EP0990489A2 - Power driven screwdriver - Google Patents

Abstract

The screw driver includes first entrainment elements (42) on a drive wheel (40) interacting with the second entrainment elements (47) on the cam ring (45) for force-locking transfer. A setting device (20) allows axial displacement of the tool drive shaft so that in a first position the two entrainment elements are positively locked and in a second position they disengage whilst the coupling elements (41, 46) provided on the drive wheel and cam ring come into engagement. The coupling elements and entrainment elements can be mounted on facing sides of the drive wheel

Description

• eine Gehäuse,
• eine im Gehäuse drehbar gelagerte axial verschiebbare Werkzeugantriebswelle, die an einem ersten Ende im Gehäuse gelagert ist und an ihrem zweiten Ende eine Aufnahme für ein Werkzeug aufweist,
• eine auf der Werkzeugantriebswelle drehbar gelagertes und motorisch angetriebenes Antriebsrad, das gehäuseseitig gegen ein axiales Verschieben gesichert ist,
• einen Nockenring, der auf der Werkzeugantriebswelle axial festgelegt und gegen Axialverschiebungen nach außen gesichert ist,
• ein Federelement, um die Werkzeugantriebswelle nach außen in Richtung auf die Aufnahme vorzuspannen,
• erste Kupplungselemente am Antriebsrad,
• zweite Kupplungselemente am Nockenring, die mit den ersten Kupplungselementen zusammenwirken, um eine drehmomentabhängige Auslösekupplung zu bilden und
• eine Stelleinrichtung zur axialen Verstellung der Werkzeugantriebswelle.

The invention relates to a power-operated screwdriver, comprising:

• a housing,
• an axially displaceable tool drive shaft rotatably mounted in the housing, which is mounted at a first end in the housing and has a receptacle for a tool at its second end,
• a motor-driven drive wheel which is rotatably mounted on the tool drive shaft and is secured on the housing side against axial displacement,
• a cam ring which is fixed axially on the tool drive shaft and secured against axial displacement to the outside,
• a spring element to bias the tool drive shaft outward towards the receptacle,
• first coupling elements on the drive wheel,
• second clutch elements on the cam ring, which cooperate with the first clutch elements to form a torque-dependent release clutch and
• an adjusting device for the axial adjustment of the tool drive shaft.

Such screwdriver with an adjustable, torque-dependent Shut-off clutch, which usually cooperate with each other Have cam elements with oblique flanks have been Years in use.

An example of such a screwdriver is given below the screwdriver sold under the designation "ASse639" (cf. Complete catalog of the applicant "Fein high-performance power tools 1995/96, pages 78, 79, 224).

In some cases it is desirable to use the torque-dependent shut-off clutch to be deactivated here, for example if the screwdriver is to be used for drilling. This is it known the two coupling elements, the cams with oblique Have flanks to brace against each other, so that a torque-dependent triggering is avoided. In this One speaks of the so-called "rigid drive through".

The disadvantage of such an embodiment is that very strong axial forces occur due to the inclined cams, which must be taken up by the storage.

Various solutions are known in the prior art, around an input shaft and an output shaft rigidly with each other to couple (see US-A-5 016 501, US-A-3 243 023 and EP-A-0 792 723), however, are such coupling mechanisms complicated structure and for use in a simple Screwdriver with torque-dependent release clutch (single claw clutch) hardly suitable.

The invention is therefore based on the object of an improved Specify screwdriver, with a simple means Torque-dependent clutch deactivated can be so that a rigid drive is achieved.

According to the invention, this object is achieved in a screwdriver of the type mentioned in that first entrainment elements are provided on the drive wheel, with second driving elements on the cam wheel for positive power transmission cooperate, and that the actuator is an axial Adjustment of the tool drive shaft such that in a first position, the first and second driver elements are positively engaged with each other, and that in one second position the driver elements are disengaged while the coupling elements are in engagement with one another.

The object of the invention is completely achieved in this way.

