EP0615705A1 - Rotatable fastener - Google Patents

Abstract

The plane of at least one groove (21) containing a pulley cable (3) running round the outer periphery of the winder disc (2) contains a hub bore (22) diametrically penetrating the central hub part of the winder disc. The lengthwise section (3a) of the pulley cable runs through the hub bore, between its two ends. The two outer orifices of the hub bore widen out radially so as to curve backwards. Two cable pulley through-holes (4,5) in the housing periphery wall (1a) are diametrically opposite on the same plane as the cable pulley holder groove.

Description

The invention relates to a rotary lock for the adjustable, releasable contraction of two locking elements which can be clamped relative to one another, in accordance with the preamble of claim 1.

Twist locks of the type required in the preamble of claim 1 are known from EP-B-393 380 and EP-A-412 290. These known twist locks are specially designed for use on sports shoes. The closing flaps of a sports shoe can be contracted or released by winding or unwinding a traction cable on a winding disc rotatably mounted in a housing, for which purpose this winding disc has a traction cable receiving groove in which at least one end of the traction cable is fixed. So that a corresponding sports shoe can be adapted to the foot of a user, a precise adjustment of these twist locks is provided in that a releasable locking device or pawl device is arranged in the area between a turning handle acting on a rotary operating shaft and the winding disc. Furthermore, the rotary actuating shaft, which is rotatably mounted centrally in the housing, is in a drive connection with the winding disk via a gear arrangement, for example a planetary gear.

The invention is based on the object of further improving a twist lock of the type required in the preamble of claim 1 in such a way that it is distinguished by a particularly favorable traction cable arrangement and guide.

This object is achieved by the characterizing part of claim 1.

Advantageous refinements and developments of the invention are the subject of the dependent claims.

While in the known designs described the traction cable is fixed with one end or with both ends in a single traction cable receiving groove, the invention proposes a hub through hole in the plane or in the height of at least one traction cable receiving groove running around the outer circumference of the winding disk to provide, which diametrically crosses a central hub region of this winding disk and through which the traction cable is loosely guided with a longitudinal section located between its two ends. The pulling rope, which interacts with two locking elements that can be braced relative to one another, can thus be reliably arranged and guided in the associated pulling rope receiving groove, but in an extremely advantageous manner, a free longitudinal mobility of this pulling rope at least at the beginning of the tensioning or closing process of the corresponding pulling rope longitudinal section within the associated hub through bore, receiving groove and associated pull rope through openings is ensured in a housing wall. This free longitudinal mobility of the traction cable contributes to extremely good cable centering (self-centering) in the area of the winding disc at the beginning of the tensioning or closing process, so that the closing elements to be contracted can be clamped relative to one another in a manner which is extremely well adapted to the individual closing elements.

A particularly advantageous embodiment of the invention is also seen in the fact that the two outer mouth sections of the hub through-hole in the winding disk expand radially outward in such a way that - viewed in the view of the winding disk and in the direction of winding rotation thereof - they arcuate with the same slot width run backwards. As a result of these designs, when the traction cable is wound up in the associated traction cable receiving groove of the winding disk, there are, as it were, stepless transitions from the hub through bore to the outer circumferential wall of this hub, that is to say to the inner peripheral region of the circumferential traction cable receiving groove. The corresponding pull rope section is thus deflected into the pull rope receiving groove without significant kinking.

With regard to the assembly or replacement of the traction cable, it is easily conceivable that a corresponding traction cable can also be easily inserted from the outside in this embodiment according to the invention through associated traction cable lead-through openings in a housing circumferential wall and through an associated hub through-hole, without this Twist lock must be disassembled.

In this rotary fastener according to the invention, only a single pull cable receiving groove can be provided on the outer circumference of the winding disk, in which case the two free ends of the pull cable are then respectively fastened to one of the two locking elements which can be braced against one another, while a central longitudinal section of the pull rope is loosely passed through the hub through hole.

