EP2943698A1

EP2943698A1 - Transmission device

Info

Publication number: EP2943698A1
Application number: EP14700455.0A
Authority: EP
Inventors: Dirk Oberschmidt; Eckart Uhlmann
Original assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Current assignee: Fraunhofer Gesellschaft zur Forderung der Angewandten Forschung eV
Priority date: 2013-01-11
Filing date: 2014-01-10
Publication date: 2015-11-18
Also published as: WO2014108496A1; DE102013200347A1

Abstract

The invention relates to a transmission device, comprising a drive module that can be rotationally driven about a driving axis (3). In order to ensure uniform loading of a tool that is to be drivable by means of the drive module, it is provided that the drive module has a base (1, 2, 26, 27, 28, 31 32) rotatable about the driving axis and an output element (12, 13) for transmitting a rotational motion to a functional element, the output element being mounted rotatably about an output axis (12a) in relation to the base, wherein the base is rotatable in relation to an arrangement of teeth (4a), in particular a stationary arrangement of teeth, and has a planet gear (5), which is mounted rotatably about a first auxiliary axis (8) and which revolves on a circular path (20) during the course of rotation of the base, is driven by meshing with the arrangement of teeth, and interacts with the output element (12, 13) directly or by means of one or more additional gears.

Description

transmission device

The invention is in the field of mechanical engineering, especially of mechanics, and relates to a transmission device with a drive module rotatably drivable about a drive axis.

The invention can be used with particular advantage in processing machines, in particular where tools are mounted in rotation and are moved relative to a workpiece. This is the case in particular during machining, for example in the case of milling heads, which can perform a translational movement in addition to a rotational movement, but also in lapping and polishing tools or in erosion electrodes. In such tools, the operation with a rigid output shaft often has the consequence that corresponding shafts and shaft bearings are loaded on one side and worn, and also that the machining tools are subject to asymmetrical wear, so that on the one hand the precision of the processing can suffer and on the other hand the tool is not optima! is being used.

Basically, it is known in a lapping kinematics, in addition to a rotation of the shaft of the lapping tool to realize an eccentric deflection of the output shaft, which is superimposed on the rotational movement. The present invention is based on the object, with a rotating tool to realize a variation of the wear of the tool on the workpiece with the least possible constructive effort. The solution should be reliable and guarantee a long service life of the mechanism.

The object is achieved with the features of the invention according to claim 1. For this purpose, a transmission device is provided with a drive module rotatably drivable about a drive axis, the drive module having a base rotatable about the drive axis and a support element rotatably mounted about a Abtrtebsachse rotatably mounted output element for transmitting a rotational movement to a Funktionsseiement, the base relative to a in particular stationary, toothing is rotatable and relative to the base about a first auxiliary axis rotatably mounted planetary gear which rotates in the course of rotation of the base on a circular path and is driven by meshing with the toothing and with or directly by means of one or more other gears interacts with the output element. The transmission has a drive module, which as a whole can be driven rotatably, for example by means of a motor, in particular an electric motor. The drive module may for this purpose have a drive shaft which is fixedly connected to the rotatable base. A planetary gear is rotatably mounted indirectly or directly on the base. The base may, for example, have one or more flat plates, each of which is perpendicular to the drive axle and fixedly connected to each other, for example, by extending between them rods or a hollow cylindrical housing part. On one of the plates or between two plates, the planetary gear can be mounted simply or repeatedly rotatably, advantageously be roller-mounted. The auxiliary axis about which the planetary gear is rotatable is opposite to

Drive axle advantageously offset, so that the Hiifsachse during rotation of the Base rotates on a circular path. Thus, the planetary gear runs on a circular path and meshes with a toothing, which is arranged, for example, stationary either inside or outside the circular path of the planetary gear relative to the base. As a result, the planetary gear is driven, so that on the one hand performs a rotation about its central axis and on the other hand, a rotation on a circular path.

The planetary gear can thus interact directly with an output element and on the other hand transmit the rotations about its central axis on the one hand and on a circular path. In this case, the planetary gear one or more further gears may be connected downstream in the gear train. The planetary gear can also directly drive an output shaft.

Advantageously, the invention can be realized in that the planetary gear directly or by means of one or more other gears drives a driven gear, which is connected to the output element, in particular a rotating about an output shaft output shaft. In this case, the output shaft relative to the auxiliary axis of the planetary gear can be radially offset, wherein the output shaft with respect to the drive shaft stand still or can perform around the drive axis around a translational movement.

