DE102010050612B4 - Rotary drive device - Google Patents

Abstract

A rotary drive device, comprising a device housing (7) on which a first output member (5) is rotatably mounted about its longitudinal axis (5a) to perform a tappable, rotary output movement (12) relative to the device housing (7) and in which Fluidkraft operable drive means (2) are arranged, which are rotatably connected to a about its longitudinal axis (4a) relative to the device housing (7) rotatable second output member (4) in turn with the first output member (5) for causing the output movement (12) is drivingly coupled, wherein the drive-like coupling between the second output member (4) and the first output member (5) a planetary gear (13) is present, a rotatably connected to the first output member (5) sun gear (47) and a ring gear ( 46) and that via a plurality, in each case both with the sun gear (47) and with the ring gear (46) in meshing engagement Plane tenräder (42) which are rotatably mounted at a radial distance from the longitudinal axis (4a) of the second output member (4) on a planet carrier (36), characterized in that the first output member as a driven plate (5) and the second output member as an output shaft ( 4), wherein the planet carrier rotatably (36) connected to the output shaft (4) and the ring gear (46) is fixedly arranged on the device housing (7).

Description

The invention relates to a rotary drive device, comprising a device housing, on which a first output member is rotatably mounted about its longitudinal axis in order to perform relative to the device housing a tappable, rotary output movement, and are arranged in the actuatable by fluid force drive means, with a to his Longitudinal axis relative to the device housing rotatable second output member are in rotary drive device, which in turn is drivingly coupled to the first output member for causing its output movement, wherein the drive-like coupling between the second output member and the first output member, a planetary gear is present, which rotatably with the first output member connected sun gear and a ring gear and which has a plurality of, each with both the sun gear and with the ring gear in meshing engagement planetary gears having the radial distance to Längsa Chse of the second output member are rotatably mounted on a planet carrier.

Such a rotary drive device is known from DE 42 22 525 A1 known. This has a second output member formed by a cylinder ring part, which initiates a driving force generated by drive means in a planetary gear, wherein the generated rotary output movement is tapped on a first output member forming output shaft. The planetary gear has a planet carrier formed directly from the device housing, wherein the ring gear is designed as part of a ring gear of the planetary gear and is rotatable relative to the device housing. The ring gear is attached to the cylinder ring part, which is drivable by fluid force to a rotational movement.

The AT 241 216 B describes a planetary gear with a special bearing of planetary gears on a planet carrier. Each planetary gear sits on an eccentric shaft, all eccentric shafts are coupled together via a lever mechanism.

One from the WO 2010/099868 A1 known rotary drive device has a device housing and a rotatable output unit in this regard consisting of an output shaft and an end plate arranged thereon output drive. The output unit can be driven by drive means to an oscillating rotational movement, wherein the drive means are actuated by fluid force and in particular consist of a so-called oscillating piston drive. At the output drive is a mounting interface for mounting an external component to be moved by means of the rotary drive device oscillating. The external component is, for example, a gripper, which serves to position workpieces in a certain way during the course of a production process.

A disadvantage of the known rotary drive device is that the tappable on the driven plate rotation angle is limited to a level substantially below 360 degrees. This is mainly due to the structure of the oscillating piston drive. Applications in which - for example, for the assembly of screw caps - rotational movements are required with several turns, thus can not be covered by the known rotary drive device.

From the EP 2 093 432 A1 is already known a rotary drive, which is equipped with a driven plate, which can be rotated in one and the same direction by more than 360 degrees. This is due to the present in this rotary drive drive means, which consist of two counteractivatable racks, which are in Verzahnungsabgriff with the output shaft. A disadvantage of this rotary drive, however, in the relatively large transverse dimensions perpendicular to the longitudinal and rotational axis of the output actuator.

From the DE 100 54 796 A1 is a device for the rotational angle adjustment of a shaft with respect to its drive known. In a device housing are drive means in the form of a rotary piston drive, wherein a pivot piston is integrally formed with an adjusting shaft which carries a sun gear of a planetary gear. The sun gear meshes with a plurality of planetary gears, which in turn are in meshing engagement with a ring gear arranged on the device housing. The planet gears are seated on a cover rotatably connected to an output shaft, so that during a pivotal movement of the rotary piston through the output shaft, a rotational movement is performed whose angle of rotation is less than the swept by the rotary piston pivot angle. As an alternative to the planetary gear proposes the DE 100 54 796 A1 an eccentric gear before.

It is the object of the present invention to provide a rotary drive connection of the type mentioned, in which a large rotation angle range can be tapped on the driven plate if necessary.

To solve this problem, the invention provides that the first output member is formed as a driven plate and the second output member as an output shaft, wherein the planet carrier rotatably connected to the output shaft and the Ring gear is fixedly arranged on the device housing.

