PL211266B1 - Mechanism of correction of a dose of automatic applicator, especially for insulin - Google Patents

Abstract

Automatic applicator dose correction mechanism, especially for insulin or other liquid pharmaceutical preparations, for multiple injectable administration of fixed doses of medicament from a removable container, comprising a double clutch assembly for setting and correcting the fixed dose, comprising a coupling sleeve connected to a ratchet sleeve and a drive nut, characterized by the fact that the coupling sleeve (2) is radially coupled to the ratchet sleeve (1) by means of a control recess and spline, and coupled to the drive nut (3) by means of pawl arms passing through the through-holes (2.2) of the coupling sleeve (2) .

Description

(12) PATENT DESCRIPTION (19) PL (11) 211266 (13) B1 (21) Application number: 381798 ^{(51) Int.Cl.}

A61M 5/315 (2006.01) A61M 5/24 (2006.01) A61M 5/31 (2006.01) (22) Reported date: 02.20.2007 (54) Automatic applicator dose correction mechanism, especially for insulin

(73) The right holder of the patent: (43) Application was announced: COPERNICUS SPÓŁKA Z OGRANICZONĄ ODPOWIEDZIALNOŚCIĄ, Szczecin, PL 01/09/2008 BUP 18/08 (72) Inventor (s): ADAM STEFAŃSKI, Gniezno, PL (45) The grant of the patent was announced: April 30, 2012 WUP 04/12 (74) Representative: item. stalemate. Ewa Grenda

PL 211 266 B1

Description of the invention

The present invention relates to a dose correction mechanism of an automatic applicator, in particular for insulin or other liquid preparations, in particular for multiple injection administration of fixed doses of a medicament from a removable container, e.g. for self-administration of insulin by a diabetic patient.

EP 0 338 806 B1 discloses a syringe comprising a body, a dose setting device in the form of a rotatable cap or ring mounted on the body and movable to a selected predetermined position in which the pawl is positioned to hold the dose setting device in place. at this predetermined position, the displacement of the dose setting device is accompanied by the biasing of a spring which, when the catch is released, provides a force to eject the set dose, characterized by having means adapted to release the catch, thereby returning the dose setting device to its original position. for driving the piston rod through the one-way clutch to expel the set dose and having a long (high) pitch threaded screw system capable of converting the rotary motion of the dose setting device to a linear motion of the piston rod.

From the description of the Polish patent PL 191 327 B1 there is also known a syringe for dividing fixed doses of a drug from a cartridge containing an amount of drug, sufficient for the preparation of several therapeutic doses, comprising a housing, a piston rod having a non-circular cross-section and an external thread, a piston rod drive comprising two elements, i.e. piston rod guides and a nut that has an internal thread to fit the threads of the piston rod and a dose setting mechanism including a non-self-locking threaded connection along which an injection button is unscrewed from the proximal end of the housing by rotation relative to the housing of the dose setting member which is characterized by in that a unidirectional coupling is provided between the nut and the stem guide to allow the rotation of these parts in one direction, but not in the opposite direction, the rotation that has been made possible being the only movement of the piston rod in the circumferential direction in the syringe, and the coupling e is designed so that an initial resistance, large enough to withstand the torque exerted on the coupling via a dose setting, has to be overcome in order for rotation to occur.

This known syringe with automatic dispensing based on a torsion spring does not offer the possibility of correcting the set dose.

Also known from WO 02/053214 A1 (EP 1 351 732) is a dose setting device for use in conjunction with a fluid-filled reservoir, the dose setting device being adapted to repeatedly inject individually determined doses of fluid from the reservoir, the reservoir, the reservoir, the reservoir, the reservoir. doses comprising: a housing, a driver adapted to eject a dose of a medicament from the reservoir, elastic means, a dose setting assembly mounted in the housing and connected to elastic means, the dose setting member comprising a dose setting member moveable in a first direction against the bias of the elastic means against the elastic means. a selected predetermined position, wherein displacement of the dose setting member is associated with spring bias, and wherein the dose setting member is displaceable in a second direction to selectively correct the set dose. Moreover, the device comprises locking means associated with the housing for holding the device in position despite the action of the elastic means, the locking means being released to cause the driver to eject a predetermined dose of medicament from the syringe, the force to eject the predetermined dose being provided. by elastic means.