A further advantageous embodiment of the invention provides that the toothing is provided as an annular internal toothing on a ring gear, in particular on a stationary in the transmission device relative to the drive module fixed ring gear. The ring gear is advantageously realized as a hollow cylindrical, in particular annular component, in which on its inner circumferential surface a circumferential toothing is arranged. The ring gear may be stationary, for example, in a housing of the transmission device in which rotates the base to be arranged. However, the ring gear may also be rotatable within the gear housing about its axis of symmetry, so that both the ring gear and the base rotates, advantageously coinciding the axis of rotation of the base, so the drive shaft, and the axis of rotation of the ring gear. However, it is basically a tumbling rotary motion of the ring gear to a It is conceivable to move an axis on a circular path, wherein it must be ensured that the internal toothing of the ring gear is always in engagement with the planetary gear.

With the construction described can be advantageously realized also that the drive module is at least partially disposed within the ring gear. As a result, a compact construction of the transmission device can be achieved overall.

It may also be advantageously provided that the toothing is provided as an annular external toothing on a toothed wheel, in particular on a toothed wheel which is fixedly fixed in the gear mechanism relative to the drive module. Also in this case, the planetary gear on the toothing, specifically the external teeth, a gear run and mesh with this, so that also a rotation of the Pianetenzahnrades is achieved with simultaneous traversed transient movement on a circular path. For the gear in principle applies the above to the ring gear executed, namely that the gear can be fixed either fixed relative to the base or against the base independently of this can be arranged rotatably driven.

The output shaft may coincide with the drive axis, but it may also advantageously radially offset relative to the drive axis and in particular in the course of rotation of the drive module relative to the drive axis to be movable.

Advantageously, the output shaft is parallel to the drive axis and is radially displaceable within the drive module with respect to the drive axis.

The radial displaceability of the output shaft relative to the drive axle causes, for example, the output shaft with simultaneous rotation of the output element to be self-transiatorisch on a circular path about the drive axis movable, the radius of this translational

Movement of the output shaft by the displacement is selectable. The Output shaft can be moved so far that it coincides with the drive axle.

In principle, the output element can be connected directly to the planetary gear and thus perform a rotational movement about itself, the direction of rotation is opposite to the direction of rotation of the drive module and the base.

On the other hand, the pinion gear may also drive another gear identical to or directly connected to the output member so that the output member rotates in a sense of rotation coincident with the direction of rotation of the drive module and the base. In addition, further gears between the output element and the planetary gear may be arranged, the one

Design of the speed of the output element and the direction of rotation allow.

In an advantageous realization of the invention can be provided that the output shaft is fixed relative to the first auxiliary axis, in particular to this parallel and radially of this is arranged at a fixed distance. This design is particularly advantageous if the output movement is transmitted from the planetary gear to another gear, which in turn forms the output element or is directly connected to this. The output element may be, for example, an output shaft, on which the further gear is fixed. In this case, it is necessary that the distance between the auxiliary axis and the output shaft remains largely constant.

It may also be advantageous if the output shaft is parallel to the drive axis and rotates relative to this at a fixed radial distance.

However, it is also conceivable that alternatively the output axis, for example, perpendicular to the drive axis and the auxiliary axis, if z. B. the planetary gear carries a bevel gear that transmits a rotation to another bevel gear that is mounted perpendicular to the auxiliary axis. The Wettier bevel gear would then perform a rotation about its axis of symmetry and at the same time a movement with the rotating planetary gear.

Runs the output axis parallel to the drive axis, it can be advantageously provided that the distance of the output shaft of the drive axle is adjustable. By using this setting, the desired overall movement of the tool can ultimately be adjusted when using the transmission device.

A further advantageous specific embodiment of the invention provides with respect to a rotatable about the output shaft output shaft advantageous that this output shaft is rotatably mounted in at least one output-bearing device which is pivotable about the first auxiliary axis. If the output element is designed as an output shaft, then this is usefully indirectly or directly driven by the planetary gear by means of another gear which is fixed on the output shaft, and the output shaft is rotatably mounted in a driven-bearing device. The storage of the output shaft can be accomplished advantageously by means of one or two bearings, which should be arranged on both sides of the position of the planetary gear along the output axis when using two bearings to optimally absorb the forces on the output shaft. The output bearing device advantageously has a fixed distance from the auxiliary axis and is pivotable about this on a circular path, so that upon pivoting of the output bearing device, the engagement between the planetary gear and a further arranged on the drive shaft gear is maintained. Depending on the pivot position of the output bearing device or the output axis relative to the auxiliary axis then moves both the auxiliary axis of the planetary gear and the output axis on each of a circular path about the drive axis during rotation of the planetary gear around the drive axis of the drive module. The pivot position of the output-bearing device to the first auxiliary axis should be advantageous fixed adjustable. It can then be freely selected and set and initially remains constant during operation.

