises the 3rd stator and rotor, the 3rd stator is arranged on the second mover, and the 3rd stator has the first annual disk, and multiple coils are along the circumferential direction successively set on the first annual disk, rotor has the second annual disk, multiple magnet is along the circumferential direction successively set on the second annual disk, and the first annual disk and the second annual disk are oppositely arranged, and multiple magnet and multiple coils are faced mutually.

Preferably, the number of the coil on the first annual disk is 1.2 times of magnet number on the second annual disk.

Preferably, on the first annual disk, be provided with 72 coils, on the second annual disk, be provided with 60 magnet.

Preferably, also comprise at least one in motor cable, sensor wire, cooling tracheae, motor cable, sensor wire, cooling tracheae pass the centre bore of the first annual disk and the second annual disk.

Preferably, also comprise: the first crossed roller bearing, be arranged on the stator of first direction electric machine assembly, the mover of first direction electric machine assembly moves along first direction by the first crossed roller bearing; The second crossed roller bearing, is arranged on the mover of first direction electric machine assembly, and the second mover of second direction electric machine assembly moves along second direction by the second crossed roller bearing; The 3rd crossed roller bearing, is arranged between the 3rd stator and rotor of electric rotating machine, and rotor rotates above the 3rd stator by the 3rd crossed roller bearing.

Brief description of the drawings

Figure 1A and Figure 1B are respectively schematic isometric and the diagrammatic side view of conventional U-shaped hollow linear electric motors.

Fig. 2 A and 2B show respectively along the profile of A-A line in Figure 1B and B-B line.

Fig. 3 A and 3B are respectively according to the stereogram of U-shaped hollow linear electric motors of the present utility model and diagrammatic side view.

Fig. 4 is according to the schematic diagram of the coil block of U-shaped hollow linear electric motors of the present utility model.

Fig. 5 shows can be as the schematic diagram of the U-shaped hollow linear electric motors of decoupling zero of Y-direction linear electric motors.

Fig. 6 A-6C schematically shows the setting of the magnet polarity of the magnet array of the U-shaped hollow linear electric motors shown in Fig. 5.

Fig. 7 schematically shows the stereogram of electric rotating machine.

Fig. 8 shows the profile that electric rotating machine is cut open along the diametric plane of crossing corner displacement transducer.

Fig. 9 A and 9B show respectively stator and the rotor of electric rotating machine.

Figure 10 schematically shows the example according to motor platform of the present utility model.

Embodiment

Describe in detail according to linear electric motors of the present utility model, disk rotary motor and motor platform below with reference to accompanying drawing.

motor platform general introduction

First briefly describe according to motor platform of the present utility model.

The motion of directions X electric machine assembly driven object on directions X.

Directions X electric machine assembly can use one or more linear electric motors of hereinafter describing.Preferably, use two according to linear electric motors of the present utility model.

When working to drive with two or more motors on directions X simultaneously, further improve the driving force of directions X, and further effectively reduced the height dimension of platform directions X electric machine assembly in Z direction (third direction).

These two or more motors generally can adopt series system work, be that coil is connected in series, also can adopt parallel way work, coils from parallel connection of coils connects, but while adopting parallel way, the driver of platform is required to larger drive current, so more preferably adopt series system.

Y-direction electric machine assembly is set in addition and carrys out the motion of driven object in Y-direction (second direction).

In applications such as Wafer Dicings, electric rotating machine (theta motor) can also be set.Electric rotating machine, under the driving of directions X electric machine assembly and Y-direction electric machine assembly, moves along directions X and Y-direction, and can be with dynamic load to be rotated, and adjusts angle.

Directions X electric machine assembly, Y-direction electric machine assembly and Theta electric rotating machine are described respectively below.

directions X electric machine assembly

Fig. 3 A and 3B are respectively according to the schematic isometric of hollow linear electric motors of the present utility model and diagrammatic side view.

As shown in Fig. 3 A and 3B, magnet assemblies (stator) 110 inner sides are provided with U-shaped groove, two groups of magnet arrays 115,116 are arranged on two sidewalls of U-shaped groove face to face, and space is left in centre, so that coil block (mover) 120 can be moved betwixt.

On two sidewalls of U-shaped groove, the polarity of relative two magnet units in position is contrary.