According to another advantageous development of the invention, the winding disc can have on its outer circumference two circumferential traction cable receiving grooves, which are correspondingly incorporated into the outer circumference of the winding disc in two planes that are axially spaced and parallel to one another. In this case, at least for a pull cable receiving groove, a diametrical hub through hole is provided for the loose passage of a central longitudinal section of the pull rope, and two pull cable receiving grooves are assigned two diametrically opposed pull cable through-openings in the housing passage wall. This design allows an arrangement and guidance of the at least one rope in two parallel pulling rope receiving grooves, whereby the winding disk can accommodate a maximum of twice the amount of pulling rope compared to a winding disk with only a single pulling rope receiving groove, which reduces the mutual bracing area of the to be contracted and also releasable from each other releasable locking elements.

While the known designs described at the outset are intended for special use on sports shoes, the construction according to the invention of the twist lock enables use that is not only limited to sports shoes, but can also be adapted to many other useful applications, such as various items of clothing (for example gloves, especially baseball or other sports gloves, belts, outer clothing), protective helmets, bags, cases, quick fasteners for fastening of containers or similar parts on two-wheelers, etc. In any case, with the help of the twist lock (twist lock) according to the invention, fast locking of locking elements which can be braced relative to one another can be brought about, this bracing also being able to be released again quickly.

Fig.1

einen vertikalen Querschnitt (etwa Schnittlinie I-I in Fig.2) durch eine erste Ausführungsform des erfindungsgemäßen Drehverschlusses, bei der die zugehörige Wickelscheibe nur eine einzige Zugseil-Aufnahmenut besitzt;

Fig.2

eine etwas vereinfachte, horizontale Schnittansicht durch den Drehverschluß, etwa entlang der Linie II-II in Fig.1, wobei sich die Wickelscheibe in ihrer Ausgangsstellung befindet;

Fig.3

eine ähnliche Horizontalschnittansicht wie in Fig.2, wobei die Wickelscheibe jedoch bereits eine Teilumdrehung ausgeführt hat;

Fig.4

eine Horizontalschnittansicht durch den Drehverschluß bei einer Ausführungsvariante, in der sich die Zugseil-Durchführungsöffnungen in der Gehäuseumfangswand nicht diametral gegenüberliegen;

Fig.5

eine vertikale Schnittansicht (etwa entlang der Schnittlinie V-V in Fig.6) durch eine zweite Ausführungsform des Drehverschlusses, bei der die Wickelscheibe zwei Zugseil-Aufnahmenuten besitzt und jede Aufnahmenut einen mittleren Längsabschnitt des Zugseiles aufnimmt;

Fig.6

eine vereinfachte Horizontalschnittansicht etwa entlang der Linie VI-VI in Fig.5;

Fig.7

eine ähnliche vetikale Schnittansicht wie Fig.5 (Schnittlinie etwa entsprechend VII-VII in Fig.8) zur Erläuterung einer weiteren Ausführungsform, bei der die eine Zugseil-Aufnahmenut einen mittleren Längsabschnitt und die zweite Zugseil-Aufnahmenut die Enden des Zugseiles aufnimmt;

Fig.8

eine vereinfachte Horizontalschnittansicht etwa entlang der Linie VIII-VIII in Fig.7;

Fig.9 und 11

schematische Aufsichten auf besondere Ausführungsvarianten der Wickelscheibe mit allgemeinen Anwendungsmöglichkeiten der Zugseilführungen;

Fig.10

eine Seitenansicht der Wickelscheibe, etwa entsprechend Linie X-X in Fig.9.

The rotary lock according to the invention will be explained in more detail below with reference to some exemplary embodiments illustrated in the drawing. In this drawing:

Fig. 1

a vertical cross section (about section line II in Figure 2) through a first embodiment of the twist lock according to the invention, in which the associated winding disc has only a single pulling cable receiving groove;

Fig. 2

a somewhat simplified, horizontal sectional view through the twist lock, approximately along the line II-II in Figure 1, with the winding disc in its initial position;

Fig. 3

a similar horizontal sectional view as in Figure 2, but the winding disc has already made a partial revolution;

Fig. 4

a horizontal sectional view through the twist lock in an embodiment, in which the pull-cable through openings do not lie diametrically opposite in the housing peripheral wall;

Fig. 5

a vertical sectional view (approximately along the section line VV in Figure 6) through a second embodiment of the twist lock, in which the winding disk has two traction cable receiving grooves and each receiving groove receives a central longitudinal section of the traction cable;