In addition, it may be advantageously provided that the driven-bearing device by means of a rotatable about the first auxiliary axis pivot shaft mounted, in particular fixed to the pivot shaft. The output-bearing device can for example be fixedly connected to the rotatable pivot shaft, in particular integrally connected, or it can be provided in each case with the pivot shaft fixedly connected pivot arms, at their remote from the pivot shaft ends in each case the output bearing device or individual bearings of the output Bearing device are provided.

The planetary gear, for example, be rotatably mounted directly on the pivot shaft, but it can also be advantageously provided that the planetary gear is supported by a hollow shaft which surrounds the pivot axis and in particular a pivot shaft concentrically. The

Hollow shaft may in turn be rotatably mounted relative to the pivot shaft, but the planetary gear may in turn be rotatably mounted on the hollow shaft. If a pivot shaft is provided, then the hollow shaft surrounds the pivot shaft concentrically and can for example be mounted directly on the pivot shaft.

For adjustable adjustment of the pivot position of the output-bearing device can be advantageously provided that the output bearing device carries an adjusting toothing, by a fixed to the base gear, in particular by a mounted on the base Justier-worm or adjusting gear movable is. Thus, the driven-bearing device can be moved defined by means of the adjusting teeth relative to the base of the drive module, wherein the driven-bearing device moves forced on a circular path about the auxiliary axis, so that the engagement of the planetary gear with another, rotatable about the output shaft gear is permanently guaranteed.

To adjust the adjusting teeth, a gear, in particular a gear or worm wheel used, which in turn is rotatably mounted on the base and drives the adjusting teeth.

If an adjusting worm wheel or an adjusting gear is used to drive the adjusting toothing, which can be driven by means of a worm gear, then the worm gear on the one hand a self-winding ensures inhibition, so that the output bearing device remains fixed in the absence of external effects; On the other hand, an adjustment movement is reduced from the outside so far that an accurate adjustment of the pivot position of the output-bearing device is made possible.

An advantageous embodiment of the invention also provides specifically that the worm gear has a first spindle whose axis of rotation is parallel to the drive axis, wherein the first spindle is manually adjustable by means of bowl surfaces by twisting, and which carries a first worm, which with a rotatably mounted Justier -Zahnrad cooperates, wherein the adjusting gear is coupled to a second worm wheel on a second spindle, which cooperates with the adjusting teeth on the output bearing means. The first spindle has, for example, a screw slot, which the

Einsteilung allowed by means of a commercially available screwdriver, wherein upon rotation of the first spindle, the first worm wheel drives the adjusting gear, which is for example mounted on the same shaft, which also carries the second worm wheel, so that the second worm wheel rotates with reduced rotational speed and in turn drives the adjusting toothing on the output bearing device at a very low rotational speed.

In the following the invention will be shown with reference to an Ausführungsbeispieis in some drawings and explained below. It shows

Fig. 1 is a three-dimensional view of a portion of the transmission device, Fig. 2 is a three-dimensional view of a ring gear with a

Planetary gear and an output element,

3 is a plan view of the arrangement of Fig. 2, Fig. 4 is a plan view of an arrangement according to FIG. 2, wherein the

Angular position of the output element has been changed to the planetary gear, Fig. 5 is a schematic view of Verstellmöglichketten the

Output element / output bearing device,

Fig. 6 in a plan view, the adjusting device within a

Ring gear,

7 shows a first part of an adjusting device for the angular position of the output bearing device,

8 is a side view of the arrangement of FIG. 7,

9 is a first side view of the adjusting / Justiereinrtch- device with a pivot shaft and a hollow shaft, by means of which the planetary gear is mounted, Fig. 10 is a further side view of the arrangement of Fig. 9,

Fig. 11 shows a first part of the mounting of the adjusting device, the

Output bearing means and the planetary gear in a three-dimensional view,

Fig. 12 shows a second part of the mounting of the adjusting device, the

FIG. 13 an overview of the transmission device in a three-dimensional view, FIG.