By using additional driving elements on the drive wheel and there is a positive power transmission on the cam ring from the drive wheel to the cam ring and thus to the Tool drive shaft in a simple manner, being used for conversion the already existing adjusting device for the axial Adjustment of the tool drive shaft is used so that in a first position, the driving elements on the drive wheel and are positively engaged with each other on the cam ring and in a second, axially displaced position of the tool drive shaft only the coupling elements in engagement with each other are so that the trigger clutch trigger depending on the torque can.

In this way it becomes a particularly reliable option to switch between torque-dependent shutdown and rigid through drive achieved with simple means, the Disadvantages of the prior art, such as high axial forces, be avoided.

According to a further embodiment of the invention, the coupling elements and the entrainment elements on the facing Arranged sides of the drive wheel.

This results in a particularly simple structure.

According to an advantageous development of the invention Coupling elements disengaged in the first position.

This measure ensures that when hiring the screwdriver to the first position (rigid drive) the coupling elements are disengaged and therefore none Can exert more axial forces. This simplifies the structure and relieves the storage.

In an additional development of the invention, the coupling elements designed as cam elements with oblique flanks.

This results in a particularly simple structure of the interacting coupling elements. In an alternative However, it would also be conceivable, for example curved ones Driving flanks on a coupling half to be provided with suitable driving elements, e.g. a straight pin on the interact with the other coupling half.

In an additional development of the invention, the entrainment elements as claw elements with straight, to the axis of rotation axially parallel flanks.

In this way, the driving elements are of a particularly simple construction guaranteed.

According to a further embodiment of the invention, at least two, preferably three first coupling elements in uniform Angular distances from each other arranged on the drive wheel, and at least two, preferably three first entrainment elements at equal angular intervals to each other on the drive wheel arranged, which are each arranged and shaped accordingly second coupling elements and driving elements on the cam ring are assigned, with the first and second entrainment elements each extend over a central angle, which is larger than the central angle over which the Extend coupling elements.

In this way it is ensured with simple means that in the first position (rigid through drive) the coupling elements are out of function and therefore do not exert any axial forces can. At the same time it is achieved that the first and second Driving elements in the second position (torque-dependent Shutdown) are out of function.

In this version, the first and second coupling elements preferably constructed so that they are seen in the axial direction have a greater height than the height of the first and second driving elements.

In an additional development of this embodiment, the coupling elements concentric on one with the entrainment elements arranged outwardly offset circle, preferably each a coupling element following a driving element in a radial direction externally offset position is assigned.

Through these measures, a particularly stable structure of the Coupling elements and driving elements enables and a Generous design of the coupling elements enables, as this higher forces due to the radially outward position can transmit. It is also achieved that minimal wear and tear appear in continuous operation.

According to a further feature of the invention, the actuating device comprises an adjusting sleeve, which is in the housing via a thread Is guided axially adjustable, with the adjusting sleeve a locking ring is axially displaceable and secured against rotation is fixed, which is rotatable relative to the housing and locked in different angular positions is.

In this way, the triggering torque can be adjusted the torque-dependent triggering clutch in simple Achieve this and combine it with an appropriate adjustment, to ensure the rigid through drive.

In an additional development of the invention is a thrust bearing provided to support the drive wheel, which has a compliant Element, preferably supported on the housing via an O-ring is.

This measure has the advantage that a possibly at Transition between the first and second positions of the tool drive shaft tendency especially when starting for jamming due to the flexible bearing of the drive wheel is avoided and at the same time some damping for the case is reached that an adjustment during operation of the collar. In this way there are signs of wear by adjusting the adjusting ring during operation significantly reduced.

It is understood that the above and those below Features of the invention to be explained not only in the specified combination, but also in others Combinations or alone can be used without the Leave the scope of the invention.

Fig. 1

einen Teil-Längsschnitt durch einen erfindungsgemäßen Schrauber;

Fig. 2

eine Aufsicht des Nockenrings gemäß Fig. 1 in vergrößerter Darstellung und

Fig. 3

einen Schnitt durch den Nockenring gemäß Fig. 2 längs der Linie III-III.

