EP0255869A2

EP0255869A2 - Rotating device for a sports shoe, particularly a ski boot

Info

Publication number: EP0255869A2
Application number: EP87109608A
Authority: EP
Inventors: Robert Schoch
Original assignee: Weinmann & Co KG Fahrrad- und Motorrad-Teilefabrik GmbH; Weinmann & Co KG
Priority date: 1986-08-08
Filing date: 1987-07-03
Publication date: 1988-02-17
Anticipated expiration: 2007-07-03
Also published as: EP0255869B1; AT84402T; US4748726A; DE3626837A1; EP0255869A3

Abstract

In this particular usable in ski boots rotary closure are connected by a rotational movement in one direction or the other two traction wire tensioning elements in their effective length variable in opposite directions to tighten or loosen shoe closure flaps. For accurate setting of the rotary closure and accurate adaptation of the shoe to a foot, a catch means is provided in the region between the rotary handle and a cable pulley for the traction wire tensioning elements, which is a a pawl-supporting, with the turning handle while maintaining an idle path rotatable intermediate member and a in a includes cover incorporated toothed ring and is constructed in a simple and space-saving.

Description

The invention relates to a rotary closure for a sports shoe, particularly a ski boot, according to the preamble of claim 1.
Screw caps for ski boots are already known in various embodiments. One of these known rotary closures is disclosed for example in DE-C 22 13 720th In this case, the connected operation of the rotary closure effecting rotation handle rotatably directly with a functioning as the drive disc driver disc, the eccentrically arranged drive pin provided during the rotational movement of the rotary handle in succession with as drive elements at the top of the sheave, radial guide grooves come into engagement, so that a kind of Geneva mechanism for the rotary drive of the pulley results. In this way a certain extent gradual tightening or loosening the fastening tab of an associated athletic shoe may be brought about. After about the same Grundprizip also the rotary closure according to US-A-37 38 027 is formed.
Further, a rotation lock embodiment of the presupposed in the preamble of claim 1 is from about Art EP-B-56953 is known. Here, the pawl of the ratchet means is a matching recess in the lower half of a assigned on the shaft of the boot to be fastened housing body, while the biased formed with an engaging tooth and a projecting shoulder, up pawl of said pivotally movable in a recess of the lid-like upper Hälte, stationary housing body is mounted. disposed within a housing above this body, generally cup-shaped rotary handle is arranged provided with engaging teeth ring gear so that its teeth with the locking pawl can engage. This gear ring has an upwardly projecting, sleeve-like protrusion having a multi-start, external coarse thread, which meshes with a corresponding internal thread in the center of the turning handle engaged such that when the rotary handle to be rotated in one direction in the sense of closing this first performs an axial lost motion in the ball screw until it has brought the toothed ring referred to the pawl into engagement and then entrains this ring gear in a further rotational movement, whereby a kind of ratchet effect is achieved by the interaction of toothed ring and pawl. then If the rotation lock to be opened again, then the rotation handle is rotated reversely by first again, idle rotation is carried out on the steep thread of the ring gear to the ring gear of the pawl is disengaged, whereupon the actual loosening is effected during the further rotation of the Drehgrif fes ,
If one considers only the steep thread engagement between the toothed ring and rotating handle in this known from EP-B-56,953 known embodiment (for the preparation of idle rotation), these training results not only in a particularly complex structure, and consequent high manufacturing costs, but it also requires a undesirably great overall height (on the one hand due to the structural design and on the other due to the axial movement capability of the rotary handle).
The invention is therefore based on the object further improve a rotation lock of the presupposed in the preamble of claim 1 type in a manner such that at an extremely sensitive setting of the rotary closure and a reliable maintenance of the setting made a relatively simple and space-saving design (particularly low profile) is guaranteed.
This object is achieved by the features specified in the characterizing part of claim 1.
In this embodiment of the invention the gear ring is stationary and stationary provided and incorporated directly into the top of the casing. The pawl is, however, worn by, arranged between the turning handle and the housing cover washer, which is rotatably connected with the drive pulley for the rope pulley, so that the pawl is rotatable together with the intermediate plate and thereby in a desired manner with the teeth of the toothed ring in engagement can be brought.
This inventive design are particularly favorable conditions for a simple, reliable and space-saving design.
A particularly advantageous embodiment of the invention is given by the feature of claim 2, wherein such a configuration is further formed in a particularly advantageous manner by the features of claim. 3
In this inventive rotary closure a relatively flat shape will also be ensured, among other things, that - in contrast to the last known embodiments explained - the turning handle has only to perform a pure rotary motion, ie the rotary handle maintains its relatively small height even when he in one or the other circumferential direction is rotated.
Further advantageous embodiments of the invention are the subject of the other dependent claims.
The invention will be explained with reference to the drawing voltage closer. show in this drawing