Fig. 14 is an end view of the base with the output shaft and Fig. 15 is a view of a processing machine. FIG. 1 shows a number of parts of the transmission device which are particularly important for the function in a three-dimensional view, with the remaining parts initially being omitted in order to explain the basic mode of operation in a clear form.

The drive module of the transmission device initially has a base, which in turn has two fixed base plates 1, 2 which are each arranged on the front side at the two ends of the base. The first base plate 1 is rigidly connected to the second base plate 2 via elements not shown in FIG. The corresponding connecting elements may, for example, contain a cylindrical sleeve or a cage structure made of connecting rods between the first base plate 1 and the second base plate 2. Typically, the first base plate is rotatably driven directly by means of a motor, wherein a non-illustrated shaft stub can be coupled to the first base plate. This may for example also have a key surface for a positive connection with a drive coupling.

The two base plates 1, 2 are thus rotationally driven in rotation about a drive axis 3. All other parts shown in Fig. 1 with the exception of the stationary arranged ring gear 4 rotate with the base plates 1, 2. Instead of the base plates, the base may also other types of rigid body, such as grids or struts or rods consisting of bracing body have. There may also be more than two such

Be provided base plates or body, First, the planetary gear 5, which is rotatably mounted on a hollow shaft 6. The

Hollow shaft 6 is in turn rotatably mounted on the pivot shaft 7 about a first auxiliary axis 8.

The ring gear 4 has an internal toothing 4a, which is arranged concentrically about the drive axle 3, and the planetary gear 5 is arranged such that it constantly meshes with a rotation of the base about the drive shaft 3 with the internal toothing 4a. The planetary gear 5 can also be mounted directly on the Schenk shaft 7, for example in a rolling bearing, but this must be freely rotatable relative to. The illustrated first bearing device 9 includes a rolling bearing, which is constructed such that it fixes the hollow shaft 6 in the axial direction and ensures good rotatability of the hollow shaft relative to the pivot shaft 7.

With the pivot shaft 7, an output bearing device 10, 11 is fixedly connected, which is pivotable in total with the pivot shaft 7 about the pivot axis / first auxiliary axis 8. For this purpose, the output shaft bearing device has a first output bearing 10 and a second output bearing 11, in which an output shaft 12 is rotatably mounted about an output shaft (not shown in detail in FIG. 1).

With the output shaft 12, a driven gear / sun gear 13 is fixedly connected, which meshes with the planetary gear 5 and rotates in the course of rotation of the base both together with the planetary gear on a circular path about the drive shaft 3 and performs a rotation about the output axis. The sun gear / driven gear 13 is fixedly connected to the output shaft 12, so that with this outside the drive module, a tool for machining a workpiece can be coupled, this tool can then rotate on the one hand on its own axis and on the other hand also perform a movement on a circular path ,

The movement of the output shaft 12 or the output shaft 12a on a circular path is controllable by an adjusting device, as will be explained in more detail below.

On the second base plate 2, rotatably about a second auxiliary axis 14, a first spindle 15 is provided, which carries a first worm wheel 16. The first spindle 15 is rotatable from the end face of the second base plate 2 forth through an opening provided there by means of a key surface, for example by means of a screwdriver. The first worm wheel 16 is engaged with an adjusting gear 17, so that a worm gear is formed which greatly suppresses rotation of the first spindle 15. The Justierzahnrad 17 rotates about a third auxiliary axis 18 and is fixedly connected to a second worm wheel 19. The second worm wheel 19 in turn is engaged with a Justierverzahnung, with the Abtriebsiagereinrichtung 10, 11, and Although in particular with the part 11, is connected (not visible in Fig. 1, see reference numeral 22 in Fig. 8 and Fig. 14).

By a rotation of the first spindle 15 about the second auxiliary axis 14 so that the output bearing device 10, 11 about the pivot axis 8, d. H. the first auxiliary axle, swiveling. The effect of this pivoting will be explained in more detail below with reference to the following figures, in particular FIGS. 4 et seq. FIG. 2 shows, in a three-dimensional representation, first the ring gear 4 with the internal toothing 4a into which the planetary gearwheel 5 engages. The planetary gear 5 is fixedly connected to a hollow shaft 6, which in turn is rotatably mounted in the first bearing means 9 on the pivot shaft 7. The pivot shaft 7 is in turn mounted pivotally relative to the base plates 1, 2 in the context of an adjusting device / adjusting device (not shown in detail in FIG. 2).