Further features and advantages of the invention result from the following description of a preferred exemplary embodiment with reference to the drawing. Show it:

Fig. 1

a partial longitudinal section through a screwdriver according to the invention;

Fig. 2

a plan view of the cam ring of FIG. 1 in an enlarged view and

Fig. 3

a section through the cam ring of FIG. 2 along the line III-III.

In Fig. 1, a screwdriver according to the invention is overall with the Number 10 denotes.

The screwdriver 10 comprises a housing 11 in which an electric motor (not shown) is received, which via a gear 51st a meshing drive wheel 40 drives. Other parts of the gear thus formed are not shown. The drive wheel 40 is freely rotatably mounted on a tool drive shaft 30, at its first end 37 by means of a radial bearing 58 is mounted in the housing 11 and 38 at its second end Holder 26 for a tool 24, e.g. a screwdriver bit having.

A cam ring 45 is fixed on the tool drive shaft 30, which is positively connected to it. Between the Cam ring 45 and the drive wheel 40 is a total with the Number 50 designated trigger clutch formed. This release clutch 50 has first coupling elements 41 on one of the cam rings 45 facing side of the drive wheel 40, the second Coupling elements 46 on a drive wheel 40 facing Side of the cam ring 45 are assigned.

Is also between the cam ring 45 and the drive wheel 40 a spring element 43 arranged in the form of a spiral compression spring, through which the cam ring 45 and thus also the tool drive shaft 30, which together with the cam ring 45 axially is slidably arranged in an outward direction, that is towards the receptacle 26, is acted upon.

The torque from the drive wheel 40 can thus be closed Release clutch 50 from the drive wheel 40 via the cam ring 45 are transferred to the tool drive shaft 30 in order to Drive tool 24.

The coupling elements 41 and 46 on the drive wheel 40 and on the cam ring 45 are cam elements with flat, sloping flanks formed, the shape of which is still based on FIGS. 2 and 3 is explained in more detail.

The cam ring 45 lies on a tool-side shoulder 53 of the Tool drive shaft 30 and is on the side of the drive wheel 40 secured by a locking ring 48. To a form-fitting Power transmission from the cam ring 45 to the tool drive shaft To ensure 30, the cam ring 45 has a Central recess 49 on two opposite one another Pages with flats 49 is provided with corresponding Flattenings on the tool drive shaft 30 a Form fit.

By means of an actuating device designated overall by the number 20 can the tool drive shaft 30 together with the Cam ring 45 axially adjusted in the direction of the drive wheel 40 so the overlap between the oblique Flanks of the coupling elements 41, 46 to change.

In conjunction with the biasing force by the spring element 43 depending on the overlap set between the clutch elements 41, 46 a torque-dependent triggering torque for the release clutch 50, which also from the Contact pressure when pressing the screwdriver 10 with the tool 24 is influenced.

The actuating device 20 for adjusting the tool drive shaft 30 towards the drive wheel 40 comprises a Tool drive shaft 30 surrounding adjusting sleeve 13, the the housing 11 connected axially adjustable via a thread 12 is. On an outer area of the adjusting sleeve 13 is a sleeve 16 pressed on, which thus rotatably with the adjusting sleeve 13 and is axially immovably connected.

By now a rotation of the adjusting sleeve 13 and thus an axial To allow adjustment of the tool drive shaft 30 is an externally encompassable locking ring 14 is provided which on the Sleeve 16 is axially displaceable. The locking ring 14 is between an axial guide 17 in the form of a spline the sleeve 16 and the locking ring 14 axially displaceable, however guided against rotation on the sleeve 16. Here is the Locking ring 14 by a coil spring 18 which is between a paragraph 21 of the sleeve 16 and a shoulder 22 of the locking ring 14 in a cavity is enclosed, towards the drive wheel 40 biased. The locking ring has at the housing end 14 a plurality of locking cams that only with the number 15 are indicated in the corresponding locking cams engage the housing 11.

The locking ring 14 can thus against the tension of the coil spring 18 are pulled outwards together with the tool drive shaft 30 are rotated and then in a different angular position be locked.

Overall, the actuating device 20 thus permits axial adjustment the tool drive shaft 30 and fuse in different, given axial positions.