By interposed in a special way between the output shaft and the driven plate planetary gear can be easily achieved a translation of the rotation angle in favor of a relation to the rotation angle of the output shaft grö-βeren rotation angle of the output actuator. Even if therefore the maximum possible rotation angle of the output shaft is limited, for example, by the nature of the co-operating with their drive means, can be realized on the output drive a relatively large angle of rotation and tap. With appropriate design of the diameter ratios of the various wheels of the planetary gear, the output drive can rotate more than 360 degrees unidirectionally, even if the output shaft can not perform a complete revolution. The rotary drive device is therefore particularly predestined for equipping with drive means which are realized in the form of a rotary piston drive, in which the great advantage is given that it has transversely to the longitudinal axis of the output shaft on extremely small dimensions. The rotary drive device can therefore be made extremely compact despite the extended range of applications.

Advantageous developments of the invention will become apparent from the dependent claims.

As already indicated, the drive means are expediently realized in the form of a rotary piston drive. Such a rotary piston drive includes at least one rotatably connected to the output shaft pivoting piston which is arranged in a cavity of the device housing and this cavity divided into at least two working chambers, which are controlled so acted upon by a drive fluid, that the pivot piston performs a pivotal movement and the particular coaxial with its pivot axis aligned output shaft entrains. Such a rotary drive device may in particular be designed so that the pivot axis of the rotary piston, the longitudinal axis of the output shaft and the longitudinal axis of the output actuator coincide. As a result, the rotary drive device has only small transverse dimensions.

The planet carrier may be a separate component with respect to the output shaft, which is attached by means of suitable fastening means to the output shaft. More advantageous, however, is a one-piece design of the planet carrier and output shaft, as this allows a simple production and favors the realization of a preferably coaxial alignment of output shaft and planet carrier.

The planet carrier is expediently disk-shaped, wherein it has in particular a circular outer contour. It can be designed in particular flange.

It is expedient if the driven plate is rotatably mounted on the device housing independently of the output shaft and the planet carrier. In this way mutual influences and over-determinations can be easily excluded.

In an advantageous embodiment, the device housing has on its outer side via a preferably coaxially arranged to the output shaft receiving recess, in which the driven plate is received with at least a portion of its axial height. The opening facing away from the housing of the receiving recess forms a mounting opening through which the driven plate during assembly of the rotary drive device can be inserted into the receiving recess. Radially outwardly, the driven plate is expediently enclosed by a limiting wall which is stationary with respect to the device housing and in particular formed directly by the device housing, which forms the side wall of the receiving recess. Concentrically between the driven plate and the boundary wall, a bearing assembly may be arranged, in particular equipped with a rolling bearing device, by which the driven plate is rotatably mounted with respect to the device housing and at the same time supported in the radial direction on all sides. Such a driven output actuator can withstand very high loads, which is avoided by the direct housing-side mounting of the output actuator that lateral forces caused by a arranged on the driven plate external component, adversely affect the upstream in the power flow drive components.

The driven plate is expediently mounted rotatably on the device housing. Thus, it can be easily removed to make the planetary gear available, for example, for maintenance purposes or to exchange components with the aim of changing the rotation angle ratio.

The driven plate can be fixed in particular by means of a bearing ring surrounding it at the edge.

The sun gear is expediently located on the axial surface of the output actuator facing the device housing. It would be conceivable an embodiment in which the sun gear is formed integrally with the driven plate. However, it is considered more convenient if the sun gear is one is separate component with respect to the output drive, so that an independent production is possible and in the case of wear of the sun gear while maintaining the output actuator replacement of this sun gear can be made. In an advantageous manner of attachment of the sun gear on the driven plate fastening means are provided which are effective between the driven plate and the sun gear. Such fasteners may include a plurality of the driven plate from axially outwardly axially passing through fixing screws, which are supported with their heads on the driven plate and which are screwed with their threaded shank in each case a threaded bore of the sun gear, so that the sun gear can be clamped axially with the driven plate.

In a separate embodiment of sun gear and driven plate, it is expedient if cooperating centering means are present at these two components, which ensure an exactly coaxial alignment in the attached state.

For the attachment of the planetary gears is that they are suitably arranged detachably on the planet carrier. They can therefore be easily replaced in case of wear, in particular even without removing the Planetenradträgers from the device housing. The accessibility for purposes of exchange can be ensured, for example, by the output drive and the sun gear being detachably mounted in such a way that they can be removed from the device housing, so that the planetary gears are easily accessible from the outside.

It is advantageous if the planet carrier for releasably fixing the planet wheels for each planet gear has an individual receiving structure. Such a receiving structure may for example have the form of a cylindrical projection or a receiving bore. It is advantageous in any case if the receiving structures are designed for plug-fastening of the planetary gears. During disassembly, the planetary gears can thus be easily deducted from the planet carrier and during assembly, they can, depending on the configuration of the receiving structures, plugged onto the planet carrier or plugged into the planet carrier.