Further, in Fig. 2, the sun gear or driven gear 13 is shown, which is fixedly connected to the rotatably mounted Abtriebswelie 12, wherein the output shaft 12 and thus the output shaft 12a at a fixed distance from the hollow shaft 6 and the pivot shaft 7 and pivotable about it is arranged.

Figure 3 shows a plan view of the ring gear 4 with the internal toothing 4a, on which the planetary gear 5 rotates on the circular path 20. The planetary gear 5 rotates about the first auxiliary axis 8, which is symbolically represented by a cross.

The sun gear or driven gear 13 is arranged relative to the first auxiliary axle 8 such that the output shaft, which in this case coincides with the rotational axis of the driven gear 13, coincides with the drive axle 3. The output gear 13 thus rotates upon rotation of the base only about its own axis and does not circulate in a circular path about the drive axis, but remains stationary. Figure 4 shows in a variant, another setting of the pivot position of the output gear 13 relative to the first auxiliary axis 8. By means of the pivot mechanism, the output bearing device and with this the output gear 13 is pivoted out of the drive shaft 3, and when circulating the planetary gear 5 on the circle 20 that runs Output gear 13 at the same time on the circle 21 about the drive shaft 3 around. In addition, the output gear 13 is driven by the Pianetenzahnrad 5 about its own axis, which coincides with the output axis.

This results in a movement of the output shaft 12, which corresponds to a rotation about the output axis and at the same time a circulation on a circular path 21. The diameter of the circular path 21 is adjustable by means of adjusting device / adjusting device shown in more detail below.

FIG. 5 shows a plan view of the pinion gear 5 and the FIG

Output gear 13, on which path 45, the output shaft 12 with the output gear 13 is pivotable about the center of the planetary gear 5 around. The sheet is designated 45 in FIG.

From Figure 6 shows in more detail how the pivot position of the output shaft 12 with respect to the first auxiliary axis 8 adjustable. In Fig. 6, the second Abtriebsiagereinrichtung 11 is shown, which has a solid composite body, for example, designed as a pivot arm, in which the pivot shaft 7 on the one hand and the output shaft 12 on the other hand are mounted at a fixed distance from each other. The solid body of the second output bearing device 11 is a total of about the first auxiliary axis 8 arcuately in the direction of the double arrow 45 pivotally. For this purpose, the second output bearing device 11 has an adjusting toothing 22 which engages with the second worm wheel 19. When the second worm wheel 19, which is coupled to the adjusting gear 17 on a common spindle, is rotated, the adjusting gear 22 is driven with reduction of the movement and the second driven bearing device 11 is pivoted about the first auxiliary axis 8.

The Justierzahnrad 17 can be driven for this purpose by a not shown in FIG. 8 first worm wheel 16, which in Fig. 1 is apparent. The first worm wheel 16 is driven by a key surface on a first spindle 15, which carries the first worm wheel. The key area is designated in FIG. 8 by 23 and can be actuated, for example, by means of a screwdriver.

In a drive of the base of the transmission device, the base plates rotate together with the output bearing device 10, 11 and the

Output shaft together around the drive axle, and with them the planetary gear runs on the teeth of the Hohirades, so that the

Output shaft 12 also rotates on a circular path depending on the setting of the adjusting device on the path indicated by the double arrow 45. The sun gear / driven gear simultaneously rotates about the output shaft of the output shaft 12.

FIG. 7 shows the first spindle 15 which drives the first worm wheel 16. The first worm wheel 16, whose worm drive is not shown in FIG. 7 for the sake of clarity, in turn drives the adjusting gear 17, which is arranged on a common shaft / second spindle with the second worm wheel 19. The second worm wheel 19 cooperates in the manner explained in connection with FIG. 6 with the adjusting toothing 22 of the second drive bearing device 11.

FIG. 8 shows a side view of the arrangement from FIG. 5, wherein the first spindle is designated by 15, the first worm wheel by 16 and the adjusting gear by 17.