The above dose setting device requires the use of additional force to overcome the pressure of the linear spring in order to disengage the dispensing mechanism by axially displacing it in order to correct an incorrectly set overdose by turning the knob in the opposite direction of the dose setting. It is a complicated operation, especially for people with reduced motor skills or low finger strength, e.g. for children or the elderly.

The Polish patent specification PL 208 660 B1 also describes an automatic applicator, especially for insulin, for multiple injections of fixed doses of a medicament from a replaceable container, comprising a body housing having a clip, connected to a cover of a removable medicament container, in particular an insulin pushed with a plunger connected to piston rod and linearly displaced by a lockable drive and guide unit, driven by a double clutch assembly by a tension spring placed in the body housing, a tightened dose setting knob also by a double clutch assembly, the drive-guide assembly being actuated by the trigger assembly, and on the tension spring holder there is a movable indicator cylinder, which is characterized in that the double clutch assembly is a coupling plate axially coupled to the ratchet plate body and coupled to the pawls, the tabs of which are detachably meshed with the tooth ring. at the drive nut.

Also known from WO 2006/045526 A1 is an adjustment mechanism for an injection device comprising a torsion spring to assist in the injection of a dose of a medicament from the injection device, the adjustment mechanism including an adjustment cam of an increase-setting adjustment cam adapted to receive and cooperate with a boost-setting dial key. the boost-up setting key and the up-setting dialing key are adapted to - when rotating the dose setting member in the first direction - cooperate in tensioning the torsion spring of the injection device, and a down setting cam adapted to receive and cooperate with the down-setting dial key, wherein The decrease setting cam and the decrease setting dial key are adapted to - when rotating the dose setting member in the other direction - cooperate in reducing the tension of the torsion springs of the injecting devices. The second direction of rotation is opposite to the first direction of rotation.

The automatic applicator dose correcting mechanism known from WO 2006/045526 and Polish patent application P 341 395 operates on the basis of a torsion spring and a system of cams controlling the dose dial direction. Correction of an incorrectly set dose is done by turning the dose setting knob in the opposite direction to the setting. During the correction, the pawl arms are pulled towards the center of the clutch by means of the projections on their outer track, which allows the adjustment mechanism to be turned in the opposite direction, i.e. reducing the dose, and the drive spring causes the advance movement and re-engagement of the pawl in the position less by one dose. Correction takes place as long as the user turns the knob in the direction of dose reduction. The disadvantage of the presented solution is the way the force acts on the pawl arms. The force retracting the pawl arms does not act directly on them, but through the protruding tab in an axial direction, which causes an additional torsional force on the pawl arms. Since the pawl arms are pressed against the toothed rim of the nut by an additional force from the torsion spring and this resistance must be broken during dose correction, it is possible, with prolonged use of the applicator, that these forces will permanently twist the pawl arms in the direction of the force, which will result in loss of the applicator's ability to correct the dose as the radial movement of the warped pawl arms may not be sufficient for the mating portions of the toothed rim and the tabs on the pawl arms to pass in the opposite direction.

The main disadvantage of the known solutions is the lack of possibility of a precise, controlled reduction of an erroneously overdose of a medicament.

The main object of the present invention relating to a dose correcting mechanism of an automatic applicator, especially for insulin, in particular for repeated injection of fixed doses of a medicament from a replaceable container, is to provide the possibility of a precise, controlled reduction of an erroneously determined overdose of a medicament while maintaining an automatic stress-free application of the medicament.

The second aim of the present invention is to achieve greater structural correctness by eliminating the unfavorable forces within the mechanism that may affect its correct operation, especially during its repeated and long-term use (which corresponds to the specificity of the use of insulin applicators).

The main objects of the present invention have been realized by the dose correcting mechanism of an automatic applicator, especially for insulin or other liquid pharmaceutical preparations, for multiple injection administration of fixed doses of medicament from a removable container containing a double clutch assembly for setting and correcting the fixed dose, constituting a coupling sleeve coupled to a ratchet sleeve and coupled to a drive nut, which according to the present invention is characterized in that the coupling sleeve is radially coupled to the ratchet sleeve by a control recess and spline and coupled to the driving nut by pawl arms extending through the pass-through cuts of the coupling sleeve.

This new design of the double clutch assembly, in the form of a form-locked clutch with a one-way reversible ratchet clutch, enables precise, controllable

A significant reduction in an incorrectly determined overdose of a medicament, while maintaining an automatic stress-free application of the medicament.