A particularly pronounced variability in terms of possible applications has a rotary drive device, in which the planet carrier is equipped with several groups of receiving structures for planetary gears, these groups of receiving structures are alternatively usable for equipping with planetary gears in particular different diameters. The receiving structures belonging to the same group are expediently in each case on a circular line which is designated as a reference circle and coaxial with the longitudinal axis of the output actuator. At least two groups of receiving structures lie on mutually concentric pitch circles of different diameters. If the rotational angle ratio of the rotary drive device to be changed, only one other than the previously used group of receiving structures with planetary gears of a different diameter to equip, so that further the meshing engagement is ensured with the ring gear. The sun gear is replaced accordingly, for which purpose sun gears with different diameters are available.

Finally, it is also advantageous if the rotary drive device is equipped with a Drehwinkeleinstelleinrichtung, which is easily accessible, in particular from the outside, to specify or limit the maximum achievable by the output shaft angle of rotation as desired.

• 1 eine bevorzugte Bauform der erfindungsgemäßen Drehantriebsvorrichtung in einer perspektivischen Vorderansicht,
• 2 die Drehantriebsvorrichtung aus 1 in einer perspektivischen Rückansicht, wobei insbesondere auch eine vorzugsweise vorhandene Drehwinkeleinstelleinrichtung ersichtlich ist,
• 3 eine Explosionsdarstellung der in 1 und 2 abgebildeten Drehantriebsvorrichtung,
• 4 die Drehantriebsvorrichtung gemäß 1 bis 3 aus einem mit 1 vergleichbaren Blickwinkel, wobei allerdings der vordere Bereich des Vorrichtungsgehäuses aufgebrochen und der Abtriebsteller sowie das Sonnenrad in einem Teilschnitt dargestellt sind, so dass ein guter Einblick in das Planetengetriebe möglich ist,
• 5 die Drehantriebsvorrichtung in perspektivischer Darstellung im Längsschnitt und im vorderen Bereich teilweise aufgeschnitten,
• 6 eine perspektivische Vorderansicht der Drehantriebsvorrichtung aus einem verglichen mit 1 etwas anderen Blickwinkel, das Ganze in einem winkeligen Längsschnitt und in einem abgestuften Schnitt durch den vorderen Gehäusebereich einschließlich des Abtriebstellers, des Sonnenrades und der Planetenräder, und
• 7 eine Vorderansicht der Drehantriebsvorrichtung mit axialer Blickrichtung auf den Abtriebsteller, wobei der Abtriebsteller hälftig weggeschnitten dargestellt ist, so dass ein Einblick in die Komponenten des Planetengetriebes möglich ist.

The invention will be explained in more detail with reference to the accompanying drawings. In this show:

• 1 a preferred design of the rotary drive device according to the invention in a perspective front view,
• 2 the rotary drive device 1 in a perspective rear view, wherein in particular a preferably present Drehwinkeleinstelleinrichtung is visible,
• 3 an exploded view of in 1 and 2 pictured rotary drive device,
• 4 the rotary drive device according to 1 to 3 from one with 1 comparable view angle, however, wherein the front portion of the device housing broken and the driven plate and the sun gear are shown in a partial section, so that a good view of the planetary gear is possible,
• 5 the rotary drive device in a perspective view in longitudinal section and partially cut open in the front region,
• 6 a front perspective view of the rotary drive device of a compared with 1 a different angle, the whole in an angular longitudinal section and in a stepped section through the front housing area including the output plate, the sun gear and the planet gears, and
• 7 a front view of the rotary drive device with an axial line of sight on the Output actuator, wherein the driven plate is shown half cut away, so that an insight into the components of the planetary gear is possible.

The in their entirety with reference numeral 1 designated rotary drive device has a device housing 7 , which extends along a dash-dotted line indicated major axis 9 extends, being about in the axial direction of the main axis 9 oppositely oriented end faces, the below for better distinction as the front 9a and back 9b be designated.

On the device housing 7 is in the area of the front 9a a driven plate 5 rotatably arranged. The driven plate 5 has a longitudinal axis 5a that with the main axis 9 coincides and at the same time the axis of rotation of the output actuator 5 Are defined.

The driven plate 5 is preferably designed disc-shaped and has at its from the device housing 7 axially groundbreaking outer surface 10 at least one mounting interface 6 on, with their help on the driven plate 5 a not further shown, to a rotary or pivoting movement drivable external component of any kind in a preferably releasable manner can be fixed. The mounting interface 6 consists of an example of a plurality of arranged in a suitable pattern arranged mounting holes. The said external component may be, for example, a gripping device, for example a suction gripper or a jaw gripper, with the aid of which an object to be repositioned can temporarily be gripped and held.