Fig. 6

a simplified horizontal sectional view taken approximately along the line VI-VI in Figure 5;

Fig. 7

a vetical sectional view similar to Figure 5 (section line approximately corresponding to VII-VII in Figure 8) to explain a further embodiment, in which the one pulling cable receiving groove receives a central longitudinal section and the second pulling cable receiving groove the ends of the pulling cable;

Fig. 8

a simplified horizontal sectional view taken approximately along the line VIII-VIII in Figure 7;

Fig. 9 and 11

schematic views of special design variants of the winding disk with general applications of the pull rope guides;

Fig. 10

a side view of the winding disc, approximately according to line XX in Fig.9.

The general structure of the first embodiment of this twist lock according to the invention will be explained with reference to FIG. 1.

This rotary lock contains as an essential part a rotatably mounted in a housing 1 winding disc 2, on which - in the present case preferably - a single pull cable 3 can be wound up and unwound, which is passed through pull cable through openings or - holes 4, 5 which are provided in the peripheral wall 1 a of the housing 1. The pull rope 3 interacts with two closing elements, not shown in FIG. 1, which can be adjusted, but releasably pulled together by the twist lock, and can thus be braced relative to one another.

The rotary lock also contains a rotary actuation shaft 6 which is rotatably mounted centrally in the housing 1 and which is connected to the winding disk 2 in rotary drive connection via a gear arrangement, preferably via a planetary gear 7 with sun gear 8, planet gears 9 and internal ring gear 10. It is also expedient here if, in a manner known per se, one end (in FIG. 1 the lower end 6a) of the rotary actuation shaft 6 carries a disengageable coupling element 11a of a coupling 11 provided in the drive connection mentioned, which is counteracted by the force of a compression spring 12 exercisable, axial pressure actuation (arrow 13) of the rotary actuation shaft can be disengaged. In this disengaged state, the winding disc 2 is then freely rotatable, thereby a rapid unwinding of the wound pull rope 3 and thus a quick release of the bracing of the closing elements is made possible. Said lower end 6a of the rotary actuation shaft 6 projects together with the coupling element 11a carried by it axially into a central axial bore 14 of the central winding disc hub 15.

As is also known per se from the explanations described at the outset according to EP-B-393 380 and EP-A-412 290, the rotary drive of the winding disk 2 takes place in such a way that the rotary actuating shaft 6 via a rotary handle 16 which can be rotated relative to the housing 1, which, for example, covers the top of the housing 1 in a cap-like manner, is rotated in the desired direction, as a result of which the central sun gear 8 is driven via the coupling 11, which is in meshing engagement with a plurality of planet gears 9, which in turn are in meshing engagement with a stationary internal ring gear 10 and are freely rotatably guided on trunnions 18, which are fixedly formed on the upper, first outer side 2a of the winding disk 2.

In addition, based on the known design according to EP-B-393 380 coaxial with the winding disk 2 and on the lower, second outer side 2b of the winding disk 2 opposite the clutch 11, at least one stop element, for example in the form of a stop arm 17, or in the housing 1 two stop arms 17, be rotatably supported. This stop element (stop arm 17) comes into contact with the housing 1 after at least approximately two turns of the winding disc, as a result of which the rotary movement the winding disc 2 is limited accordingly in order to avoid excessive stress on the pull rope 3.

The winding disk 2 is received and guided in a preferably cylindrical shape in a corresponding section of the housing 1 (as can be seen in FIG. 1). In addition, it can also be expedient if a rotary bearing pin 17a of the stop element 17 protrudes briefly from below into the axial bore 14 of the winding disk hub 15 from the lower, second outside 2b of the winding disk 2. The stop element 17 or one of the two stop elements 17 also has a second pivot pin 17b, which is arranged coaxially with the first pin 17a projecting into the axial bore 14 and opposite thereto and engages in a bearing bore 19 which engages in a bottom wall 1b of the housing 1 is provided appropriately.

Finally, for the general structure of the twist lock, it should also be mentioned that this - similar to the two known designs mentioned above - also contains a releasable pawl device 20, which is designed to fix the twist actuating shaft 6 and the winding disk 2 in a made adjustment of the twist lock.