Preferably, the through-cuts of the coupling sleeve have a rectangular, oval or parabolic shape (with the contour of two complex cut-off peaks of the parabola) in straight-line view, which allows free operation of the ratchet mechanism during dose setting without exposing the mechanism to additional frictional forces. cooperating. These notches also allow reversal movement between the ratchet sleeve and the coupling sleeve with the minimum frictional forces necessary to deflect the pawl arms sliding across the raceway at one of the edges of the cutout.

Preferably, the coupling sleeve is radially coupled to the ratchet sleeve by a radial control recess on the outer surface of the coupling sleeve and a projection on the inner surface of the ratchet sleeve, or by a radial control recess on the inner surface of the ratchet sleeve and a projection on the outer surface of the coupling sleeve. the control selection is rectangular in the straight-ahead view.

Preferably, the coupling sleeve is radially engaged with the drive nut by means of ratchet sleeve pawl arms located in the notches of the ratchet sleeve and extending through the pass-through slots of the coupling sleeve, the pawl arms being detachably meshed with the ratchet toothed rim on the outer surface of the driving nut and forming integral parts. portions of the ratchet sleeve, most preferably material of the ratchet sleeve ratchet cuts.

Preferably, the ratchet notches in the ratchet sleeve are rectangular, oval or parabolic in shape when viewed straight ahead, which allows the ratchets to deflect freely during the setting and correcting movements. This also enables correct cooperation with the nut's toothed ring and the raceway of the coupling sleeve. These cuts are designed to minimize the possible impact of bending moments on the pawl arms.

The coupling sleeve may also radially engage the drive nut by pawl arms on the outer driving surface of the nut extending through the slots of the coupling sleeve, the pawl arms being detachably meshed with the ratchet rim on the inner surface of the ratchet sleeve and being integral parts of the drive nut.

Preferably, the pawl arms of the ratchet sleeve or drive nut slide along the radially deflecting track with the corrective movement to reduce the set dose, the track being an oblique cut of one of the radial edges of the radial cutout of the coupling sleeve. It ensures that the pawl arms slide along the track in a way that does not cause additional torsional loads on the pawl arms over and above the necessary normal (centrifugal) loads for the correct operation of the mechanism.

Preferably, the locking element of the drive nut is a ring rim locking device that locks the nut in position during the setting movements, in a manner preventing rotation of the nut, ensuring accuracy in dose setting.

Preferably, the pawl bushing has a groove or threaded profile on its outer cylindrical surface for engagement with the indicator element. Such a connection constitutes a non-compliant clutch, which increases the accuracy of the indication of the currently set drug dose by unambiguous determination of the mutual position of the actuating and indicator mechanisms.

Preferably, the drive nut fastener comprises a thread or keyway to transmit rotation from the torsion spring through the setting mechanism to the linear sliding motion of the piston in a backlash-free manner, ensuring that the piston is accurately displaced by the set amount.

Fig. 1 shows a longitudinal view of the complex dose correcting mechanism of the automatic applicator, Fig. 1A is a cross-sectional view AA of the dose correcting mechanism of the automatic applicator of Fig. 1 during dose setting, Fig. 1. 1B is a cross-sectional view AA of the dose correcting mechanism of the automatic applicator of Fig. 1 during a dose correction, Fig. 2A is an exploded, axonometric side view and partial cutout view showing a spring of the automatic applicator of Fig. 2A. Fig. 2B. 1 is an exploded, full axonometric side view of the automatic applicator of FIG. 3 is an axial longitudinal section view of the automatic applicator with the dose correction mechanism of the invention, FIG. 4A is another embodiment of the automatic applicator dose correction mechanism. a in exploded view, in side view

FIG. 4B shows yet another embodiment of the automatic applicator dose adjustment mechanism in an exploded, full axonometric side view.