Inside the device housing 7 are fluid power operable drive means 2 through which the output actuator 5 to an indicated by a double arrow oscillating, rotary output motion 12 around the longitudinal axis 5a let drive. The output movement 12 is from the at the output drive 5 attached external component removed or tapped.

The drive means 2 act indirectly with the output drive 5 together. On the one hand are the drive means 2 with one in the device housing 7 extending output shaft 4 in rotary drive connection. On the other hand, the output shaft 4 in turn with the driven plate 5 drivingly coupled. The drive coupling is done with the help of a between the output shaft 4 and the output drive 5 intermediate planetary gear 13 realized.

The output shaft 4 is preferably coaxial with the driven plate 5 arranged. It has a longitudinal axis 4a , which also represents its axis of rotation. The output shaft 4 extends through a housing bore 14 through, being in this housing bore 14 with axial distance from each other two the output shaft 4 concentrically enclosing storage units 15a . 15b are arranged through which the output shaft 4 while ensuring the described rotational degree of freedom in the radial and preferably also in the axial direction with respect to the device housing 7 is supported.

The output shaft 4 closes with an axial distance that passes through the intermediate planetary gear 13 is conditional, to the axial outer surface 10 opposite back or axial inner surface 11 of the output actuator 5 at. It passes through the device housing 7 suitably so completely that they have a rear end portion 16 in the area of the back 9b from the device housing 7 protrudes. There it cooperates with an optionally available rotation angle adjustment device 17 whose structure and mode of operation will be explained later.

The device housing 7 has a housing wall 8th coming from the housing bore 14 is interspersed, with the housing bore 14 in the area of the front 9a to one to the front 9a open recording well 18 extended. The forward-oriented opening of the receiving recess 18 is hereafter as a mounting hole 22 designated; through this mounting hole 22 through can at not yet used driven plate 5 the output shaft 4 into the housing bore 14 be plugged in.

The driven plate 5 is located at least a part of its axial height in the interior of the receiving recess 18 , He too can through the mounting hole 22 into the device housing 7 used and removed if necessary.

By the drive means 2 can the output shaft 4 to an oscillating about their acting as a rotation axis longitudinal axis 4a rotating and by a double arrow 23 indicated rotational movement to be driven. The drive means 2 are advantageously of fluid-actuated type and allow the generation of a high drive torque. By way of example, they are in the form of a compact-build and in spite of its compactness for generating high drive torque suitable oscillating piston drive 3 realized.

To the oscillating piston drive 3 heard in the interior of the device housing trained and at an axial distance in particular coaxial with the receiving recess 18 arranged cavity 24 from the output shaft 4 is interspersed. in the Interior of the cavity 24 is a rotationally fixed to the output shaft 4 connected rotary piston 25 standing with a graduation wall 26 the cavity 24 in two each along a portion of the circumference of the output shaft 4 extending working chambers 27a . 27b divided. Preferably, the cavity has 24 a circular cross section and is from the output shaft 4 coaxially interspersed, so that there is an annular space, which in this annulus locally a the end wall 26 forming subdivision body 26a is used stationary under sealing. The swinging piston 25 has at least one radial with respect to the output shaft 4 protruding wing section 25a , which under seal on the wall of the cavity 24 slides along when the output shaft 4 is twisted. The maximum angle of rotation of the output shaft 4 is thereby by the acting as a stop wall 26 predetermined in the pivoting of the wing section 25a lies.

In each of the working chambers 27a . 27b opens one of two suitable for fluid control control channels 28a . 28b , the other end with connection openings to the outer surface of the device housing 7 and through each working chamber 27a . 27b controlled by a drive fluid can be acted upon. Compressed air is particularly suitable as the drive fluid, although any other gaseous or liquid medium would also be usable.

By coordinated fluid loading of the two working chambers 27a . 27b can the swinging piston 25 to an oscillating pivotal movement about one with the longitudinal axis 4a coincident pivot axis are driven. Due to the non-rotatable connection with the output shaft 4 this has the already mentioned oscillating rotary motion 23 the output shaft 4 result.

The maximum possible swivel angle of the swivel piston 25 and therefore also the maximum possible rotation angle of the output shaft 4 depends on the angular extent of the end wall 26 from. As an example, the maximum tilt angle is about 270 degrees. Accordingly, the output shaft 4 only be rotated by a maximum of 270 degrees.

With the help of Drehwinkeleinstelleinrichtung 17 can be any working rotation angle range of the output shaft 4 variably set within the above-mentioned maximum angle of rotation. In this way, it can be achieved, for example, that the rotational angle of the output shaft passed over during the oscillating rotary movement 4 any angle below the maximum possible 270 degrees. The adjustment of the working rotation angle range is from outside the device case 7 possible.

