Title of Invention | COUPLING DEVICE WITH TENSIONING BODIES |
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Abstract | The invention relates to a coupling device for establishing a couplable connection between two rotationally mounted machine parts, particularly a first shaft (2) and a second shaft (13). To this end, shaft (13) comprises a coupling ring (1) that, on the inside, has tensioning bodies (3), which act against each another in pairs and which are arranged so they surround the shaft (2). |
Full Text | Clutch device with sprags DESCRIPTION The invention refers to a clutch device for the couplable connection of a first shaft and a second shaft. Clutches are known in a number of embodiments, and are described in technical literature, above all in machine element textbooks and clutch- and transmission atlases. The object of the invention is to interconnect two rotatably mounted machine parts. The clutch according to the invention, which is effective in both rotational directions, is a cone clutch with sprags, as are known from reverse locks, and freewheel- or override clutches, and are used as coupling elements. With sprags as coupling elements, the machine parts to be coupled can be coupled steplessly to one another in any optional rotational position. The characteristic of a positive clutch can be imparted to the torque transmission, since, depending upon the cone angle, with self-locking, the clutch can be constructed torsionally fixed, up to the breakage of the sprags or their surrounding parts. With suitable matching of the cone angle and the axial shift force, a safety clutch can also be created, which begins to slip upon the exceeding of a predetermined maximum torque. The invention is described in more detail with reference to exemplary embodiments in the drawing figures. In the drawings: Fig. 1 a, b show sectioned views A-A of a clutch according to Fig. 2, Fig. 1 c shows an enlarged view of Fig. 2, Fig. 2 shows a first embodiment' of a clutch, Fig. 3 shows a further embodiment of a clutch with sliding sleeve, Fig. 4 shows a further embodiment of a duplex clutch with sliding sleeve, Fig. 5 shows a further embodiment of a double clutch with sliding sleeve. The component parts of the clutch are shown in Fig. 1 . The clutch comprises the outer clutch ring 1, the shaft 2, and the sprags 3 installed radially in between, which in an encircling cage 4 which is known per se from freewheels, are retained in recesses 5, which are distributed evenly on the periphery of the cage 4, and, by a spring element 6, are in spragging readiness. The sprags 3, in the described case, have, in the middle, inclined slots 7 for the holding of the encircling spring element 6 used in this embodiment, known per se from freewheels, which is supported on the right-hand edge 8 of the slots 7, and presses radially on the sprags 3 with the adjusting force FA. The force application point for FA does not lie in the connecting lines 9, between the outer and inner contact point of the sprags 3 with the associated clamping faces 10 and 11, so that, in each case, a torque M ensues, which rolls the sprags 3 into spragging readiness. The sprags 3 are in pairs opposite one another, and are held in spragging readiness so that neither a right- nor a left-hand rotation of the clutch components 1 and 2 in relation to one another is possible. Fig. la and lb show an installed position of the sprags, rotated by 18 0°, and a spring element 6 with a larger diameter (Fig. la), and also a spring element 6 with a smaller diameter (Fig. lb). In Fig. la, with the clutch open, the sprags 3 are pressed against the clamping face 11 of the shaft 2 , with this being the appropriate embodiment if the shaft 2 is in the decoupled state. In Fig. lb, the sprags 3 are retained in the clutch ring 1, and make this embodiment universally usable. Fig. lc shows that the clamping faces 10 and 11 are exactly parallel, and form an angle a of from 0 to about 10° in relation to the rotational axis. The radial spacing in the clamping faces 10 and 11 is equal to the maximum sprag height, minus the required radial roll-in travel of the inner and outer engagement curves of the sprags 3. A stop 12 prevents the sprag cage 4 from axially sliding out. The coupling and decoupling of the two machine parts of the outer clutch ring 1 and the shaft 2, takes place by displacement axially in relation to one another by the amount s. The amount s must be large enough until the sprag engagement curve comes out of contact with one of the clamping faces 10 or 11. If L is this necessary clearance, then the amount s must be s ≥ L/sina. L consists of the radial roll-in travel of the sprags 3, and the desired clearance between untensioned sprags 3 and clamping face. The selection of the cone angle a is of vital significance for the shift performance of the clutch. The two pieces of operating data, axial shift force and shift travel, are in a reciprocal relationship to one another. In the general application case, the clutch is designed so that the axial shift force Fa is sufficient to overcome the adjusting force FA of the springs on the sprags 3, and to ensure there is a contact force FK between engagement curve and clamping faces. FK counteracts the adjusting forces FA of the two clamping faces in relation to one another, and, in the first instance, depends upon the angle a. The clutch, in general, is designed so that the clutch is self-locking, which is achieved with the current material pairing of steel on steel, with a coefficient of static friction of about µ = 0.1 and, therefore, tan a Since, in operation, the sprags mutually spread apart a little further during shock-like transmission of the rotational movement, the holding release force, with a In the Figs. 2-4,the clutches show the coupled state in the upper half of the illustration, and the decoupled state in the lower half of the illustration. In Fig. 5, the clutch shows the decoupled state in the upper half of the