Profile along A-A line, B-B line in Fig. 3 B can be similar with the situation of Fig. 2 A and 2B.The polarity arrangement that is each magnet unit 117,118 in magnet array 115 and 116 can be identical with the magnet array of conventional U-shaped hollow linear electric motors shown in Figure 1A, 1B, 2A, 2B 15,16.

As shown in Figure 3 B, each magnet unit the 117, the 118th in magnet array 115,116, stacked together and form in the direction towards coil by two magnet.

The situation of a magnet unit of two the stacked formation of magnet has been shown in Fig. 3 A and 3B.It will be understood by those skilled in the art that and also can adopt more magnet to carry out magnet unit of stacked formation.

As described above, the power that electrified wire is subject in magnetic field is:

$F=I\stackrel{\→}{L}\×\stackrel{\→}{B}$

By stacked two-layer or more multi-layered magnet, can increasing magnetic field B, thus cause the effective length L of coil cutting magnetic line reduces, can maintaining larger actuating force in the case of reducing magnet and coil height like this.

In addition, adopt double-deck magnet arrangement not only can greatly strengthen the excitation field of hollow linear electric motors, the fan-out capability of raising motor, can also solve well blocked up magnet and manufacture difficulty, and difficult problem magnetizes.

Fig. 4 is according to the schematic diagram of the coil block of U-shaped hollow linear electric motors of the present utility model.

On mover 120, be provided with multiple coils 125.Taking 3 phase-4 electrode structure motors as example, coil block adopts many group coils (one group of coil is 3 coils, i.e. the A-B-C three-phase of motor).In Fig. 4, draw the namely situation of 12 coils of four groups of coils that adopts.The coil number that it will be understood by those skilled in the art that employing is more, and the height of coil (and magnet) can be less, and the height dimension of motor more easily meets.

In Fig. 4, coil 125 is hollow coil, there is no iron core.

As shown in Figure 3, coil 125 is arranged in U-shaped groove, the both sides of coil 125 respectively with two sidewalls of U-shaped groove on magnet array 115,116 face mutually.

Arranging of magnet polarity can be with identical shown in Fig. 2 A and 2B., the magnet unit 117 surface polarity of magnet array 115 can be (from left to right), for example, N, S, N ..., S, the magnet 118 surface polarity of magnet array 116 can be (from left to right), for example, S, N, S ..., N.Magnet surface place alternating polarity in each magnet array changes.The surface polarity of the magnet of facing mutually in two groups of magnet arrays is contrary.

Adopt the double-deck magnet arrangement of multi-coil can solve easily the relation of motor fan-out capability and motor height, in limited altitude range, obtain suitable motor power output.

The moving magnetic field that adopts double-deck magnet arrangement that the excitation field of motor is produced much larger than motor coil operating current, (within the scope of impulse stroke, motor actuating force is steady to make so U-shaped hollow linear electric motors obtain the advantage of voice coil motor, fluctuate little, antijamming capability is strong), be not subject to again the restriction of stroke, well together with the advantages of the advantage of U-shaped hollow linear electric motors and voice coil motor.

Directions X adopts the U-shaped hollow linear electric motors of this special structure can also effectively reduce the moving-mass (the cored structure of coil block of iron core linear electric motors, often heavy a lot of than hollow core structures) of electric mover (coil block).

In addition, describe as an example of U-shaped hollow linear electric motors example here.But, those skilled in the art should be understood that, in common (non-U-shaped) hollow linear electric motors, cored linear electric motors, form magnet array by the magnet unit that has used two or more magnet stacked, can strengthen equally excitation field, improve the fan-out capability of motor, can solve well again blocked up magnet and manufacture difficulty, difficult problem magnetizes., the utility model adopts design two-layer or more multi-layered magnet array to be not only applicable to U-shaped hollow linear electric motors, is also applicable to common (non-U-shaped) hollow linear electric motors, cored linear electric motors.

y-direction electric machine assembly

Below with reference to Fig. 5 and Fig. 6 A-6C, describe according to the Y-direction electric machine assembly adopting in motor platform of the present utility model.

In order to alleviate the quality of driven object of directions X electric machine assembly, according in motor platform of the present utility model, the stator of Y-direction electric machine assembly is not arranged on the mover of directions X electric machine assembly, but can equally with the stator of directions X electric machine assembly be fixed on pedestal.