On the outer circumference of the winding disc 2, an annular circumferential traction cable receiving groove 21 is incorporated, the axial dimension (slot width) of which is slightly larger than the diameter of the traction cable 3 and the radial dimension of which is sufficiently large to be able to accommodate a sufficiently large longitudinal section of the traction cable 2.

This is where an essential idea of the invention begins, according to which a hub through bore 22 diametrically crossing the central hub region (hub 15) of this winding disk 2 is provided in the plane or at the height of this circumferential traction cable receiving groove 21. Through this hub through bore 22, the pull cable 3 is passed loosely with a longitudinal section located between its two ends, i.e. with a central longitudinal section 3a, i.e. the diameter of the hub through bore 22 is accordingly only very slightly larger than the diameter of the pull cable 3, but preferably somewhat smaller than the axial width of the pull cable receiving groove 21 (as shown in FIG. 1). This fact is also illustrated in the horizontal sectional view in FIGS. 2 and 3.

FIGS. 2 and 3 also show that the two outer mouth sections 22a, 22b of the hub through bore 22 are increasingly expanding radially outwards in such a way that - in the view of the winding slide 2 (FIGS. 2 and 3) and in the latter The winding direction of rotation (arrow 23) is considered - they run in an arched backward curve with the slot width remaining the same (axial dimension with respect to the winding disk 2), as can be seen particularly well in FIG. 2 at 22a 'and 22b'. This allows a relatively continuous winding of the central longitudinal section 3a of the pull cable 3 in the transition from the hub through bore 22 to the outer peripheral wall of the hub 15. The latter is compared in a comparison between the starting position of the winding disk 2 in FIG. 2 and the position of the winding slide 2 in FIG clearly what the winding disc 2 has made a first partial revolution after the starting position.

In the embodiment according to FIGS. 1 to 3, the two pull cable through openings 4, 5 in the housing peripheral wall 1a are arranged in the same plane as the pull cable receiving groove 21 and the hub through bore 22, and they are approximately diametrically opposed. This version is suitable for very different applications of the twist lock according to the invention.

A variant of the previously explained embodiment is shown in FIG. 4. According to this, the two pull cable through openings 4 ', 5' are also arranged in the same plane as the pull cable receiving groove 21 and the hub through bore 22, but they are not diametrically opposed, but rather have a circumferential distance UA of less than 180 °, preferably about 90 ° from one another. This can be of particular advantage in the case of sports shoes, in particular ski shoes, if the twist lock is to be attached to a so-called spoiler.

In the embodiment of the twist lock described above, in which only a single pulling cable receiving groove 21 is provided on the outer circumference of the winding disk 2, the two free ends of the pulling cable 3 are fastened to one of the two locking elements (not illustrated in more detail) that can be braced against one another, while the central longitudinal section 3a of the pull cable 3 is loosely guided through the hub through bore 22.

Another embodiment of the twist lock is explained with reference to FIGS. 5 and 6. Since the general structure of this embodiment largely corresponds to the general structure explained in detail with reference to FIG. 1, the same parts are provided with the same reference numerals, so that there is no need to explain them again. 5 and 6 therefore also include a housing 1, a rotatably mounted winding disk 2 for winding and unwinding preferably a single pull cable 3, a rotary actuating shaft 6 rotatably mounted centrally in the housing 1, a gear arrangement, preferably in the form a planetary gear 7 for driving the winding disk 2, a clutch 11 between the rotary actuating shaft 6 and the planetary gear 7 as well as a pawl device 20 and at least one stop arm 17 for limiting the rotational movement of the winding disk 2.

