DE102004007372A1 - Torque limiting screwdriver has a pair of clutch plates pressed apart against spring pressure when torque is applied - Google Patents

Abstract

A simple torque limiter for a screwdriver or similar tool has a torque limiting clutch comprising two clutch plates (36, 18) which are coupled together for normal torques and which are pressed apart with increasing torque. One clutch plate (36) is pressed against a spring element (20) which is not tensioned when no torque is applied and which provides a controlled support for the clutch up to clutch release. The movable clutch plate is located inside tool handle and the other clutch plate is rotationally connected to the tool holder.

Description

The The invention relates to a screwing tool according to the preamble of the claim 1.

at Screwing tools will torque the screwing of one Drive body, e.g. a handle transferred to a tool shank with a working end with the part to be turned, e.g. a screw engages. That of the drive body transferable to the tool shank Torque can be limited by a clutch that when exceeded a predetermined limit torque disengages the drive. hereby can e.g. the tightening torque of a screw are limited, and a damage to prevent the thread.

Such a screwing with torque limiter is for example from the DE 101 43 181 A1 known. In this screwing the torque limiter is housed in an axial handle. The torque limiting is effected by a clutch in which balls are held under the pressure of a coil spring in engagement with a drive element and an output member. The coil spring is constantly under a bias, which defines the limit torque. The dimensioning of the coil spring and the coupling elements is opposed to a realization of high limit torques.

Of the Invention is based on the object, a screwing with torque limiter for disposal to provide, which in a compact design and high limit torques allows.

These The object is achieved by a screwing tool with the features of claim 1.

advantageous versions The invention are specified in the subclaims.

at the screwing tool according to the invention The clutch is driven by a drive pulley and a driven pulley formed, which axially engage with each other to a torque-locked connection between the drive body and the tool shank. The drive pulley and the The driven pulley are held in axial engagement by a bending spring. The spiral spring is fixed with at least one end in the drive body and stops with a free bending area the drive pulley and the driven pulley engaged. If the specified limit torque is exceeded, so the drive pulley and the driven pulley are axially against the elastic bending force of the spiral spring from its torque-locking engagement disengaged.

The Using a spiral spring offers the advantage of being a very advanced one Range of spring forces for the definition be exploited the limit torque can. In particular, it is possible also very high spring forces realize that engage the clutch and the limit torque determine. Even high limit torques can be achieved with small dimensions the bending spring can be achieved.

The Biegefeder can be arranged so that they are not deformed elastically is and is not under a bending stress when the drive pulley and the driven pulley are in torque-locking engagement. Just when the transmitted torque approaches the limit torque, the bending area of the bending spring is elastic from its rest position deflected. If the screwing tool is not used, it stands Biegefeder therefore not under an elastic bias. When not using the screwing therefore no material fatigue occurs Bending spring on, leading to a change the elastic characteristic and thus to influence the setting lead the limit torque could.

The Screwing tool can preferably be designed as Handschraubwerkzeug be. The drive body is formed by the handle of the screwing tool. Preferably the handle is designed as a cross-grip, which is a substantial expansion of the drive body having serving handle perpendicular to the axis of the tool shank. In this version the bending spring can be designed in particular as an elongated bending rod be, which extends perpendicular to the axis of the tool shank. An elongated bending bar enables the choice of material and the rod cross-section the realization of a wide range of spring forces, which determine the limit torque. In particular, too very high spring forces and so that a high limit torque can be achieved.

The Training of the spiral spring as an elongated bending rod additionally offers the Possibility to in the drive body fixed length of the bending rod and thus the length to change its free bending range. This allows the spring force of the Bending range and thus the limit torque can be changed adjustable.

If the drive body is designed as a transverse grip, then the bending rod is preferably arranged symmetrically to the axis of the tool shaft and fixed at both ends. The deflectable bending region is formed by the axially central region of the bending rod. An adjustment of the limit torque is preferably effected by changing the clamping length of the bending rod at its two ends, so that the bending region always remains symmetrical to the axis of the tool shank. In this embodiment can be changed by changing the clamping length over which the two ends of the bending rod, the spring force of the bending region and thus the limit torque in a very wide adjustment range.