Heavier in view of magnet, in Y-direction electric machine assembly, magnet assemblies is arranged on stator, and coil is arranged on mover, thereby further alleviate mover quality.

Like this, the mover of Y-direction electric machine assembly will move with the mover of directions X electric machine assembly on directions X, again can motion in the Y direction under the driving of Y-direction electric machine assembly.

Coil and the magnet array of Y-direction electric machine assembly are provided so that, in the time that its mover moves along directions X, magnet array does not apply active force to coil substantially, and in the time switching in coil, the second magnet array produces the active force in second direction to the second coil.

This point can realize by design magnet array.For example, the polarity of the multiple magnet in magnet array is identical on directions X, and alternately changes in the Y direction.

In a preferred embodiment, the upper surface of the each magnet in magnet array (in the face of the surface of coil, can be called " action face ") is rectangle, and its long edge directions X arranges, and its shorter edge Y-direction arranges.On directions X, can use like this magnet of lesser amt.

Taking U-shaped hollow linear electric motors as example, the Y-direction electric machine assembly that can be used for motor platform of the present utility model is described below.But, should be appreciated that Y-direction electric machine assembly can not be also U-shaped hollow linear electric motors.That is, can only have one group of magnet array, mover carries coil under the guide of guide rail (or crossed roller bearing), move on directions X with the mover of directions X electric machine assembly, and motion in the Y direction under the driving of Y-direction electric machine assembly.

Fig. 5 shows the schematic diagram as the U-shaped hollow linear electric motors of example.Shown in Fig. 5, U-shaped hollow linear electric motors are provided with the electric machine assembly of two groups of magnet arrays facing mutually.These U-shaped hollow linear electric motors have decoupling zero (decouple) structure.

As shown in Figure 5, stator 500 has U-shaped groove, on two sidewalls of U-shaped groove, is provided with two groups of magnet arrays 510,520.Two groups of magnet arrays 510,520 are arranged on the coil both sides that arrange on coil block (mover) 530.

The polarity of the magnet of facing mutually in Z direction in two groups of magnet arrays 510,520 is contrary.Like this, the magnet array 510,520 of both sides can produce the active force on equidirectional to coil.

Fig. 6 A-6C schematically shows according to the setting of the magnet polarity of the magnet array 510,520 of U-shaped hollow linear electric motors of the present utility model (i.e. two surfaces that magnet array is relative, also i.e. the action face to coil generation effect).

Wherein Fig. 6 B is the schematic top view of U-shaped hollow linear electric motors shown in Fig. 5.Fig. 6 A is that hypothesis is cut the cutaway view opening on backward open along C-C line in Fig. 6 B.Fig. 6 C is that hypothesis is cut the cutaway view opening under backward open along D-D line in Fig. 6 B.

As shown in Fig. 6 A and 6C, in magnet array 510,520, the physical dimension of each magnet can be the same, and just magnetizing direction is different.Every a line has three bar magnets of identical polar.But the utility model is not limited to a line three bar magnets, can be a long magnet, can be also the magnet of any other quantity.

See from top to bottom, the magnetic of each row alternately changes.See along Y-direction, the magnet surface place polarity of magnet array 510 be followed successively by (in figure from top to bottom) S, N, S ..., N, correspondingly, the magnet surface place polarity of magnet array 520 be followed successively by (in figure from top to bottom) N, S, N ..., S.Magnet surface place alternating polarity in each magnet array changes.And the surface polarity of the magnet of facing mutually in two groups of magnet arrays is contrary.

The example that shown in Fig. 6 A and Fig. 6 C, just magnet polarity arranges, the polarity setting of two sections also can be exchanged, and does not affect the performance of motor.

In the time that coil block 530 moves under the driving of two hollow cylinder linear electric motors of directions X, there is no variation (when the physical dimension error of each magnet and the error that magnetizes are negligible) by the magnetic flux of coil block, therefore, no matter whether coil block switches on, it all can not produce power output at directions X, that is to say that coil block can only move along with directions X, can not disturb and affect the motion of directions X.But in the time that coil block is switched on, in fact the U-shaped hollow linear electric motors of decoupling-structure are at this time exactly common U-shaped hollow linear electric motors, produce output and the motion of Y-direction.

