DE10122660C2 - The wave gear - Google Patents

Description

The invention relates to a wave gear according to the preamble of the main claim.

The function of this - also known as harmonic drive or ring gear transmission - Corrugated gear as a very strongly reducing, self-locking system with the drive shaft coaxial rotating output is based on the fact that a rotating so-called Well generator radially deforms an inner wheel tire all the way around and thereby its outer surface outer circumferential surface all around locally against the hollow cylindrical inner circumferential surface che slightly larger circumference of a stationary, dimensionally stable support ring presses. As a result, the inner wheel rolls itself or its wheel arbor rotatably mounted on it fen non-positively via friction surfaces or positively via teeth in the support ring from, the wheel or its tire slower depending on the circumferential difference as the motor-driven drive core of the wave generator rotates. This versus Drive greatly slowed rotary movement is preferably on the outer surface or external toothing of the wheel tire on the inner circumferential surface or internal toothing of another hollow cylindrical outer ring, but concentric to the support ring not stationary but transferred to the rotatable output ring. In which generic contribution "Genial einfach" by H. Hirn (KEM Antriebstechnik Heft 11/1996) as a wave generator a cam-shaped non-circular (oval in axial cross-section) Drive core rotated concentrically in the hub of the radially deformable inner wheel. As radial Oriented plunger-acting, dimensionally stable spokes between those running around the drive core radially deformed hub and the radially deformable, externally toothed tire this inner wheel cause the external toothing according to its rotating  radial deformation with the internal toothing of the support ring in each case only via the here just rolling, limited arc piece is engaged. This wave gear is on due to its strong reduction and self-locking for sensitive and well reproduced feasible, mechanically stable, manually performed adjustment and setting tasks suitable. Such a wave generator is usually driven by a motor a high-speed, coaxially connected to the drive core and therefore inexpensive available low voltage dc motor, its rotation so in a very much long Samere rotary movement corresponding to greater torque on the output shaft is set. Such a motor-gear combination is used in particular by elek tromechanical, rotary adjusting devices in the motor vehicle.

According to DE 197 08 310 A1, such a wave gear can also have an inner wheel be equipped, one in axial with regard to the different number of teeth Direction to different radii graded Flexband tires to larger To enable reductions without increasing the construction volume. For circulating ver Formation of the tire is given there in addition to the non-circular drive core mentioned if necessary, carries the tire on a rotating roller bearing - alternatively, arrangements with two or three planet wheels rotating in the tire, for example in the form of support rollers provided, which are mounted axially parallel in front of a rotating carrier disc and thereby the radially flexible external gearing circumferentially against the two adjacent to each other beard rigid internal gears.

The invention is based on the technical problem, while maintaining its apparatus and application-oriented advantages to continue the wave gear develop that there are other applications that are not yet feasible due to their design open up opportunities especially when equipped as a geared motor.

The solution characterized in the main claim as a hollow shaft gear with concentric through the wave gear extending channel of in relation to the device diameter comparatively very large inner diameter gives the advantage of through the center of the transmission, for example, supply lines or construction able to lay elements. The wave generator is now a concentrically rotating one Washer as a carrier of at least two eccentric, axially parallel oriented bolts zen, over which (and thus axially offset against the ring washer) a radially flexible Cuff runs in the manner of an axially wide toothed belt, which umlau with the bolts fend locally in the inner periphery of the coaxially arranged side by side, the washer with its bolts surrounding support and driven rings is pressed into it. So can now z. B. concentric electrical or hydraulic supply lines through the well gears run through, which is a prefabricated and space-saving gear installation allows. The wave gear can also be stationary, for example in the manner of a sleeve a stationary pipeline are carried to z. B. a fluid throttle in the manner of an iris diaphragm in this pipeline through direct attack by the ver pivotable gear output ring protrude radially from the pipeline adjust the aperture lever; or coaxially through the fixed wave gear a bolt, which is movably mounted - possibly even in the gearbox itself - runs through  for switching or signaling tasks, that of the output ring by twisting or (via a worm thread engagement) by axial displacement.

An electric motor drive for this hollow wave gear can be arranged externally and about a gear or worm gear on the input side of the gearbox be closed. In the case of a belt drive on the drive side, the carrier ring can be used for the rotating bolts also serve as a pulley or toothed belt pulley serve. However, a wave geared motor is more space-saving and easier to assemble, if its drive is integrated into the transmission by its rotor, the is then equipped with the retaining ring for the circumferential pressure pin on the front Form of a thick-walled hollow cylinder in an annular stator housing.

Regarding additional training and their characteristics and advantages is not on the further claims also on the following description of one in the drawing limited to the essentials of the function and not quite to scale sketch graced preferred implementation example for hollow wave gear and invention their drive motors referenced. The drawing shows:

Fig. 1 in the axial longitudinal section of a gear motor with a built into the wave gear drive elec tromotorischem,

Fig. 2 in cross section through the support ring of the wave gear according to FIG. 1 whose ring disc equipped with umlau fenden rollers in front view and

Fig. 3 shows a wave gear motor with an annular disc equipped according to Fig. 2, the wave gear but is now driven by a belt drive from an externally stationed motor.