The Drehwinkeleinstelleinrichtung 17 preferably includes a rotationally fixed to the rear end portion 16 the output shaft 4 attached and radially from the output shaft 4 widening stop arm 32 , which when turning the output shaft 4 around its longitudinal axis 4a is pivoted. In the swing path of this stop arm 32 There are two on the device housing 7 releasably fixable counter stops 33a . 33b running along a on the device housing 7 trained circular arc guide 34 in the pivoting direction of the stop arm 32 are infinitely displaceable and can be clamped. For clamping, they are each with a clamping screw 35 fitted. Every counter-attack 33a . 33b defines one of the two endpoints of the desired working rotation angle range. The rotational movement 23 the output shaft 4 stops each time when the stop arm 32 on one of the counter-attacks 33a . 33b incident.

The rotational movement of the output shaft 4 is through the already mentioned planetary gear 13 in the context of a translation in favor of an increased angle of rotation on the driven plate 5 transfer. In this way it can be achieved that the driven plate 5 despite the fact that the output shaft 4 can not make a full turn, can be driven at least to a full turn or preferably to more than a full turn. For example, can be achieved in this way that the driven plate 5 at a rotation angle of the output shaft 4 of about 270 degrees, a rotation angle of 720 degrees sweeps. This information is to be understood as an example. By design of the planetary gear 13 can be realized virtually any gear ratio.

Although a large angular transmission is at the expense of the output drive 5 tappable torque. In particular, the oscillating piston drive 3 however, is able to provide a very high output torque, the output drive can 5 always provide a sufficiently high output torque available.

The direction of rotation of the output actuator 5 is expediently always the same as the instantaneous direction of rotation of the output shaft 4 ,

While in the embodiment of the rotary piston 25 and the output shaft 4 are separate components, an embodiment would be possible in which these two components are integrally formed with each other. In the separate design, the rotational drive can be particularly easily realized that the output shaft 4 outside, like in particular 3 it can be seen, at least in the area of the cavity 24 has a spline, in which a complementary internal toothing of a bearing bush of the oscillating piston 25 positively engages, with the swing piston 25 on the output shaft 4 is plugged.

The planetary gear 13 contains one preferably in the interior of the receiving recess 18 arranged planet carrier 36 , which rotates with the output shaft 4 connected is. The planet carrier 36 is preferably disc-shaped, with its main plane of extension perpendicular to the longitudinal axis 4a runs. Preferably, it has a circular outer contour whose diameter is smaller than the inner diameter of the receiving recess 18 so that between him and one the receiving recess 18 peripherally enclosing boundary wall 37 an annular gap 38 remains. The boundary wall 37 is preferably a part of the housing wall 8th ,

The planet carrier 36 is at the output drive 5 facing front end side of the output shaft 4 appropriate. Preferably, it is integral with the output shaft 4 educated. In any case, he makes the rotational movement of the output shaft 4 immediately with.

Exemplary has the planetary gear 13 over three planetary gears installed at the same time 42 at equal angular intervals around the center of the planet carrier 36 are arranged distributed around, each with a radial distance from the longitudinal axis 4a the output shaft 4 are arranged. More precisely, the planetary gears 42 positioned so that their at the same time defining the axes of rotation longitudinal axes 42a with radial distance to the longitudinal axis 4a and in this case parallel to this longitudinal axis 4a are arranged.

The planet wheels 42 are the planet carrier 36 at the output shaft 4 upstream in front. They are expediently in one and the same, to the longitudinal axis 4a right-angled plane.

Every planetary gears 42 is designed as a gear and has an external toothing.

For storage of planetary gears 42 has the planet carrier 36 per planetary gear 42 about an individual recording structure 43 , These recording structures 43 are in particular for releasably fixing the planet gears 42 educated. By way of example, each recording structure 43 from an axially in the driven plate 5 extending bore leading to the downforce plate 5 facing front surface 44 of the planet carrier 36 are open.

Every planetary gear 42 has a storage structure 45 which is designed bolt-like in the embodiment and in a receiving structure 43 is preferably releasably applicable. The pairs of reception structures 43 and storage structures 45 are particularly designed so that they can be joined together in the context of a mating process. By the bolt-like bearing structure 45 in the recording structure 43 is rotatable, can be any planetary gear 42 around its longitudinal axis 42a to be twisted. Should a planetary gear 42 can be replaced, it can easily from the assigned recording structure 43 be pulled out.

The above-described embodiment of the receiving structures 43 and storage structures 45 Although is particularly advantageous, but can also be realized in other ways. It would be conceivable, for example, as a recording structure 43 to provide a threaded hole into which a trained as a threaded bolt bearing structure is screwed, wherein the bearing structure 45 then as a bearing means for rotatably receiving the associated planetary gear 42 serves. Anyway, it is beneficial if the planetary gears 42 detachable on the planet carrier 36 are fixed so that they can be easily replaced in case of wear and can be easily removed for a further explained below purpose.