Y-direction electric machine assembly adopts this special decoupling-structure, dexterously the magnet of Y-direction electric machine assembly is placed in outside the motion of directions X, make the motor of directions X need not drive the magnet assemblies of very heavy Y-direction motor, greatly improved driving force and the dynamic property of X-Y platform.And adopt this decoupling-structure can arrange easily Y-direction motor, reduce as far as possible the height dimension of Y-direction.

In addition, Y-direction electric machine assembly adopts this special decoupling-structure, and the stator of Y-direction electric machine assembly does not need to be arranged on the mover of directions X electric machine assembly.Like this, the height of the stator of Y-direction electric machine assembly can be superimposed upon on the height of directions X electric machine assembly completely.By this assembly of directions X electric machine assembly and Y-direction electric machine assembly, can further reduce the height of motor platform.

theta motor (disk rotary motor)

Describing below with reference to Fig. 7, Fig. 8, Fig. 9 A and 9B can be according to the disk rotary motor further arranging in motor platform of the present utility model.Disk rotary motor can adopt disc type DDR (directly the driving rotation) motor of large hollow.

Fig. 7 schematically shows the stereogram according to electric rotating machine of the present utility model.

Fig. 8 shows the profile that electric rotating machine is cut open along the diametric plane of crossing corner displacement transducer.

As shown in Figure 7 and Figure 8, this electric rotating machine comprises stator 710 and rotor 720.Coil 715 is arranged on stator 710, and magnet 725 is arranged on rotor 720.

On stator 710, can be provided with corner displacement sensor read heads 730, on rotor 720, can be provided with corner displacement transducer ruler 735.Corner displacement transducer ruler 735 is cyclic structures.

Between stator 710 and rotor 720, be provided with rotation crossed roller bearing 740.Rotor 720 rotates above stator 710 by rotation crossed roller bearing 740.

Fig. 9 A and 9B show respectively stator 710 and the rotor 720 of electric rotating machine.

Stator 710 and rotor 720 all have annular disk-like structure.Multiple coils 715 are successively set on the annual disk of stator 710 along circumferencial direction.Coil 715 can not contain iron core, is hollow coil.Multiple magnet 725 is along the circumferential direction successively set on the annual disk of rotor 720.

As shown in FIG. 7 and 8, stator 710 and rotor 720 are oppositely arranged, and multiple magnet 725 is faced mutually with multiple coils 715.

The number of the coil 715 on the annual disk of stator 710 can be about 0.75 times to 1.5 times of number of the magnet 725 on the second annual disk, in one embodiment, is 0.8 times to 1.3 times, in another embodiment, is 1.2 times.For example, on the annual disk of stator 710, can there be 72 coils 715, and on the second annual disk, have 60 magnet 725.The external diameter of the first and second annual disks can be for roughly from 10 centimetres (4 inches) to 30 centimetres (12 inches).

In existing disk rotary motor, coil is generally 3/4 with the number ratio of magnet, and 0.75.In this application, in order to improve output torque in limited space, and obtain rotating more stably output and less velocity perturbation, inventor has expected adopting larger coil magnet number ratio.

The power that electrified wire is subject in magnetic field is as described above:

$F=I\stackrel{\→}{L}\×\stackrel{\→}{B}$

In improvement for linear electric motors, due to effective length, L reduces hereinbefore, so increased magnetic field intensity B by stacked magnet.And in disk rotary motor, if increasing magnetic field B, thereby strengthen magnet thickness, the corresponding increase of the height of disk rotary motor.And constant at magnet height, while even suitably reducing magnet height in order to reduce the object of motor whole height, magnetic field intensity is difficult to increase, and even also can reduce.

It will be understood by those skilled in the art that each coil can have the effective length of certain cutting magnetic line by the shape of design coil.

By increasing coil quantity, can correspondingly strengthen total effective length of cutting magnetic line.

Like this, the deficiency of magnetic field intensity B, thus can make up by the effective length L that increases coil number increase cutting magnetic line.

By adopting above-mentioned tray type structure, can, in the case of maintaining enough actuating force, reduce as far as possible the height dimension of electric rotating machine.

In addition, adopt hollow tray type structure, the cable pipelines such as various motor cable in motor platform, sensor wire, cooling tracheae etc. can be through the centre bore setting of the annual disk of stator and rotor.Like this, also contribute to further to reduce the height of whole platform.

motor platform

Describe in more detail according to motor platform of the present utility model below with reference to Figure 10.