A special feature of this embodiment of the twist lock, which is illustrated in FIGS. 5 and 6, but also with reference to FIGS. 7 and 8, is above all that the winding disk 2 has two ring-shaped circumferential traction cable receiving grooves on its outer circumference, both essentially can be of the same size and in accordance with the type explained with reference to FIG. 1. These two traction cable receiving grooves 21, 21a are - cf. Fig. 5 and 7 - in two axially spaced and parallel to each other planes or heights in the winding disc 2 (from its outer circumference) incorporated. In the embodiment according to FIGS. 5 and 6, an associated diametrical hub through bore 22 or 22c is provided for each of the two pulling cable receiving grooves 21, 21a. Here are by both Hub through bores 22, 22c of central longitudinal sections 3a and 3b of the pull cable 3 are passed through in such a way that, on the one hand, the two ends 3c and 3d of this pull cable 3 located outside the rotary lock and, on the other hand, an outer pull cable section formed by a pull cable longitudinal section located outside the housing 1. Loop 3e are in locking engagement with the closing elements, as is illustrated with reference to FIG. 9. In comparison to the first embodiment explained with reference to FIGS. 1 to 3 (with only one pulling rope receiving groove 21), the winding disk 2 according to FIGS. 5 and 7 (with two pulling rope receiving grooves 21 and 21a) can be approximately twice the length of the pulling rope 3 record, that is, this winding disk 2, each with two pulling rope receiving grooves, has a double pulling rope receiving capacity compared to the embodiment according to FIG.

In the embodiment according to FIGS. 5 and 6, central longitudinal sections 3a, 3b of the pull cable 3 are loosely guided through the associated hub through bores 22, 22c, and at the same level or height as the pull cable receiving grooves 21 and 21a on the one hand and the hub through bore 22 and 22c, on the other hand, two pull cable through-openings 4, 5 can be arranged diametrically opposite one another in the housing peripheral wall 1a; However, the diametrically opposite pull-wire through-openings 4, 5 can also be provided as approximately vertically extending elongated holes in such a way that the two longitudinal pull-wire sections 3a, 3b running one above the other are passed through one elongated hole each. The latter statement also applies again accordingly to the embodiment according to FIGS. 7 and 8.

An essential difference between the two embodiments according to FIGS. 5 and 6 on the one hand and FIGS. 7 and 8 on the other hand can be seen in the fact that, according to FIGS. 7 and 8, a diametrical hub through bore 22 is only available for the one lower pulling cable receiving groove 21 is provided for loose passage of a central longitudinal section 3a, while the two ends 3c and 3d of the pull rope 3 are fixed in the plane or height of the upper, second pull rope receiving groove 21a in the winding disc hub 15. This setting can take place, for example, in that corresponding blind bores and through bores - as indicated in FIG. 8 - are provided in the winding disc hub 15, which receive the outermost end sections of these two cable ends 3c and 3d, these outermost end sections then preferably in the associated hub bores Ultrasonic welding, that is to say in an extremely simple manner, can be attached to the hub 15, in particular when the traction cable 3 is a corresponding plastic cable and the winding disk 2 or its hub 15 is a corresponding plastic part.

As can also be seen in FIGS. 7 and 8, the embodiment selected there forms two outer pull rope loops 3e and 3f, which - as indicated in FIG. 11 - can engage with the corresponding locking elements, the points of engagement thereof are indicated at 24 and 25 (similar points of attack 24, 25 of corresponding locking elements are also illustrated in FIG. 9).

The hub through bores in the winding disks 2 of the embodiments according to FIGS. 5 to 8 can also be shaped in the same way, as is explained in more detail with reference to FIGS. 2 and 3.

While in the embodiments according to FIGS. 5 to 8, the longitudinal sections of the pull cable (including the corresponding ends) introduced into the two superimposed pull cable receiving grooves 21, 21 a run approximately parallel to one another in the starting position of the winding disk 2 (see FIG. 2), 9 to 11 show configurations according to which the longitudinal sections of the pulling cable (for example middle longitudinal sections 3a, 3b in FIG. 10) introduced into the two superimposed pulling rope receiving grooves 21, 21a intersect, preferably approximately, in the starting position of the winding disk 2 run at right angles to each other. 9 and 10 is essentially adapted to the example of FIGS. 5 and 6 and the configuration of FIG. 11 is essentially adapted to the example of FIGS. 7 and 8.

Reference is once again made to the two embodiments according to FIGS. 5 and 6 on the one hand and FIGS. 7 and 8.