In the axial direction of the output shaft 4 at the same height as the planet wheels 42 is also to the planetary gear 13 belonging ring gear 46 in relation to the device housing 7 arranged fixed fixed manner. It consists in particular of an annular body with a circumferential internal toothing. The ring gear 46 is coaxial with the longitudinal axis 4a aligned and is conveniently in the receiving recess 18 placed. In selbige it may for example be pressed non-rotatably. Out 4 is clearly visible, as in the recording 18 seated ring gear 46 from the boundary wall 37 is enclosed radially on the outside.

The diameter of the planet wheels 42 is chosen so that every installed planetary gear 42 with the ring gear 46 is in meshing engagement. Consequently, the planet wheels are running 42 with its external toothing on the internal toothing of the ring gear 46 off when the planet carrier 36 together with the output shaft 4 is rotated and the planetary gears thus about the longitudinal axis 4a circulate.

As another component, the planetary gear 13 a coaxial to the longitudinal axis 4a aligned sun gear 47 on. The sun wheel 47 engages with a circular cylindrical, on the outer circumference a circumferential toothing having toothing section 48 between the planetary gears 42 a, wherein the tooth diameter of the sun gear 47 is chosen such that its toothing section 48 simultaneously with each of the planet gears 42 is in meshing engagement.

When the planet carrier 36 performs a rotational movement, in this case practice on the ring gear 46 running planet wheels 42 due to its gearing engagement with the one smaller gearing diameter than the ring gear 46 having sun gear 47 a drive torque on the sun gear 47 and call for a rotational movement of the sun gear 47 around the longitudinal axis 4a out. The direction of rotation is the same as that of the output shaft 4 , However, the rotational speed of the sun gear is 47 larger than that of the output shaft 4 , and also results in comparison to the output shaft 4 larger angle of rotation of the sun gear 47 ,

The sun wheel 47 transfers its rotary motion directly to the driven pulley 5 where it is fixed coaxially and rotationally fixed. In the embodiment, the sun gear 47 with the output drive 5 screwed. Particularly advantageous is a detachable connection, so that the sun gear 47 if necessary from the output drive 5 can be removed and replaced. However, it would be possible in principle, the sun 47 and the output drive 5 integrally form with each other.

The sun wheel 47 sits like the planet wheels 42 in an axial space between the planet carrier 36 and the output plate further axially outboard 5 , As the driven plate 5 the mounting hole 22 covers, it also acts as a covering for the planetary gear 13 , which is well encapsulated by the environment and the problem of external contamination is greatly minimized.

The sun wheel 47 sits at the device housing 7 facing axial inner surface 11 of the output actuator 5 , It is in the embodiment of this axial inner surface 11 set in coaxial alignment and by fasteners 53 in a preferably detachable manner on the driven plate 5 fixed.

Exemplary include the fasteners 53 several fixing screws 53a , which from axially outside in axially through mounting holes 54 of the output actuator 5 are plugged in, so they are the output drive 5 succeed. The sun wheel 47 points with the mounting holes 54 axially aligned threaded holes 55 on, in which the fixing screws 53a are screwed with their threaded shank. Each fixing screw 53a Has a screw head, located on the axial outer surface 18 of the output actuator 5 supported, the screw heads expediently completely sunk axially in the drive plate 5 are included.

The fasteners 53 thus allow axial distortion of the sun gear 47 with the output drive 5 ,

It is advantageous if the sun gear 47 and on the output drive 5 matching centering 56 There is a mutual location centering between sun gear 47 and driven plates 5 cause. By way of example, the centering means exist 56 from one on the axial inner surface 52 of the output actuator 5 trained centering recess 56a and a complementary centering projection 56b of the sun wheel 57 , The centering projection 56b is suitably integral with the toothing section 48 connected and preferably also has the threaded holes already mentioned 55 on. It engages radially centered in the center in the driven plate 5 trained centering projection 56b one.

The driven plate 5 is suitably independent of the output shaft 4 and the planet carrier 36 on the device housing 7 rotatably mounted. For its rotary bearing is expediently an annular bearing assembly 57 present concentrically in between the outer periphery of the output actuator 5 and the inner periphery of the boundary wall 37 existing annulus within the receiving cavity 18 is incorporated. Through the bearing assembly 57 is the output drive 5 both radially and axially with respect to the device housing 7 supported, but has the necessary rotational freedom to perform its rotary output movement 12 ,

The bearing assembly 57 expediently contains a rolling bearing device 58 comprising a plurality of rolling elements, which on the one hand on at least one of the device housing 7 arranged tread and on the other hand on at least one of the output plate 5 support arranged tread.