In Figure 9, the Verstelieinrichtung / Justieretnrichtung is shown as a whole in a side view, the output shaft is denoted by 12 and as well as the pivot shaft 7 and the hollow shaft 6 passes through the ring gear 4, on the hollow shaft 6 is not shown in detail the planetary gear within mounted on the ring gear 4, as well as on the output shaft 12, the output gear 13 is rotatably mounted in the amount of the ring gear 4. The

Pivot shaft 7 is pivotally mounted in a first Justierlagereinrichtung 24 and in a second Justierlagereinrichtung 25. The hollow shaft 6 is rotatably mounted on the pivot shaft 7 in turn in two rolling bearings 9, 9a. As part of the adjusting device, the first output bearing device 10 and the second output bearing device 11 are connected to the pivot shaft 7 in such a way that the output bearing devices 10, 11 are pivotable about the first auxiliary axis 8, which coincides with the pivot axis of the pivot shaft 7.

The second output bearing device 11 is provided with a not shown in FIG. 9 Justierverzahnung which is driven by means of the second worm wheel 19, which is fixedly connected to the Justierzahnrad 17 on a common shaft. In addition, the first worm wheel 16 is shown, by means of which the Justierzahnrad 17 can be driven and which is mounted on the first spindle 15. The first spindle 15 carries at a front end a key surface 23, by means of which the pivot position of the output bearing devices 10, 11 from the outside of the second base plate 2 forth by means of a conventional tool, such as a screwdriver is adjustable. On the key surface or instead of the key surface 23 may also be provided a motor drive, which can also automatically adjust the pivot position. 9 shows the arrangement of FIG. 9 in a representation rotated by 180 ° about the drive axis, wherein the second worm wheel 19, which interacts with the adjusting toothing 22, can be seen in the foreground in front of the adjusting gearwheel 17. Incidentally, the same parts are provided with the same reference numerals 9, to illustrate the output bearing devices, the first output bearing device 10 has a bearing block 10a and a pivoting arm 10b and a fastening device 10c for fastening the pivoting arm 10b to the pivot shaft 7. In the same Way, the second output bearing device 11, a second bearing shell IIa and a pivot arm IIb and a fastening device 11c for attachment to the pivot axis 7.

FIG. 11 shows, in a three-dimensional representation, parts of the transmission device with a first base ring 26, which is fixedly connected to the first base plate 1 and to which the bearing device 24 for the pivot axis 7 is fastened. In addition, the mounted on the pivot axis 7 hollow shaft 6 is shown on which the planetary gear 5 within the internal teeth 4a of the ring gear 4th is rotatable. The rotary bearing 9 of the hollow shaft 6 is fixed to a second base ring 27, which is connected in a manner not shown with the first base ring 26, for example via a continuous part-cylindrical sleeve 28.

In FIG. 12, basically the same arrangement is shown as in FIG. 11, wherein a continuous sleeve 28 is shown in its entirety connecting the first base ring 26 to the second base ring 27, so that the insight into the interior of the base is different from that in FIG. 11 is locked. In the teilzylindri- see sleeve 28 must be released in any case in the form of at least one recess of the area in which the planetary gear 5 with the internal teeth 4a of the ring gear 4 is engaged.

Figure 13 shows an overview of the transmission device with the housing 29, through which a drive shaft 30 is performed. The drive shaft 30 is fixedly connected to the first base plate 1. Next, the partially cylindrical sleeve 28 is shown, which connects the first base plate 1 and a base ring 26 with the second base ring 27. Through an opening of the part-cylindrical sleeve 28, the pivotable shaft 7 and the planetary gear 5, which rotates in the ring gear 4, visible. Below the ring gear 4, a continuation of the partially cylindrical sleeve 28 with further base rings 31, 32 is shown, which are each connected to the partially cylindrical sleeve 28. The sleeve 28 then terminates on the second base plate 2. The base thus has a total of the one shown

Betspiel a substantially hollow cylindrical shape. The ring gear 4 is fixedly connected to the housing wall 33 of the housing 29. At the lower end in FIG. 13, the output shaft exits from the housing end face 34, which rotates on one side on its own and on the other hand is stationary depending on the setting of the adjusting device or rotates with the base on a circular path.

FIG. 14 shows, in an end view, the housing 29, viewed from the end face 34 of FIG. 13. It is to be pointed out in detail on the representation of the output shaft 12, which can move in an arcuate recess 2a of the second base plate 2, wherein the Base plate 2 rotates within the housing 29. The base plate 2 is shown in Fig. 14 semitransparent.