If one looks first in FIGS. 5 and 7 and also in FIG. 1, the design and arrangement of the clutch 11 in the transmission connection between the lower end 6a of the rotary actuation shaft 6 and the planetary gear 7, then the disengageable clutch element (for example a claw clutch part) 11a projects with the lower shaft end 6a from the upper outer side 2a of the winding disk 2 somewhat into the upper end section of the axial bore 14 Winding disc hub 15 into it. Between the underside of the coupling element 1a and the longitudinal section (3a in FIGS. 1 and 7 and 3b in FIG. 5) of the traction cable 3 that is directly adjacent to this coupling element 11a, such a clear axial clearance must now be found in the axial bore 14 (see FIG. 5) be present so that the lower shaft end 6a together with the coupling element 11a can be pressed down sufficiently axially into the axial bore 14 in order to be able to disengage the coupling in the desired manner if necessary. Accordingly, the axial length of the end section of the axial bore 14 receiving the lower shaft end 6a and the coupling element 11a must extend from the corresponding outer side 2a of the winding disk 2 to the nearest hub through bore 22 or 22c - according to arrow 13 - at least the maximum pressure actuation path (corresponding to play s) plus corresponds at least to coupling element 11a or its thickness. Since in the embodiment according to FIGS. 5 and 6 two middle longitudinal sections 3a, 3b cross the winding disk hub, while in the embodiment according to FIGS. 7 and 8 only a single middle longitudinal section 3a crosses the winding disk hub 15, the axial dimension or thickness of the winding disk can 2 in the example of FIGS. 7 and 8 are kept smaller than in the case of the example according to FIGS. 5 and 6, as a comparison of the graphic representations in FIGS. 5 and 7 shows.

In this context, it should also be pointed out that the pivot bearing pin 17a of the stop element 17, which projects into the axial bore 14 of the winding disk hub 15, projects only as far into this bore, that in any case the closest or lower hub through bore 22 is left free.

With regard to the design of the pull cable through-openings 4, 5, it should also be mentioned that these - as indicated in Fig. 2 at 4a and 5a - similar curved sections as the mouth sections 22a, 22b of the hub through holes (Fig. 2 and 3) in the Can have way that the pull rope 3 can be guided or deflected largely without kinks during the winding process along the curved opening sections 4a, 5a.

As can be seen from the exemplary embodiments described, the use of only a single pulling rope is particularly preferred in this rotary lock or rotary clamp. In the described embodiments, however, it is also possible to provide at least two traction cables in a corresponding manner, it being possible, for example, in the case of two traction cable receiving grooves, to assign a traction cable to each of the receiving grooves of the winding disk.

This twist lock according to the invention can be made of any suitable material. At least the main parts of this twist lock can be made of metal, preferably relatively wear-resistant light metal. However, an embodiment is also particularly preferred in which at least the main parts of this twist lock are made of plastic material, preferably of an impact-resistant and wear-resistant plastic material.

In any case, this twist lock according to the invention can be adapted extremely well to very different applications, it also being distinguished by a particularly flat and space-saving design.

Claims (15)