Preferably, the driven plate 5 at the same time also removable on the device housing by the measures taken to its pivot bearing 7 stored. By way of example, this is done with the help of a concentric on the driven plate 5 screwed bearing ring 59 , where the bearing assembly 57 axially between this bearing ring 59 and an annular radial projection 63 is incorporated. By screwing on the bearing ring 59 on the driven plate 5 becomes the bearing assembly 57 axially compressed and at the same time radially braced, so that the driven plate 5 safe in the receiving cavity 18 is held. An additionally attachable sealing ring 64 covers one annular joint between the bearing ring 59 and the boundary wall 37 so that impurities are prevented from entering.

From the above explanations it is clear that an oscillating rotational movement 23 the output shaft 4 a likewise oscillating output movement 12 of the output actuator 5 entails. The angle of rotation and the rotational speed of the output movement 12 depends on the design of the planetary gear 13 from. If one assumes that the ring gear 46 always remains unchanged, thus allows the rotational speed ratio and angular displacement by selecting a corresponding dimensioning of the planetary gears 42 and the sun wheel 47 specify as required.

In this connection, there is the rotary drive device 1 of the embodiment, the advantageous possibility for a simple change of the gear ratio. The gear ratio can be realized that only the planetary gears 42 and the sun wheel 47 be replaced by differently dimensioned gears. The ring gear 46 can remain in place, leaving one and the same ring gear 46 is used regardless of the selected gear ratio.

Earlier it was already mentioned that the planet carrier 36 several recording structures 43 for equipping with the planet wheels 42 having. To now provide the opportunity for a simple change of gear ratio, are on the planet carrier 36 several groups of reception structures 43 . 43b . 43c available, the alternative for equipping with planetary gears 42 Different diameters are available.

For example, the above-mentioned receiving structures form 43 a first group of host structures 43 all in even distribution on one to the longitudinal axis 4a concentric first circle 65 are arranged. A group of second receptions 43b is again with the same distribution on a to the first circle 65 concentric second pitch circle 66 , whose diameter is smaller than that of the first pitch circle 65 , Exemplary is still a third group of third recording wells 43c present, which are placed on a newly reduced in diameter third circle, concentric to the first and second pitch circle 65 . 66 is arranged. The embodiment is thus with a total of three groups of receiving structures 43 . 43b . 43c fitted.

To the rotary drive device 1 now belong except in the embodiment in the receiving structures 43 the first group mounted planetary gears 42 even more planetary gear sets, which are currently not mounted and the respective more planetary gears 68 respectively. 69 included, wherein the gear diameter of belonging to different planetary gear planetary gears 42 . 68 . 69 differ from each other. While the planetary gears mounted in the embodiment 42 belong to a first planetary gear, has the rotary drive device 1 of the embodiment also still a set of second planet gears 68 and another set of third planetary gears 69 , The second planet wheels 68 have a larger diameter than the currently installed planet gears 42 and the third planetary gears 69 have the largest gear diameter of the existing planet wheels.

By simply replacing it is thus possible, optionally in the form shown, the planetary gears 42 in the reception structures 43 of the first circle 65 to install, or belonging to the second wheel set second planetary gears 68 in the second recording wells 43b to assemble, or belonging to the third set of third planetary gears 69 in the third recording wells 43c to assemble. The toothing diameters of the planetary gears are selected so that the planetary gears in the mounted state in each case with the internal toothing of the ring gear 43 comb.

To the rotary drive device 1 then there are also several sun gears 47 . 70 . 71 their toothing section 48 have different diameters, so they each with one of the existing wheelsets of planetary gears 42 . 68 . 69 can be combined. The larger the gearing diameter of the planet gears used, the smaller the gearing diameter of the sun gear to be installed.

In 7 are planet gears 68 . 69 of the second and third planetary gear sets as well as the second and third sun gears tuned thereto 70 . 71 indicated in dotted and dashed form.

To change the gear ratio, is exemplary after previous release of the bearing ring 59 the driven plate 5 from the recording cavity 18 taken so that on the one hand the sun gear attached to it 47 and on the other hand, on the planet carrier 36 fixed planet wheels 42 are accessible. Now only the planetary gears are left 42 through the second or third planet gears 68 . 69 by substituting them for the reception structures provided for them 43b or 43b be mounted, and it is the existing sun gear 47 through the second or third sun gear 70 . 71 to replace its gearing diameter on those of the newly installed planetary gears 68 or 69 is tuned.

The number of existing groups of receiving structures for planetary gears is basically arbitrary. Conveniently, at least two such groups of receiving structures are present, which are located on mutually concentric pitch circles of different diameters.