Figure 10 schematically shows the example according to motor platform of the present utility model.

On pedestal, be provided with at certain intervals two U-shaped hollow linear electric motors as shown in Figure 3A, as directions X electric machine assembly.

Two directions X electric machine assemblies, by the interaction between their coil block (120) and magnet arrays (in the U-shaped groove of stator 110) separately, drive its common mover (X plate 150) to move on directions X.X plate 150 can be fixed together by the fasteners such as screw and two coil blocks (mover) 120.

Directions X crossed roller bearing 140 on the stator 110 of directions X electric machine assembly.X plate 150 moves along directions X by directions X crossed roller bearing 140.

The stator 500 of Y-direction electric machine assembly is not arranged on the mover of directions X electric machine assembly.Coil block 530 is fixed together with Y plate 550 (Y-direction mover).

On X plate 150, be provided with Y-direction crossed roller bearing 540.Y plate 550 moves along Y-direction by Y-direction crossed roller bearing 540.

The stator 710 of electric rotating machine is arranged on Y plate 550.

Between stator 710 and rotor 720, be provided with rotation crossed roller bearing 740 (Fig. 7,8).Rotor 720 rotates above stator 710 by rotation crossed roller bearing 740.

By using directions X crossed roller bearing 140, Y-direction crossed roller bearing 540, rotation crossed roller bearing 740, can further reduce according to the height dimension of X-Y-Theta motor platform of the present utility model, ensure precision and rigidity that platform is good simultaneously.

The read head of directions X linear displacement transducer 130 is arranged on the stator 110 of directions X electric machine assembly, and ruler is arranged on mover (X plate 150).

The read head of Y-direction linear displacement transducer 535 is arranged on X plate 150, and ruler is arranged on mover (on Y plate 550).

The corner displacement sensor read heads 730 of electric rotating machine is arranged on stator 710, and ruler 735 is arranged on rotor 720.

Be set to relatively fix by the read head of displacement transducer, and ruler motion is conducive to reduce the impact of motion on platform property and the impact on sensor output signal of sensor wire.This point is even more important in the situation that motor platform height dimension reduces.

In this motor platform, directions X electric machine assembly, Y-direction electric machine assembly and theta electric rotating machine are all optimised, to reduce the height of himself.Meanwhile, the assembling mode of directions X electric machine assembly and Y-direction electric machine assembly also can further reduce the height of motor platform.Meanwhile, the driveability of each motor is all kept.

Therefore, as mentioned above, set about from many aspects according to motor platform of the present utility model, enough actuating forces, reduced the height dimension of motor platform in the case of ensureing.

In the motor platform model machine of realizing in design, podium level size is less than 128mm, and performance index are as follows:

Directions X resolution is 0.1um,

Directions X kinematic accuracy is ± 2um,

Acceleration is 6G (G is acceleration of gravity),

Directions X maximum movement speed is 2m/s,

Directions X dynamic response time is 10ms;

Y-direction resolution is 0.1um,

Y-direction kinematic accuracy is ± 2um,

Acceleration is 8G (G is acceleration of gravity),

Y-direction maximum movement speed is 2m/s,

Y-direction dynamic response time is 10ms;

Theta resolution is less than 0.2arcsec (second of arc),

Precision is less than 1.5arcsec,

Theta direction dynamic response time is 10ms.

So far, described in detail according to the specific embodiment of linear electric motors of the present utility model, disk rotary motor and motor platform.But it will be understood by those skilled in the art that the utility model is not limited to various details described herein, but can make suitable amendment.Protection range of the present utility model is limited by appended claims.

Claims (15)

1. linear electric motors, comprise stator and mover, are provided with coil on one in described stator and described mover, are provided with magnet array on another, and described coil is faced mutually with described magnet array,

It is characterized in that,

Described magnet array comprises multiple magnet units,

Each magnet unit is included in towards two or more magnet stacked together in the direction of described coil.

2. linear electric motors according to claim 1, is characterized in that,

Described stator has U-shaped groove, and described in two groups, magnet array is separately positioned on two sidewalls of described U-shaped groove,

On two sidewalls of described U-shaped groove, the polarity of relative two magnet units in position is contrary,

Described coil is arranged on described mover, and is arranged in described U-shaped groove, and the both sides of described coil respectively with two sidewalls of described U-shaped groove on magnet array face mutually.