The tool drive shaft 30 is by means of a fixed bearing 34 stored, which is enclosed between discs 33 and 35 and by means of a locking ring 36 on the adjusting sleeve 13 is installed. A puncture is provided on the adjusting sleeve 13, so that between the tool drive shaft 30 and the Adjusting sleeve 13, a cavity 55 is formed, the tool side through a shoulder 31 and on the housing side through the disk 33 is limited. Within this cavity 55 is a locking ring 32 set on the tool drive shaft 30. The axial Adjustment range of the tool drive shaft 30 in the direction of the drive wheel 40 is thus by the stop of the locking ring 32 limited to the disc 33. In the opposite Direction is the axial adjustment range of the tool drive shaft 30 limited by a locking ring 39 which on the Adjusting sleeve 13 is fixed and on the housing side on a paragraph 57 strikes.

The tool drive shaft is in the position shown in FIG. 1 in the maximum outward position, caused by the stop of the adjusting ring 39 on the shoulder 57 of the housing 11 is limited. The result is a minimal one Covering the flanks of the first and second coupling elements 41, 46 on the drive wheel 40 and on the cam ring 45 and thus a minimum triggering torque of the trigger clutch 50.

According to the invention, in addition to the coupling elements 41, 46 first drive elements 42 on the drive wheel 40 and on the cam ring 45 second driving elements 47 are provided, which are in the form and size are coordinated. With these take-away elements 42 and 47 are claws with straight, parallel flanks.

The shape and arrangement of the coupling elements and driving elements will now be explained in more detail with reference to FIGS. 2 and 3.

2 and 3, the cam ring 45 is in supervision and shown enlarged in section along the line III-III. On an additional illustration of the drive wheel 40 on which the corresponding first coupling elements 41 and first driving elements 42 are provided, since these are complementary to the second coupling elements 46 and second driving elements 47 are formed on the cam ring 45.

From the supervision according to FIG. 2 it can be seen that three second coupling elements 46 and three second driving elements 47 on the surface of the cam ring 45 by angles of each 120 ° offset from each other. The second are Coupling elements 46 arranged outside, while the second driver elements 47 in the same angular position, however are arranged offset radially inwards. The second coupling elements 46 are designed as cam elements with flat, sloping flanks 60 executed. Against this are the second Driving elements 47 as claw elements with flat, in the axial direction running flanks 62 executed. The second coupling elements 46 extend over a central angle α, which is smaller than the center angle β, over which the second entrainment elements 47 extend.

From Fig. 3 it can be seen that the coupling elements 46, seen from the surface of the cam ring 45, have a height h ₁ , which is greater than the correspondingly measured height h _{2 of} the driving elements 47.

This configuration enables the tool drive shaft 30 by means of the actuating device 20 in one area Set so that only the coupling elements 41 and 46 with the sloping flanks are effective when the screwdriver is in Is taken into operation and the tool drive shaft 30 through Muscle strength with their tool 24 against the action of the spring element 43 is pressed so that the coupling elements 41, 46 engage.

Depending on the set axial position of the tool drive shaft 30 results in either a large coverage of the sloping flanks of the coupling elements 41 and 46 and thus a large trigger moment or - as shown in Fig. 1 Position - a slight overlap between the sloping flanks of the coupling elements 41 and 45 so that a low trigger torque results.

Now the tool drive shaft 30 by means of the actuator 20 adjusted so far in the direction of the drive wheel 40, that the driving elements 42 and 47 on the drive wheel 40 and Cam ring 45 engage positively with one another, so the coupling elements 41 and 46 are inoperative, and it the rigid through drive is reached. Through the straight, in Flanks of the driving elements 42 or 47 there are no axial forces. Since the driving elements 47 on the cam ring 45 and also the complementary ones Driving elements 42 on the drive wheel 40 over a larger one Center angle β extend as the coupling elements 41 and 46 are the coupling elements 41 in this position or 46 completely out of function.

The drive wheel 40 is via an axial bearing 52 and one behind it arranged bushing 56 with an elastic in between Element 54 in the form of an O-ring supported on the housing side.