FIG. 15 schematically shows a processing machine 40 by means of which a workpiece 41 is to be machined. 42 designates a milling head which, in addition to a rotation about its axis of symmetry, should also execute a movement on a circular path. The milling head 42 is mounted for this purpose in a transmission device 43 and secured to the output shaft 44, which is movable in the same manner as the output shaft 12 described above. The transmission device 43 can be driven by means of a drive shaft 30.

The two superimposed movements of the tool 42 can prevent uneven premature wear and in particular a uniform symmetrical wear of the cutting surfaces can be ensured. The same applies if a erosion electrode is used as the tool 42.

Claims

claims

Transmission device with a about a drive axis (3) rotatably driven drive module,

wherein the drive module comprises a base (1, 2, 26, 27, 28, 31, 32) rotatable about the drive shaft (3) and a driven element (12, 13) rotatably mounted relative to the base about an output shaft (12a) for transmitting rotational movement has on a functional element,

wherein the base relative to a, in particular stationary, toothing (4a) is rotatable and relative to the base about a first auxiliary axis (8) rotatably mounted planetary gear (5) which rotates in the course of rotation of the base on a circular path (20) and is driven by meshing with the toothing (4a) and which cooperates directly or by means of one or more further gears with the driven element (12, 13).

Transmission device according to claim 1, characterized in that the planetary gear (5) directly or by means of one or more further gears an output gear (13) drives, which is connected to the output element, in particular about an output shaft (12a) rotating output shaft (12) ,

Transmission device according to claim 1 or 2, characterized in that the toothing (4a) is provided as an annular internal toothing on a ring gear (4), in particular on a stationary in the transmission device relative to the drive module fixed ring gear (4).

Transmission device according to claim 1, 2 or 3, characterized in that the drive module is at least partially disposed within the ring gear (4).

5. Getrtebeeinrichtung according to claim 1 or 2, characterized in that the toothing as an annular outer toothing on a Gear, in particular at one in the transmission device relative to the drive module fixedly fixed gear, is provided.

Transmission device according to claim 1 or one of the following, characterized in that the output shaft (12a) relative to the drive axis (3) radially offset and in particular during the rotation of the drive module relative to the drive axis (3) is movable.

Transmission device according to claim 1 or one of the following, characterized in that the output shaft (12a) parallel to the drive axis (3) and within the drive module radially in relation to the drive axle (3) is displaceable.

Transmission device according to claim 1 or one of the following, characterized in that the output shaft (12a) is fixed relative to the first auxiliary axis (8), in particular to this parallel and radially of this is arranged at a fixed distance.

Transmission device according to claim 1 or one of the following, characterized in that the output shaft (12a) parallel to the drive axis (3) and rotates relative to this at a fixed radial distance.

Transmission device according to claim 9, characterized in that the distance of the output shaft (12a) from the drive axle (3) is adjustable.

Transmission device according to claim 1 or one of the following, characterized in that about the output shaft (12a) rotatable output shaft (12) in at least one output-bearing device (11, 12) is rotatably mounted, which is pivotable about the first auxiliary axis (8) ,

Transmission device according to claim 11, characterized in that the pivot position of the output-bearing device (11, 12) about the first auxiliary axis is adjustable.

13. Transmission device according to claim 11 or 12, characterized in that the output-bearing device (s) (11, 12) by means of a order the first auxiliary axle (8) rotatable pivot shaft (7) pivotally mounted, in particular on the pivot shaft (7) is fixed / are.

Transmission device according to claim 1 or one of the following, characterized in that the planetary gear (5) by means of a hollow shaft (6) is mounted, which surrounds the pivot axis (8) and in particular a pivot shaft (7) concentrically.

Transmission device according to claim 11, 12, 13 or 14, characterized in that a driven-Lagerereinrtchtung (10, 11) carries a Justierzahnung (22) by a fixed to the base gear (16, 17, 19), in particular by a mounted on the base adjustment worm (19) or adjusting gear (17) is movable.

Transmission device according to claim 15, characterized in that the adjusting worm wheel (19) or adjusting gear (17) can be driven by a worm gear.

Transmission device according to claim 16, characterized in that the worm gear has a first spindle (15) whose axis of rotation is parallel to the drive axis (3), wherein the first spindle is manually adjustable by means of dish surfaces (23) by turning, and a first worm wheel ( 16), which cooperates with a rotatably mounted adjusting gear (17), wherein the adjusting gear is coupled to a second worm wheel (19) on a second spindle, with the adjusting teeth (22) on a driven-bearing device (10, 11) cooperates.