illustration, and the coupled state in the lower half of the illustration. The simplest embodiment of a shaft clutch is shown in Fig. 2. The sprag ring 3, with the inner-lying spring element 6, is held in the shaft 13 by the outer clutch ring, and, by the stop 12, is prevented from falling out. The shaft 13 is brought into clamping contact with the shaft 14, by the amount S, by axial telescoping, and, by this, is coupled torsionally fixed. The axial distance S is dimensioned so that the clamping contact is neutralized with the drawing apart of the two shafts 13 and 14, and a small clearance L ensues. In Fig. 3, the two shafts 13 and 14 are immovable in relation to one another, and the coupling action is carried out by the sprags 3, by means of the sliding sleeve 15. The sliding sleeve 15 is operated externally in a known manner, and is axially movably mounted on the shaft 13 with positive locking. The other shaft 14 carries the mating clamping face 11. The possibility of coupling two rotating machine parts by their end faces, in a small installation space, is demonstrated in Fig. 4. The sliding sleeve 16, on the clutch side, has an outer- and inner cone with the same cone angle a, and is rotatably mounted on the shift component 17, which carries out the shift travel S mechanically, hydraulically, pneumatically, or electrically operated. The two sprag rings 3 and 3' are supported on the clamping faces 10 and 11 of the sliding sleeve 16, once by the outer spring element, and once by the inner spring element 6 and 6'. The sliding sleeve 16 does not rotate in the decoupled position (lower half of the illustration). Fig. 5 shows the arrangement and embodiment of the clutch if two different drives 20 and 21 in a narrow space are to be steplessly and smoothly connected, in turn, to a driven shaft 22. In this case, the sliding sleeve 18, which is mounted movably but torsionally fixed, for example, in a wedge connection on the drive shaft 22, has a double cone 19, and 19', on the outside, and the driving machine parts 20 and 21 each have an inner cone, in which a sprag ring 3 and 3' is retained in each case. The sliding sleeve 18 is axially moved by a shift rod 23, exemplarily shown here, which is guided in the shaft 22, and is rigidly connected to the sliding sleeve 18 by the plate 24. In the end positions of the shift rod 23, the corresponding drive component 20 or 21 respectively is coupled to, and driven by, the shaft 22. The shift rod 2 3 makes an overall axial movement of S, wherein at S/2 (middle position), the two clutch connections are disengaged, so providing the neutral position without a drive for the driving elements 2 0 and 21. With this, the shift rod 23 has altogether three shift positions. The shift movement can also be initiated in the sliding sleeve 18 externally, with increased spacing of the drive elements 20 and 21. The clutch device can comprise one or more sprag rings 3, which are in a row, one behind the other, on the same inner- and outer cone (not illustrated). List of designations 1 Clutch ring 2 Shaft 3 Sprag 4 Cage 5 Recess 6 Spring element 7 Slot 8 Edge 9 Connecting line 10 Clamping face 11 Clamping face 12 Stop 13 Shaft 14 Shaft 15 Sliding sleeve 16 Sliding sleeve 17 Shift component 18 Sliding sleeve 19 Double cone 2 0 Drive component 21 Drive component 22 Shaft 23 Shift rod 24 Plate Patent claims 1. A clutch device for the coup1able connection of two rotatably mounted machine parts, especially a first shaft (2) and a second shaft (13), characterized in that the shaft (13) has a clutch ring (1), which on the inside has sprags (3), acting against each other in pairs respectively, which are installed on the shaft (2) in an encircling manner. 2. The clutch device as claimed in claim 1, characterized in that the sprags (3) are accommodated in recesses (5) of a cage (4) . 3. The clutch device as claimed in claim 1 or 2, characterized in that the sprags (3) are accommodated in a spring ring (6). 4. The clutch device as claimed in claim 3, characterized in that the spring ring (6) is formed as a helical spring ring. 5. The clutch device as claimed in one of the preceding claims, characterized in that an axially movable sliding sleeve (15), for the axial displacement of the sprags (3) , is provided on one shaft (2,13) . 6. The clutch device as claimed in one of the preceding claims, characterized in that an axially movable sliding sleeve (16), with sprags (3) attached on the outer- and inner side, is provided on one shaft (2,13). 7. The clutch device as claimed in one of the preceding claims, characterized in that an axially movable sliding sleeve (18) is provided, which has a double cone (19,19') on the outer side, and an inner cone on the inner side. Dated this 28 day of September 2006 |
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3594-CHENP-2006 EXAMINATION REPORT REPLY RECEIVED. 04-07-2012.pdf
3594-CHENP-2006 POWER OF ATTORNEY 04-07-2012.pdf
3594-CHENP-2006 AMENDED CLAIMS 04-07-2012.pdf
3594-CHENP-2006 CORRESPONDENCE OTHERS 31-10-2011.pdf
3594-CHENP-2006 FORM-3 04-07-2012.pdf
3594-CHENP-2006 OTHER PATENT DOCUMENT 04-07-2012.pdf
3594-chenp-2006-correspondnece-others.pdf
3594-chenp-2006-description(complete).pdf
Patent Number | 253508 | ||||||||
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Indian Patent Application Number | 3594/CHENP/2006 | ||||||||
PG Journal Number | 31/2012 | ||||||||
Publication Date | 03-Aug-2012 | ||||||||
Grant Date | 26-Jul-2012 | ||||||||
Date of Filing | 28-Sep-2006 | ||||||||
Name of Patentee | PAUL MULLER GmbH & CO. KG UNTERNEHMENS- BETEILIGUNGEN | ||||||||
Applicant Address | AUSSERE BAYREUTHER STRASSE 230 , 90411 NURNBERG | ||||||||
Inventors:
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PCT International Classification Number | F16D 7/02 | ||||||||
PCT International Application Number | PCT/DE05/00513 | ||||||||
PCT International Filing date | 2005-03-18 | ||||||||
PCT Conventions:
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