Figure 1 shows a longitudinal view of the complex dose correction mechanism of the automatic applicator and shows its main parts, which are: a ratchet sleeve 1 having an enlarged (in this exemplary embodiment) ratchet ring 1.1, a coupling sleeve 2 and a drive nut 3. Design of the dose correction mechanism is shown in Fig. 1.A, which is a cross-sectional view AA of the dose correcting mechanism of the automatic applicator of Fig. 1 during dose setting. As shown, the ratchet ring 1.1 of the ratchet sleeve 1 is engaged by the pawl arms 1.3 with the ratchet toothed rim 3.1 of the stationary drive nut 3. The clamping force is provided by a spring (not shown in this figure) twisted counterclockwise as indicated. dart arrow. The ratchet ring 1.1 of the ratchet sleeve 1, rotatable about the central axis of the mechanism, has one or more spring arms of the ratchets 1.3 adapted to engage with the locking edges 3.6 of the ratchet toothed wheel 3.1 of the fixed drive nut 3 and to slide over the sliding edges 3.5 of the ratchet ring 3.1 of the fixed drive nut 3. The dose correction mechanism shown here has a ratchet ring 1.1 of the ratchet sleeve 1 located outside the control sleeve 2. The coupling sleeve 2 has a through-cut 2.2 with a raceway 2.3 made on the lateral outer surface in the form of a rectangle (in view from the front of this cutout). The coupling sleeve 2 is radially coupled to the ratchet ring 1.1 of the ratchet sleeve 1 by means of the radial control cavity 2.1 of the coupling sleeve 2 and the spline 1.4 of the ratchet sleeve 1. This figure also shows the locking element of the drive nut 3 in the form of a key 3.2 for connection to the actuators applicator.

Figure 1B shows a cross-section A-A of the dose correcting mechanism of the automatic applicator of Figure 1 during dose correction, i.e. clockwise rotation as indicated by the arrow. The raceway 2.3 of the through-cut 2.2, which is the bevel of one of the radial edges of the radial through-cut 2.2 of the coupling sleeve 2, then acts as a return mechanism which ensures that the pawl arms 1.3 are displaced centrifugally during the dose-reducing movement, which allows the ratchet sleeve 1 to rotate in the direction of opposite.

Figure 2A shows the dose correcting mechanism of the automatic applicator of Figure 1 in an exploded view, in an axonometric side view and with a partial cutout showing the spring. The preferred use of the torsion spring 4 (Fig. 2A) causes the movement of the mechanism to advance in relation to the movement caused by the user and to re-engage the arms of the pawl 1.3 with the ratchet ring 3.1, the movement being continued as long as the user controls the mechanism by turning the adjustment knob ( not shown in this figure) with a characteristic click every single dose. Figure 2A shows that the ratchet sleeve 1 has a groove 1.5 on its outer cylindrical surface for engagement with an indicator element (also visible in Fig. 1 and Fig. 2B). Fig. 2B shows the dose correcting mechanism of the automatic applicator of Fig. 1 in an exploded view, in a full axonometric side view, but from a different angle, to better visualize the design of the various components of this exemplary embodiment of the automatic applicator dose correcting mechanism, including the thread 3.3 used herein instead of key 3.2.

The circuit shown in Fig. 1 operates as follows. When the dose is to be determined (up-setting), the coupling sleeve 2 is turned clockwise (looking towards the needle) with the springy arm of the ratchet 1.3 moving along the sliding edges 3.5 of the ratchet gear 3.1 of the fixed drive nut 3 from one the locking edge 3.6 of the gear rim 3.1 to the adjacent or adjacent edges depending on the angle of rotation. The ratchet sleeve 1 is driven by the coupling sleeve 2 by a control recess 2.1 on the outer wall of the coupling sleeve 2 meshed with a spline 1.4 on the inner wall of the coupling sleeve 1. Thus, when the coupling sleeve 2 is rotated, the outer ratchet sleeve 1 rotates with it. When rotating clockwise, pawl arm 1.3 moves radially alternately in and out.

When the inner coupling sleeve 2 is turned anti-clockwise (downward setting), a slight movement takes place between the coupling sleeve 2 and the ratchet sleeve 1 and, due to the displacement of the spline 1.4 in the control recess 2.1 in the opposite direction to the adjustment, it slips. movement of the pawl arm 1.3 along the treadmill 2.3

In a rectangular through-cut 2.2 with simultaneous lifting of the spring arm of the pawl 1.3 from meshing with the locking edge 3.6 of the ratchet toothed rim 3.1 of the fixed inner drive nut 3. When the arm of the pawl 1.3 is completely free of engagement with the locking edge 3.6, the outer pawl sleeve 1 can be rotated counterclockwise (looking towards the needle) with respect to the stationary inner drive nut 3.

It should be noted that the direction of rotation may be changed such that the boost setting is obtained by turning the ratchet sleeve 1 counterclockwise. In such a configuration, a decrease setting may be obtained by turning the ratchet sleeve 1 in a clockwise direction.