The Drive pulley and the driven pulley are preferably as a flat or conical circular disks formed in the manner of a toothed coupling axially meshed with a crown gear to the torque to effect. The term "crown gearing" is intended to mean each Toothing include, in which tooth back and tooth bottom substantially run radially independently from the shape of the tooth profile. It is essential only that the gearing each with rotation in the screwing direction with rising tooth flanks engages. Is a torque from the drive pulley on transmit the driven pulley, so will over the rising tooth flanks generates an axial release force against the elastic bending force of the spiral spring acts. Exceeds this release force the specified restoring force the spiral spring, so come the gears of drive pulley and Output disc axially except Engaging and the drive coupling between the drive body and tool shank is interrupted.

From this is apparent that except the spring force of the spiral spring and the flank angle of the toothing the limit torque determined. This gives the extra Possibility, the screwing tool with different limit torques in the two Forming directions of rotation by the teeth with different Flank angles is formed in the two directions of rotation. at a screwdriver, for example, in the screw one flatter flank angle can be selected as in unwinding direction. The limit torque for screwing in and tightening The screw is thus smaller than the torque, which for Unscrewing the screw can be applied. A screw is therefore screwed in with a predetermined limit torque while a greater torque can be applied to a possibly stuck screw solve and unscrewed. In extreme cases, the crown gearing can also be sawtooth have, which only one obliquely Rising tooth flank, while the other tooth flank runs perpendicular to the disk plane. Only in the oblique Rising tooth flank corresponding direction of rotation becomes an axial disengaging generated. Only in this direction of rotation is the transmissible torque limited, while transmit an infinitely high torque in the opposite direction of rotation can be.

in the The invention will be explained below with reference to an embodiment shown in the drawing embodiment explained in more detail. It demonstrate

1 an axial section through a screwing and

2 to 4 the screwing tool in different sectional views.

In the illustrated embodiment, the screwing tool is designed as Handschraubwerkzeug that a handle 10 has in the form of a transverse handle. In the axially middle area of the handle 10 is a handle bushing on the handle 12 stated.

Coaxial in the grip 12 is a receiving socket 14 used. The receiving socket 14 is in the handle bush 12 attached, eg in the handle bush 12 screwed. Coaxial in the receiving socket 14 can be a tool shank 16 be used. The tool shank 16 is formed in the illustrated embodiment as a hexagonal shaft. At the handle 10 opposite front end of the tool shank 16 is formed in a conventional manner, a working tip or a receptacle for tool bits. Because this working end of the tool shank 16 is not the subject of the invention, this working end is not shown.

The tool shank 16 can in the receiving socket 14 be held axially, including, for example, a locking device not shown radially in a circumferential groove of the tool shank 16 intervenes. The bore of the receiving socket 14 in which the tool shank 16 is received, has a diameter, which is a free rotation of the tool shank 16 in the admission book 14 allows.

In the handle bush 12 sits coaxially and freely rotatable a driven pulley 18 , The driven pulley 18 has essentially the shape of a circular disc and is on its grip 10 axially facing end face axially through the receiving socket 14 supported, causing the driven pulley 18 in terms of the handle 10 is fixed axially. The driven pulley 18 has a coaxial continuous receiving opening whose non-circular cross-section the non-circular outer cross section of the tool shank 16 corresponds, in the illustrated embodiment is thus designed as a hexagonal opening. The used tool shank 16 thus sits torque-tight in the driven pulley 18 and is non-rotatable with respect to this.

In the handle 10 is one as a bending rod 20 trained bending spring arranged. The bending rod 20 extends substantially over the entire transverse dimension of the handle 10 , The bending rod 20 is arranged perpendicular to the axis of the tool shank and extends symmetrically from the axis of the tool shank 16 to both sides. The bending rod 20 is shown in the illustrated embodiment as a rod with a round cross-section. Other cross-sectional shapes are also possible.

The bending rod 20 is in a through hole 22 of the handle 10 taken whose diameter is greater than the outer diameter of the bending rod 20 , At the two ends of the handle 10 is in each case an adjusting sleeve 24 respectively. 26 used. The adjustment sleeves 24 and 26 have an outside diameter equal to the diameter of the bore 22 corresponds to, and an inner diameter, the outer diameter of the bending bar 20 equivalent. The axial length of the adjustment sleeves 24 and 26 is shorter than the respective measured from the central axis radial length of the handle 10 , The adjustment sleeves 24 and 26 fill the annular gap between the bending rod 20 and the inner wall of the bore 22 completely out and fix the bending rod 20 at its two ends in the handle 10 along the length, with which the bending rod and the adjusting sleeves 24 and 26 overlap axially. Between the respective inner ends of the adjustment sleeves 24 and 26 remains a bending area of the bending bar 20 free, in which the bending rod 20 transverse to its longitudinal axis in the bore 22 can be deflected elastically.