3. linear electric motors according to claim 1 and 2, is characterized in that, are provided with many group coils on described mover, and described coil is hollow coil, and described linear electric motors are hollow linear electric motors.

4. a disk rotary motor, is characterized in that, comprising:

Stator and rotor, described stator has the first annual disk, and multiple coils are along the circumferential direction successively set on described the first annual disk,

Described rotor has the second annual disk, and multiple magnet is along the circumferential direction successively set on described the second annual disk,

Described the first annual disk and described the second annual disk are oppositely arranged, and described multiple magnet and described multiple coils are faced mutually,

The number of the coil on described the first annual disk is 0.8 to 1.3 times of magnet number on described the second annual disk.

5. disk rotary motor according to claim 4, is characterized in that,

The number of the coil on described the first annual disk is 1.2 times of magnet number on described the second annual disk.

6. disk rotary motor according to claim 5, is characterized in that,

On described the first annual disk, be provided with 72 coils,

On described the second annual disk, be provided with 60 magnet.

7. a motor platform, comprising:

First direction electric machine assembly, drives its mover to move in a first direction; And

Second direction electric machine assembly,

It is characterized in that,

Described first direction electric machine assembly is according to the linear electric motors described in any one in claims 1 to 3,

Described second direction electric machine assembly comprises the second stator and the second mover, on described the second stator, is provided with the second magnet array, is provided with the second coil in described the second mover,

Described the second stator and described the second mover are provided so that described the second mover can move along first direction and second direction,

The normal direction of the action face of described the second magnet array is third direction,

Described first direction, described second direction and described third direction are perpendicular to one another, and

Described the second coil and described the second magnet array be provided so that in the time that described the second mover moves along described first direction described in the second magnet array substantially described the second coil is not applied to active force, and in the time switching in described the second coil, described the second magnet array produces the active force in described second direction to described the second coil

Described the second mover is set under the driving of the mover of described first direction electric machine assembly, to move upward in described first party.

8. motor platform according to claim 7, is characterized in that, comprises first direction electric machine assembly described in two or more, drives its common mover to move in a first direction by the interaction between their coil and magnet arrays separately.

9. motor platform according to claim 8, is characterized in that, the coil of described two or more first direction electric machine assemblies is together connected in series or in parallel.

10. motor platform according to claim 7, is characterized in that,

The polarity of the multiple magnet in described the second magnet array is identical on described first direction, and alternately changes in described second direction.

11. motor platform according to claim 10, is characterized in that,

The action face of the each magnet in described the second magnet array is rectangle, first direction setting described in its long edge, and second direction setting described in its shorter edge,

On described first direction, be provided with one or more groups magnet, in described second direction, be provided with many group magnet, thereby form described the second magnet array.

12. according to the motor platform described in any one in claim 7 to 11, it is characterized in that,

On described the second stator, there is the second U-shaped groove, two group of second magnet array is separately positioned on two sidewalls of described the second U-shaped groove, described the second coil is arranged in described the second U-shaped groove, and the both sides of described the second coil respectively with two sidewalls of described the second U-shaped groove on the second magnet array face mutually

In described two group of second magnet array, on described third direction, the polarity of the relative magnet in position is contrary.

13. according to the motor platform described in any one in claim 7 to 11, it is characterized in that, also comprises:

According to the disk rotary motor described in any one in claim 4 to 6, the stator of described disk rotary motor is arranged on described the second mover.

14. motor platform according to claim 13, it is characterized in that, also comprise at least one in motor cable, sensor wire, cooling tracheae, described motor cable, sensor wire, cooling tracheae are through described first annual disk of described disk rotary motor and the centre bore of described the second annual disk.

15. motor platform according to claim 14, is characterized in that, also comprise:

The first crossed roller bearing, is arranged on the stator of described first direction electric machine assembly, and the mover of described first direction electric machine assembly moves along described first direction by described the first crossed roller bearing;

The second crossed roller bearing, is arranged on the mover of described first direction electric machine assembly, and the second mover of described second direction electric machine assembly moves along described second direction by described the second crossed roller bearing;

The 3rd crossed roller bearing, is arranged between the 3rd stator and rotor of described disk rotary motor, and described rotor rotates above described the 3rd stator by described the 3rd crossed roller bearing.