The structure of the present dose correction mechanism is based on the principle of cooperating rollers, in combination with an actuator in the form of a drive nut 3 and a drive element in the form of a torsion spring 4. The drive nut 3 is controlled from the mechanism by means of a ratchet toothed ring 3.1 transmitting the force of the spring 4 to other parts. elements in the form of e.g. a piston by means of a thread 3.3 or a key 3.2 shown in Figs. 1A and 1B. In addition, the exemplary locking element of the drive nut 3 during dose setting shown in Fig. 2B in the form of a rim 3.4 can also be made in other ways, e.g. in the form of a notch or a friction brake.

The coupling sleeve 2 may be connected to the dose dial by a shaft or sleeve extending through the center of the mechanism.

What is essential for the invention is the cooperation of the coupling sleeve 2 with the ratchet sleeve 1 and the drive nut 3 in a way that allows for a precise, controlled reduction of an incorrectly determined overdose of the drug, while maintaining an automatic stress-free application of the drug ensuring long-term use in an automatic applicator, especially for insulin, in in particular for multiple injection administration of fixed doses of a medicament from a removable container.

Long service life was obtained through the use of an innovative control of the pawl arms 1.3 placed in the rectangular notches 1.2 on the cylindrical sleeve, i.e. by sliding the pawl arms 1.3 along the raceway 2.3 located in the rectangular through-hole 2.2 of the coupling sleeve, 2 in a way that does not cause additional torsional loads on the pawl arms over the normal (centrifugal) loads necessary for the correct operation of the mechanism.

Figure 3 shows an example of an injection device (automatic applicator) having a radial dose correction mechanism in accordance with the present invention. Among other components, the injection device shown in Figure 3 has a dose setting knob 5, a plunger rod 6 having a threaded outer surface and an axially oriented drive track, a drive nut 3, a torsion spring 4, a piston lock 7, a plug 8 connecting the coupling sleeve 2 with a knob 5, a trigger 9, a ratchet sleeve 1 and a cylinder with a scale 10 placed on the ratchet sleeve 1.

The dose is set by turning the knob 5 and the nut 3, while the torsion spring 4 is tensioned. The dose setting knob 5 cannot return to its starting position due to the ratchet mechanism located between the nut 3 and the ratchet sleeve 1 stuck in the trigger 9. In the case of when the user wishes to reduce the set dose, knob 5 is simply turned in the opposite direction. Mutual cooperation between pawl 1 and cap 3 in reducing a set dose is described in detail with reference to Figures 1A and 1B.

In addition, Figures 4A and 4B show other embodiments of the automatic applicator dose correcting mechanism in an exploded, full axonometric side view. As shown in these figures, the coupling sleeve 2 can be radially coupled to the ratchet sleeve by a radial control cutout 1.8 on the inner surface of the ratchet sleeve 1 and a spline 2.4 on the outer surface of the coupling sleeve 2 (Fig. 4B). In addition, the through-cuts 2.2 of the coupling sleeve 2 and the ratchet cut-outs 1.2 of the ratchet sleeve 1 may, in the straight view, not only be rectangular, but also oval or parabolic (FIG. 4B). The mechanism can also be characterized in that the coupling sleeve 2 is radially coupled to the drive nut 3 by means of pawl arms 3.7 on the outer surface of the driving nut 3 passing through the through-cuts 2.2 of the coupling sleeve 2, the pawl arms 3.7 being detachably meshed with the ratchet toothed ring. 1.6 on the inner surface of the ratchet sleeve 1 and form integral parts of the driving nut 3 (Fig. 4A). The ratchet sleeve 1 can be connected to the indicator element in the form of a scale not only by means of a groove 1.5. Other connections are also possible, e.g. in the form of a thread profile 1.7 on the outer cylindrical part of the sleeve 1 (Fig. 4B) or a dog clutch. Of course, also in the embodiments shown in Figures 4A and 4B, the mechanism in question functions as described above in the embodiment shown in Figures 1, 1A and 1B. Accordingly, an applicator having the mechanism of Figs. 4A or 4B functions the same as the applicator of Figs. 3.