The adjustment sleeves 24 and 26 or at least one adjusting sleeve 24 is in the hole 22 axially adjustable. For this purpose, the adjustment sleeve 24 an external thread 28 on, which in a corresponding internal thread of the bore 22 intervenes. By axia les adjusting the adjustment sleeves 24 and 26 in the hole 22 The length range over which the ends of the bending rod can be changed 20 in the grip 10 are fixed. As a result, the length of the free bending region of the bending rod can be adjusted and thus the spring characteristic or the elastic restoring force of this bending region. A scale slider 30 is in the wall of the hole 22 guided longitudinally displaceable and sits with a ring 32 freely rotatable but axially fixed on the adjusting sleeve 24 , Will the adjustment sleeve 24 in the hole 22 shifted, so takes the adjustment sleeve 24 the scale slider 30 With. The scale slider 30 is through a breakthrough 34 of the handle 10 visible, noticeable. One on the graduated scale 30 attached scale can thus through the breakthrough 34 be read. The scale shows the position of the adjusting sleeve 24 and thus the axial length of the free bending region of the bending rod 20 , which in turn is a measure of the elastic restoring force of the free bending region.

Axially aligned with the axis of the tool shank 16 is at the bend 20 a drive pulley 36 appropriate. The drive pulley 36 has the shape of a circular disc with the same diameter as the drive pulley 18 , The drive pulley 36 is outside on the bending rod 20 attached in such a way that the central axis of the drive pulley 36 the central axis of the bending rod 20 vertical cuts. The drive pulley 36 has on its back a central axial extension 38 on top of the bending rod 20 surrounds, so that the drive pulley 36 with the bending rod 20 in the direction of its transverse deflection is firmly connected and by the bending rod 20 is held unrotatable.

On the from the bending rod 20 facing away from the drive disk 36 with the of the receiving socket 14 abgewand th end face of the driven pulley 18 in touch. The adjacent end faces of the drive pulley 36 and the driven pulley 18 have an interlocking crown teeth 40 on. The crown gearing 40 is shown in the illustrated embodiment with a wave-shaped profile of the radial teeth. Other gearing forms are also possible. It is essential that the crown gearing 40 the drive pulley 36 and the driven pulley 18 engages with each other at least in one direction of rotation with an obliquely rising tooth flank.

The bending rod 20 holds the drive pulley 36 in such a position that the drive pulley 36 with their crown teeth 40 axially in the crown toothing 40 the driven pulley 18 engages, in turn, through the receiving socket 14 is supported. In this way, with the crown teeth 40 interlocking drive pulley 36 and driven pulley 18 a torque-locking coupling, via which a torque from the handle 10 over the bending rod 20 , the drive pulley 36 and the driven pulley 18 on the tool shank 16 can be transferred.

In the unused state, the bending rod stops 20 the drive pulley 36 axially in engagement with the driven pulley 18 , Here is the bending rod 20 not deflected in its bending area, so that no elastic deformation of the bending rod 20 occurs and no elastic force by the bending rod 20 is exercised. The bending rod 20 is therefore not subject to material fatigue. In addition, the bending rod exercises 20 no forces on the adjusting jets 24 and 26 out. These are therefore not mechanically stressed. An adjustment of the adjustment sleeves 24 and 26 is easily possible because these adjustment sleeves 24 and 26 through the bending rod 20 are not loaded radially.

If the screwing tool is used, by means of the handle 10 a torque on the tool shank 16 exercised. On the tool shank 16 acts a braking torque of the actuated part such as a screw. Because of the handle on the bending rod 20 on the drive pulley 36 applied torque and that of the tool shank 16 on the driven pulley 18 applied braking torque to turn the drive pulley 36 and the driven pulley 18 against each other, with the rising flanks of the crown teeth 40 the drive disk 36 and the driven pulley 18 cause the drive pulley 36 increasingly from the through the receiving socket 14 axially supported driven pulley 18 against the elastic bending force of the bending rod 20 is lifted. Exceeds this by the flank angle and the torque predetermined axial disengaging force the set restoring force of the bending rod 20 so comes the crown gearing 40 from drive pulley 36 and driven pulley 18 disengaged and the torque transfer from the handle 10 on the tool shank 16 will be interrupted.