As shown in the introduction, is in itself in a wave gear 8, a radially verformba res internal gear concentrically arranged in a dimensionally stable hollow cylindrical, axially short Gehäu sefesten support ring 9, coaxially penetrated in its hub by the rotating non-circular drive core of the so-called wave generator 11, whereby the Center of the shaft gear 8 is structurally proven. However, in order to be able to keep this center free for other construction or assembly requirements, according to the invention a radially flexible, toothed belt-shaped sleeve 10 now experiences its circumferential radial deformation from a rotating annular disk 12 for it - compared to the rotation of the wave generator 11 - slowed rolling of the engagement area 17 in Support ring 9 . That centrally large-area perforated disk 12 carries several, preferably diametrically opposed to each other, two axially parallel bolts 13 , around which the flexible sleeve 10 extends concentrically to the annular disk 12 and axially adjacent to the disk 12 . In order to reduce the frictional losses, the bolts 13 can be axle shafts for roller-mounted rollers 14 , which, in the illustrated, structurally preferred example case, are put over the free foreheads in the manner of the bearing bolts 13 assigned to them. These two, diametrically opposite, supported by the washer 12 rollers 14 press the toothed outer surface of the flexible sleeve 10 radially in the engagement area 17 radially in the also toothed, axially adjacent, dimensionally stable hollow cylindrical inner surface surfaces of the stationary support ring 9 and the axially adjacent rotating From drive ring 15 into it.

By rotating the rollers about the transmission axis 16 by means of the driven ring plate 12 14, so they roll along the circumferential arc-shaped engaging portion 17, the flexible sleeve 10 in the rings 9/15 from. Contrary to in Fig. 2 and in Fig. 3 in so far only symbolically to-understand schematic diagram of the peripheral or Zähnediffe is rence between the rings 9/15 the one hand and on the other hand the flexible sleeve 10 did plural very small. As is known, this difference determines the correspondingly very large reduction ratio of the wave gear 8 . The circumference of the flexible sleeve 10 or its circularly spanned diameter is therefore hardly smaller than the inner circumference of each of the two rings 9 and 15 .

The flexible sleeve 10 can be constructed on a dimensionally stable, in the circumferential direction rigid but ra dial elastically deformable carrier approximately in the form of a wide ring made of sheet steel or plastic, on the outer lateral surface of which the teeth for the formally rolling engagement area 17 are welded up depending on the material pairing, glued, sprayed or vulcanized. In the case of a very flexible flexible sleeve 10, such as in the case of an axially wide and radially thin toothed belt, on the other hand, there is the possibility that the sleeve 10 , due to the force of gravity, sags into the channel cross section in the center of the wave gear 8 apart from its current engagement area 17 determined by the rollers 14 so here the free passage through the coaxial channel 18 prevents. As a remedy, on the other hand, the annular disk 12 , which is offset peripherally from the bearing bolt 13 , is equipped with axially parallel support pins 19 which radially catch the flexible sleeve 10 apart from the forced engagement areas 17 . Supported support rollers are also possible here, but are not necessary due to the lack of friction losses, because the cuff 10 is at best unloaded here, as can be seen in FIG. 2 above.

In the example of FIG. 3, the motor drive 20 is mounted axially parallel to the transmission 8 apart from the latter. The rotation is transmitted by means of a transmission belt 21 from a driving pulley 22 through axially parallel slots in the housin (stator 25 ) through to the outer periphery of the ring gear 12 equipped with the rolling rollers 14 of the hollow gear 8 , which is a depending on the load conditions frictional or a non-positive transmission with smooth belts or toothed belts and along the front edge correspondingly profiled belt and washers 22 , 12 can act. An external drive, for example, of a spur-toothed ring disk 12 via worm or gear wheel transmissions, can also be advantageously implemented here.

With regard to the handling and space requirements when using the hollow gear motor, it is more expedient than an external drive to integrate the drive 20 into the wave gear 8 , as taken into account in FIG. 1. Here, the washer 12 is axially opposite the bolt 13 coaxially with an electromotive, multi-pole, radially magnetized rotor 23 in the form of a thick-walled hollow cylinder designed in such a way that the lateral surface of its bore with that of the bore in the washer 12 to the central channel 18 through the geared motor through at least essentially aligned. The magnetization of the rotor 23 can be permanent-magnetic or electromagnetic. The rotor 23 is surrounded by the exciter coil 24, which is also hollow cylindrical, on the inner circumferential surface of the hollow cylindrical stator 25 fixed to the housing. The also surrounds the torsionally rigid coaxial with the rotor 23 connected annular disc 12 and is then equipped on its free end face with the stationary support ring 9 , within which the Flexman collar 10 is rolled by means of the rollers 14 rotating therein.