Claims (24)

Patent claims 1. Mechanism for adjusting the dose of an automatic applicator, especially for insulin, or for other liquid pharmaceutical preparations, for multiple injection administration of fixed doses of a drug from a removable container, including a double clutch assembly for setting and adjusting the set dose constituting a coupling sleeve connected to a ratchet sleeve and connected with a nut, characterized in that the coupling sleeve (2) is radially coupled to the ratchet sleeve (1) by means of a control and spline recess and coupled to the drive nut (3) by pawl arms passing through the through cuts (2.2) of the coupling sleeve (2) ). 2. Mechanism according to claim The process of claim 1, characterized in that the through-cuts (2.2) of the coupling sleeve (2) are rectangular when viewed straight ahead. 3. The mechanism according to claim The process of claim 1, characterized in that the through-cuts (2.2) of the coupling sleeve (2) have an oval shape when viewed straight ahead. 4. The mechanism according to p. The coupling according to claim 1, characterized in that the through-cuts (2.2) of the coupling sleeve (2) have a parabolic shape when viewed directly. Mechanism according to p. The coupling according to claim 1, characterized in that the coupling sleeve (2) is radially coupled to the ratchet sleeve (1) by a radial control recess (2.1) on the outer surface of the coupling sleeve (2) and a spline (1.4) on the inner surface of the ratchet sleeve (1). Mechanism according to claim The process according to claim 5, characterized in that the radial control recess (2.1) has a rectangular shape in the straight-ahead view. 7. Mechanism according to claim The coupling according to claim 1, characterized in that the coupling sleeve (2) is radially coupled to the ratchet sleeve (1) by a radial control recess (1.8) on the inner surface of the ratchet sleeve (1) and a spline (2.4) on the outer surface of the coupling sleeve (2). ). 8. Mechanism according to claim The process as claimed in claim 7, characterized in that the radial control recess (1.8) has a rectangular shape in the straight-ahead view. The mechanism of claim 1 A device as claimed in claim 1, characterized in that the coupling sleeve (2) is radially coupled to the drive nut (3) by pawl arms (1.3) of the ratchet sleeve (1) placed in the notches (1.2) of the ratchet sleeve (1) and passing through the through-cuts (2.2) of the coupling sleeve (2), with the arms of the pawls (1.3) being detachably engaged with the ratchet toothed ring (3.1) on the outer surface of the driving nut (3). Mechanism according to claim 1 The process of claim 9, characterized in that the ratchet cutouts (1.2) of the ratchet sleeve (1) are rectangular in straight view. 11. The mechanism according to p. The process of claim 9, characterized in that the ratchet cutouts (1.2) of the ratchet sleeve (1) have an oval shape in straight view. 12. The mechanism according to p. The method of claim 9, characterized in that the ratchet cutouts (1.2) of the ratchet sleeve (1) are parabolic in shape when viewed directly. Mechanism according to p. The method of claim 9, characterized in that the arms of the pawls (1.3) are integral parts of the pawl sleeve (1). 14. A mechanism according to p. The method of claim 13, characterized in that the arms of the pawls (1.3) are material cut from the notches (1.2) of the pawl sleeve (1). The mechanism of claim 1, The method of claim 9, characterized in that the pawl arms (1.3) of the ratchet sleeve (1) slide along the radially deflecting track (2.3) with the corrective movement reducing the set dose. 16. The mechanism of claim 16 Device according to claim 1, characterized in that the coupling sleeve (2) is radially coupled to the drive nut (3) by pawl arms (3.7) on the outer driving surface of the nut (3) passing through the through-cuts (2.2) of the coupling sleeve (2), at The arms of the ratchets (3.7) are releasably engaged with the ratchet toothed rim (1.6) on the inner surface of the ratchet sleeve (1). 17. Mechanism according to p. 16. The method of claim 16, characterized in that the pawl arms (3.7) are integral with the drive nut (3). The mechanism of claim 18 17. The method as claimed in claim 17, characterized in that the pawl arms (3.7) on the outer driving surface of the nut (3) slide along the radially deflecting track (2.3) with the corrective movement reducing the set dose. 19. The mechanism of claim 1 Device according to claim 15 or 18, characterized in that the raceway (2.3) is an oblique cut of one of the radial edges of the radial through-cut (2.2) of the coupling sleeve (2). 20. The mechanism of claim 1 The method of claim 1, characterized in that the locking element of the drive nut (3) is a locking gear rim (3.4). 21. A mechanism according to p. The method as claimed in claim 1, characterized in that the ratchet sleeve (1) has a groove (1.5) on its outer cylindrical surface for connection to the indicator element. 22. The mechanism of claim 1 A device as claimed in claim 1, characterized in that the ratchet sleeve (1) has a threaded contour (1.7) on its outer cylindrical surface for connection to the indicator element. 23. A mechanism according to claim 23 The method of claim 1, characterized in that the drive nut connector (3) is a thread (3.3). 24. The mechanism of claim 24 The method of claim 1, characterized in that the locking element of the drive nut (3) is a key (3.2).