In the middle of the bend 20 facing away from the end face of the drive pulley 36 is a camp ball 42 arranged on which the tool shank 16 axially supported with its rear end face. The bearing ball 42 minimizes friction between the end face of the tool shank 16 and the drive pulley 36 , This prevents a drive torque from the drive pulley due to this friction 36 directly on the tool shank 16 is transmitted, which leads to a distortion of the set and by the engagement of the crown teeth 40 from drive pulley 36 and driven pulley 18 defined limit moment could lead.

10

Handle

12

handle socket

14

receiving socket

16

tool shank

18

driven pulley

20

bending Beam

22

Bore of 10

24

adjusting

26

adjusting

28

thread

30

scale box

32

ring

34

breakthrough

36

sheave

38

approach

40

crown teeth

42

bearing ball

Claims (15)

Screwing tool with a drive body, with a receptacle for a tool shank and with a coupling for transmitting a torque from the drive body to the tool shank, which interrupts the torque transmission when a predetermined limit torque is exceeded, characterized in that the coupling is a drive pulley ( 36 ) and a driven pulley ( 18 ), that the drive disc ( 36 ) non-rotatably on the drive body ( 10 ) is arranged that the tool shank ( 16 ) opposite the driven pulley ( 18 ) is recorded non-rotatably that a bending spring ( 20 ) with at least one end in the drive body ( 10 ) and with a bending area the drive disk ( 36 ) and the driven pulley ( 18 ) holds axially in torque-locking engagement and that when the limit torque is exceeded, the drive disc ( 36 ) and the driven pulley ( 18 ) under elastic deflection of the bending region of the spiral spring ( 20 ) are disengaged axially from the torque-engaging engagement. Screwing tool according to claim 1, characterized in that the bending spring ( 20 ) at rest, when the drive pulley ( 36 ) and the driven pulley ( 18 ) are engaged, unloaded and not elastically deformed. Screwing tool according to claim 1 or 2, characterized in that the drive body of the handle ( 10 ) of a hand-screwing tool. Screwing tool according to claim 3, characterized in that the handle ( 10 ) is designed as a transverse handle, the bending spring ( 20 ) takes on. Screwing tool according to claim 3 or 4, characterized in that the bending spring as a bending rod ( 20 ) is trained. Screwing tool according to claim 5, characterized in that the bending rod ( 20 ) is fixed at its two ends and is elastically deflectable in its central region. Screwing tool according to one of the preceding claims, characterized in that the drive disc ( 36 ) and the driven pulley ( 18 ) formed as a plane or conical disc and coaxial with the axis of the tool shank ( 16 ) are arranged. Screwing tool according to claim 7, characterized in that the drive disc ( 36 ) and the driven pulley ( 18 ) with a crown toothing ( 40 ) mesh. Screwing tool according to claim 8, characterized in that the crown toothing ( 40 ) has symmetrical tooth flanks, in particular a wave-shaped tooth profile. Screwing tool according to claim 8, characterized in that the crown toothing ( 40 ) has a tooth profile with different flank angles. Screwing tool according to one of claims 5 to 10, characterized in that the drive disc ( 36 ) non-rotatable and in the deflection direction fixed to the bending rod ( 20 ) is attached. Screwing tool according to one of claims 5 to 11, characterized in that the bending rod ( 20 ) is fixed at at least one end with axially adjustable length. Screwing tool according to claim 12, characterized in that the bending rod ( 20 ) in a bore ( 22 ) of the handle ( 10 ) is received with a larger diameter and by at least one adjusting sleeve ( 24 . 26 ), which defines the annular gap between the bending rod ( 20 ) and the bore ( 22 ) fills coaxially. Screwing tool according to claim 7, characterized in that the end of the tool shank ( 16 ) on a center in the drive pulley ( 36 ) arranged ball bearing ( 42 ) is axially supported. Screwing tool according to claim 7, characterized in that the driven pulley ( 18 ) by one on the handle ( 10 ) receiving socket ( 14 ) is axially supported and torque-locked by the tool shank ( 16 ) is interspersed.