This slightly flexible mounting of the drive wheel 40 can, in unfavorable cases, not be completely excluded Clamping tendency between the coupling elements 41 and 46 is reduced or avoided. Although an adjustment of the actuator 20 never take place while working such adjustments can also be made during operation be tolerated by the resilient storage. Also if a change from torque-dependent triggering to the rigid through drive while the machine is at a standstill by turning the locking ring 14, so get the driving elements 42 and 47 only when switching on of the screwdriver 10 in engagement. This also creates Bumps are absorbed by the flexible storage.

Claims (11)

Power driven screwdriver, comprising: a housing (11), a tool drive shaft (30) rotatably mounted and axially displaceable in the housing (11), which is mounted at a first end in the housing (11) and has a receptacle (26) for a tool (24) at its second end, a motor-driven drive wheel (40) which is rotatably mounted on the tool drive shaft (30) and is secured on the housing side against axial displacement, a cam ring (45) which is axially fixed on the tool drive shaft (30) and secured against axial displacements to the outside, a spring element (43) for biasing the tool drive shaft (30) outwards towards the receptacle, first coupling elements (41) on the drive wheel (40), second clutch elements (46) on the cam ring (45), which cooperate with the first clutch elements (41) to form a torque-dependent trigger clutch (50) and an adjusting device (20) for the axial adjustment of the tool drive shaft (30),
characterized in that first entrainment elements (42) are provided on the drive wheel (40), which interact with second (47) entrainment elements on the cam ring (45) to form a positive force transmission, and that the adjusting device (20) permits axial adjustment of the tool drive shaft (30) in such a way that in a first position the first and second driver elements (42, 47) are positively engaged with one another, and in a second position the driver elements (42, 47) are disengaged while the coupling elements (41, 46) are in engagement with one another. Screwdriver according to claim 1, characterized in that the Coupling elements (41, 46) and the driving elements (42, 47) on the facing sides of the drive wheel (40) are arranged. Screwdriver according to claim 1 or 2, characterized in that the coupling elements (41, 46) in the first position are disengaged. Screwdriver according to claim 1, 2 or 3, characterized in that the coupling elements (41, 46) as cam elements are formed with inclined flanks (60). Screwdriver according to one of the preceding claims, characterized characterized in that the driving elements (42, 47) as Claw elements with straight axles parallel to the axis of rotation (19) Flanks (62) are formed. Screwdriver according to one of claims 3 to 5, characterized in that that at least two, preferably three first Coupling elements (41) at regular angular intervals are arranged to each other on the drive wheel (40) that at least two, preferably three first entrainment elements (42) at equal angular intervals to each other on the Drive wheel (40) are arranged, each of which corresponds arranged and shaped second coupling elements (46) and driving elements (47) on the cam ring (45) are, and that the first and second entrainment elements (42, 47) each over a central angle (β), which is greater than the central angle (α), over which the coupling elements (41, 46) extend. Screwdriver according to claim 6, characterized in that the first and second coupling elements (41, 46) seen in the axial direction have a greater height (h ₁ ) than the height (h ₂ ) of the first and second driving elements (42, 47). Screwdriver according to claim 6 or 7, characterized in that the coupling elements (41, 46) on one of the driving elements (42, 47) concentrically move outwards Circle are arranged. Screwdriver according to claim 6, 7 or 8, characterized in that that each have a coupling element (41, 46) a driving element (42, 47) in a radially outward position assigned. Screwdriver according to one of the preceding claims, characterized characterized in that the adjusting device (20) is an adjusting sleeve (13) comprises on the housing (11) via a thread (12) is guided adjustable in the axial direction, and that at the adjusting sleeve (13) a locking ring (14) axially displaceable and against this is fixed against rotation, the rotatable relative to the housing (11) and in different Angular positions is locked. Screwdriver according to one of the preceding claims, characterized characterized in that an axial bearing (52) for supporting the Drive wheel (40) is provided, which has a resilient Element (54), preferably via an O-ring on the housing (11) is supported.

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