For the radial guidance of the support ring 9 axially adjacent output ring 15 , a reciprocal peripheral engagement with the support ring 9 is provided in FIG. 1, and in addition a torsionally pinned with the housing-fixed ring 9 axial collar as a holder 26 in the manner of a union nut. The output ring 15 can be bent as outlined in the manner of a circumferential flange in NEN to a radial, centrally perforated end plate 27 which lies axially in front of the rollers 14 and thereby limits their axial mobility.

The approaching to the periphery of the central channel 18 inner edge 28 of the end plate 27 is expediently equipped with a roller bearing when the end plate 27 and thus the output ring 15 can be rotated radially on a construction element running along the channel 18 , such as a pipe or a shaft should support. If this structural element is to be rotated with the driven ring 15 , the inner edge 28 has radial claws instead of the bearing for engagement in correspondingly profiled notches on the rotatable structural element. If, on the other hand, it is an axially displaceable spindle rod, which extends coaxially through the hollow gear 8 , then a threaded inner edge 28 of the drive end plate 27 engages in the worm profile on the spindle rod in order to axially displace it.

In order to be able to lead supply or construction elements centrally through a wave gear 8 according to the invention, its wave generator 11 has a circumferentially driven annular disk 12 with axially parallel bolts 13 , which has a flexible sleeve 10 , which is guided over it, along longitudinally arcuate engagement areas 17 in the inner lateral surfaces of the axially one inside the other 9/15 umlau push adjacent support and drive rings fend radially. The annular disc 12 can be designed as a pulley or gear disc to an externally arranged electromotive drive 20 . It is expedient to integrate a hollow drive 20 into the hollow shaft gear 8 by axially fitting the annular disk 12 with a coaxial hollow cylindrical rotor 23 , which is also surrounded by a support for the support ring 9 , also a hollow cylindrical electromagnetic stator 25 .

Claims (12)

1. wave gear ( 8 ) with a shaft generator ( 11 ) rotating about its axis ( 16 ) for coaxial rolling of the engagement area ( 17 ) of a flexible sleeve ( 10 ) in a support ring ( 9 ) and in an axially adjacent output ring ( 15 ), characterized in that as a wave generator ( 11 ) an annular disc ( 12 ) is provided with a large internal diameter compared to the outer diameter of its central bore, which is equipped on at least one of its two surfaces with the engagement areas ( 17 ) be axially parallel bolts ( 13 ) , over which the Flexman collar ( 10 ) runs. 2. wave gear according to claim 1, characterized in that the annular disc ( 12 ) is additionally equipped with bolts ( 13 ) parallel pin ( 19 ) for intercepting a heavy force due to the bore of the annular disc ( 12 ) sagging flexible sleeve ( 10 ) , 3. wave gear according to one of the preceding claims, characterized in that the vertically supporting pin ( 19 ) and / or at least the radially pressing pin ( 13 ) are rotatably supported on the annular disc ( 12 ) or carry rollers ( 14 ). 4. wave gear according to one of the preceding claims, characterized in that the driven ring ( 15 ) to an axially in front of the bolt ( 13 ) and the flexible sleeve ( 10 ) located, that radially overlapping end plate ( 27 ) is bent. 5. wave gear according to one of the preceding claims, characterized in that the relative to the housing-fixed support ring ( 9 ) rotatable output ring ( 15 ) is axially bound to the support ring ( 9 ). 6. wave gear according to one of the preceding claims, characterized in that the central, substantially aligned bores in the annular disc ( 12 ) and in a face plate ( 27 ) with which the output ring ( 15 ) is equipped, a centrally through the wave gear ( 8 ) extending coaxial channel ( 18 ) be limit. 7. wave gear according to the preceding claim, characterized in that the end plate ( 27 ) on its inner edge ( 28 ) is equipped with a profile for resting on or for engagement in the substantially cylindrical lateral surface of a construction element located in the channel ( 18 ). 8. wave gear according to one of the preceding claims, characterized in that the annular disc ( 12 ) is structurally in rotary connection with a motor drive ( 20 ). 9. wave gear according to one of the preceding claims, characterized in that the annular disc ( 12 ) concentrically to it rotatably equipped with a hollow cylindrical rotor ( 23 ) of an electric drive ( 20 ). 10. Corrugated gear according to one of the preceding claims, characterized in that the support ring ( 9 ) concentrically rotatably with it is equipped with a hollow cylindrical stator ( 25 ) of an electric drive ( 20 ). 11. wave gear according to one of the preceding claims, characterized in that the annular disc ( 12 ) is equipped with a transmission pulley. 12. wave gear according to one of the preceding claims, characterized in that the annular disc ( 12 ) is designed as a toothed disc.