Claims (16)

A rotary drive device, comprising a device housing (7) on which a first output member (5) is rotatably mounted about its longitudinal axis (5a) to perform a tappable, rotary output movement (12) relative to the device housing (7) and in which Fluidkraft operable drive means (2) are arranged, which with a about its longitudinal axis (4a) relative to the device housing (7) rotatable second output member (4) are in rotary drive connection, in turn with the first output member (5) for causing the output movement (12) is drivingly coupled, wherein the drive-like coupling between the second output member (4) and the first output member (5) a planetary gear (13) is present, the rotatably connected to the first output member (5) sun gear (47) and a ring gear ( 46) and that via a plurality, in each case both with the sun gear (47) and with the ring gear (46) in meshing engagement Plane tenräder (42) which are rotatably mounted at a radial distance from the longitudinal axis (4a) of the second output member (4) on a planet carrier (36), characterized in that the first output member as a driven plate (5) and the second output member as the output shaft ( 4), wherein the planet carrier rotatably (36) connected to the output shaft (4) and the ring gear (46) is fixedly arranged on the device housing (7). Rotary drive device according to Claim 1 , characterized in that the actuatable by fluid force drive means (2) are formed by a rotary piston drive (3) having at least one rotatably connected to the output shaft (4) and by controlled fluid loading to a reciprocating pivotal movement driven rotary piston (25) which is arranged in a cavity (24) of the device housing (7) and subdivides this cavity (24) into at least two working chambers (27a, 27b) which can be acted upon in a controlled manner in each case by a drive fluid. Rotary drive device according to Claim 1 or 2 , characterized in that the planet carrier (36) integrally connected to the output shaft (4) and / or arranged on an end face of the output shaft (4). Rotary drive device according to one of Claims 1 to 3 , characterized in that the planet carrier (36) is disc-shaped and expediently has a circular outer contour. Rotary drive device according to one of Claims 1 to 4 , characterized in that the driven plate (5) is rotatably mounted on the device housing (7) independently of the output shaft (4) and the planet carrier (36). Rotary drive device according to one of Claims 1 to 5 , characterized in that the driven plate (5) with at least a part of its axial height in one of the device housing (7) defined and an end mounting opening (22) for the driven plate (5) having receiving recess (18) are arranged, wherein the driven plate (5) radially on the outside of a housing-side boundary wall (37) is enclosed and concentrically between the driven plate (5) and the boundary wall (37) expediently for rotatable, radial support of the output actuator (5) serving bearing assembly (57) is arranged, the expediently has a rolling bearing device (58). Rotary drive device according to one of Claims 1 to 6 , characterized in that the driven plate (5) is detachably mounted on the device housing (7) rotatably, in particular by means of a bearing ring (59) enclosing it concentrically. Rotary drive device according to one of Claims 1 to 7 , characterized in that the sun gear (47) on the device housing (7) facing the axial inner surface (52) of the output actuator (5) is arranged. Rotary drive device according to one of Claims 1 to 8th , characterized in that the sun gear (47) is releasably secured to the driven plate (5). Rotary drive device according to Claim 9 , characterized in that the sun gear (47) to the device housing (7) facing the axial inner surface (52) of the output actuator (5) attached and by fastening means (53) releasably fixed to the driven plate (5), wherein the fastening means (53 ) expediently a plurality of the driven plate (5) from axially outwardly axially passing through fastening screws (53 a), which are screwed into threaded bores (55) of the sun gear (47). Rotary drive device according to Claim 9 or 10 , characterized in that on the sun gear (47) and the driven plate (5) mating centering means (56) are provided for mutual centering in juxtaposed state. Rotary drive device according to one of Claims 1 to 11 , characterized in that the planet gears (42) are releasably arranged on the planet carrier (36). Rotary drive device according to one of Claims 1 to 12 , characterized in that the planet carrier (36) for releasably fixing the planetary gears (42) for each planetary gear (42) has an individual receiving structure, in particular a receiving bore, wherein the receiving structures (43) expediently for fixing the planet gears (42) by means of a plugging operation are formed. Rotary drive device according to Claim 13 , characterized in that the planet carrier (36) is equipped with a plurality of groups of receiving structures (43, 43b, 43c) which are alternatively usable for equipping with planetary gears (42, 68, 69) of different diameters and which are expediently mounted on mutually concentric partial circles ( 65, 66, 67) are different gear diameter, wherein the sun gear (47) for adaptation to the gear diameter of the currently installed planet gears (42) is interchangeable. Rotary drive device according to Claim 14 characterized in that it comprises a plurality of planetary gear sets of planetary gears (42, 68, 69), the gear diameters of planetary gears (42, 68, 69) belonging to different planetary gear sets differing from each other and having a plurality of sun gears (47) of different diameters wherein the rotary drive device (1) is alternatively equipped with different planetary gear sets and the respectively matching sun gear (47) to vary the effective between the output shaft (4) and the driven plate (5) rotation angle ratio. Rotary drive device according to one of Claims 1 to 15 , characterized in that it has a Drehwinkeleinstelleinrichtung (17) for adjusting the maximum output of the output shaft (4) work rotation angle range.

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