Twist lock for adjustable, releasable contraction of two locking elements which can be braced relative to one another, comprising a) a pulling rope (3) which interacts with at least one of the two closing elements, b) a winding disc (2) rotatably mounted in a housing (1) for winding and unwinding the pull rope (3), this pull rope being passed through lead-through openings (4, 5) in the peripheral wall (1a), c) a rotary actuating shaft (6), which is rotatably mounted essentially centrally in the housing (1) and is in drive connection with the winding disk via a gear arrangement (7), d) a detachable pawl device (20) for fixing the rotary actuating shaft (6) and the winding disc (2) when the rotary lock has been set, characterized in that e) in the plane of at least one traction cable receiving groove (21, 21a) which runs in a ring on the outer circumference of the winding disc (2), a hub passage bore (22, 22c) diametrically crossing a central hub region of this winding disc is provided, through which the traction cable (3) also coexists a longitudinal section (3a, 3b) located between its two ends is passed loosely. Rotary lock according to claim 1, characterized in that the two outer mouth sections (22a, 22b) of the hub through-bore (22, 22c) expand radially outwards in such a way that - in the view of the winding disc (2) and in the latter Direction of winding rotation (23) considered - with the groove width remaining the same, curved backwards in an arc. Twist lock according to claim 2, characterized in that two pull cable through openings (4, 5) are arranged in the housing peripheral wall (1a) in the same plane as the pull cable receiving groove (21, 21a) and are approximately diametrically opposed. Twist lock according to claim 2, characterized in that two pull cable through openings (4 ', 5,) are arranged in the housing peripheral wall (1a) in the same plane as the pull cable receiving groove (21, 21a) and have a circumferential distance (UA) of less than Have 180 °, preferably of about 90 ° from each other. Twist lock according to claim 2, characterized in that with only one pulling cable receiving groove (21) on the outer circumference of the winding disc (2), the two ends of the pulling cable (3) are each fastened to one of the two locking elements which can be braced against one another. Twist lock according to claim 2, characterized in that the winding disc (2) has on its outer circumference two circumferential traction cable receiving grooves (21, 21a) machined in two mutually parallel planes, with a diametrical hub through bore (22, at least) for one traction cable receiving groove. 22c) is provided for the loose passage of a central longitudinal section (3a, 3b) of the pull cable (3) and two pull cable receiving grooves are assigned two approximately diametrically opposite pull cable lead-through openings (4, 5) in the housing peripheral wall (1a). Twist lock according to claim 6, characterized in that an associated diametrical hub through-hole (22, 22c) is provided for each of the two pull-rope receiving grooves (21, 21a), middle longitudinal sections (3a, 3b) of the pulling rope (3) in the through-hole through both hub-through holes Are passed loosely so that, on the one hand, the two ends (3c, 3d) of this traction cable and, on the other hand, an outer traction cable loop (3e) formed by a traction cable longitudinal section located outside the housing (1) are in locking engagement with the closing elements. Rotary lock according to claim 6, characterized in that the two ends (3c, 3d) of the pull cable (3) are fixed in the plane of the second pull cable receiving groove (21a) in the winding disc hub (15), preferably by ultrasonic welding, two being outside the housing (1) trained outer pull rope loops (3e, 3f) are in locking engagement with the closing elements. Twist lock according to claim 6, characterized in that the longitudinal sections of the pull cable inserted into the two pull cable receiving grooves (21, 21a) run approximately parallel to one another in the starting position of the winding disc (2). Rotary lock according to claim 6, characterized in that the longitudinal sections of the pulling rope inserted into the two pulling rope receiving grooves (21, 21a) cross each other in the starting position of the winding disc (2), preferably approximately at right angles to one another. Rotary lock according to claim 1, wherein one end (6a) of the rotary actuating shaft (6) projects into a central axial bore (14) of the winding disk hub (15) and a disengageable coupling element (11a) of a coupling provided in the drive connection between the rotary actuating shaft and the gear arrangement ( 11) which can be disengaged by means of an axial pressure actuation (13) of the rotary actuation shaft which can be disengaged against a spring force, characterized in that the axial length of the end section of the one which receives one end (6a) of the rotary actuation shaft (6) and the coupling element (11a) Axial bore (14) from the corresponding outside (2a) of the winding disc (2) to the nearest hub through bore (22, 22c) corresponds at least to the maximum pressure actuation path plus at least the coupling element (11a). Twist lock according to claim 11, wherein coaxial to the winding disc (2) and on that of the coupling (11) opposite second outside (2b) of the winding disk in the housing (1), at least one stop element (17) is rotatably mounted, which comes into contact with the housing after at least approximately two turns of the winding disk and thereby limits the rotational movement of the winding disk, characterized in that from the second outside (2b) of the winding disk (2), a pivot pin (17a) of the stop element (17) projects into the axial bore (14) of the winding disk hub (15), leaving the nearest hub through bore (22) free. Rotary lock according to claim 12, characterized in that the stop element (17) has a second pivot pin (17b) which is arranged coaxially with and opposite to the first pivot pin (17a) projecting into the axial bore (14) of the winding disc hub (15) and in a correspondingly provided bearing bore (19) engages in a bottom wall (1b) of the housing (1). Twist lock according to claim 1, characterized in that at least the main parts of this twist lock are made of plastic material, preferably of an impact-resistant and wear-resistant plastic material. Twist lock according to claim 1, characterized in that at least the main parts of this twist lock are made of metal, preferably relatively wear-resistant light metal.

Images