Figure 1 is a perspective view of an embodiment in which the rotation lock is used according to the present invention a ski boot,.;
Fig. 2 is an exploded vertical sectional view with the essential parts of the rotary shutter;
Figure 3 is a cross-sectional view of the rotation lock along the line III - III in Figure 4.
Figure 4 is a partly covered and partly shown in the plan view plan view approximately according to line IV - IV in Figure 3.
Figure 5 is a face-up Grundrißdarstellung according to the lines V - V in Figure 3.
Figure 6 is a cross-sectional view approximately along the line VI - VI in Figure 5;
Figure 7 is a plan view of the closure in the unlocking position of the rotary handle and the pawl.
Fig. 8 is a cross-sectional view taken approximately along the line VIII - VIII in Figure 7, for showing the locking pawl in its unlocked position;
Fig. 9 is a detail cross-sectional view of the pulley when a gear drive;
FIG. 10 is a plan view of the drive assembly of FIG. 9;
Figure 11 is a similar cross sectional view as Figure 3, but only showing the arranged in the area housing and housing cover parts for explaining another embodiment in which the pulley is driven by a planetary gear..;
12 is a plan approximately in the region of the line XII-XII in Figure 11 (with the housing cover)..;
13 is a sectional view taken approximately along the line XIII-XIII in Fig. 11.;
Fig. 14 is a sectional view similar to FIG. 13, but with a different embodiment.

On the basis of Figure 1 is illustrated initially a possible embodiment, such as the twist lock 1 according to the invention may be attached to a ski boot, in particular on its formed by a plastic shell 2 outer shoe. This belonging to a known ski boot plastic shell 2 is provided in the front and upper region with an approximately slot-like opening 3, the insertion of a - facilitates the innerboot in the shell 2 and the donning and doffing of the ski boot itself - is not shown.
The plastic shell 2 also has a covering the opening 3, also made of plastic tongue 4, which is pivotable about a arranged in the region of the toe joint 5, so that they can be folded away from the main part of the shell. 2
As still further seen in Fig.1, the rotation lock 1 includes a mounted on the space formed by the plastic shell 2 shaft of the ski boot, preferably on the tongue 4 flat housing 6, one on the outer side (upper side) of the housing 6 is arranged, relative to rotatable turning handle 7 and two lead-out at opposite sides of the housing 6 traction wire tensioning elements 8, 9 which are formed in this case in the form of slings and with hook-like members 10, 11 can be brought into engagement. These hook-like elements 10, 11 are mounted on opposite lying over closing flap of the plastic shell 2 of the ski boot. By a rotary drive connection within the housing 6 a pulley in one direction or the other can be rotated by means of the turning handle 7 so that by a corresponding rotational movement of the turning handle 7, the effective length of the traction wire tensioning members 8, 9 in opposite directions in the sense of releasing and tightening the said closing flaps can be changed (via the hook-like elements 10, 11).
In the example illustrated in Figure 1 embodiment, the tongue 4 in the height of the twist lock 1 having two lateral extensions 4a, 4b provided which are used to cover the two traction wire tensioning elements 8 and 9 respectively.
The formation of the essential items of the twist lock 1 reveals especially in the exploded view in vertical section in Figure 2, while further details of these parts and their function arrangement are illustrated especially in Figure 3 to 6th
As shown in Figure 2, the relatively flat housing 6 of the twist lock 1 (see Figure 4.) Has a relatively large, in plan view circular recess 12 which is adapted in diameter and depth accurately for receiving a rope pulley 13. In this recess 12 open at approximately diametrically opposite locations guide channels 14, 15 through which the respective ends 8a, 9a of the traction wire tensioning elements 8, 9 are led out on opposite sides of the housing. 6 The clamping element ends located inside this housing 6 8a and 9a are - as indicated in Figure 4 - substantially diametrically opposed to the pulley 13 (for example - as known per se - by means of nipple) defined, so that at a corresponding rotational movement of the sheave 13 be performed in one direction or the other in a circumferential groove 16, and there can be expanded or unwound.
The pulley 13 is provided in this embodiment at its top in the form of a Maltese cross disc with radial guide grooves distributed on the periphery 17 as the drive elements.
Coaxial with the main vertical geometric axis 1a of the twist lock 1 is also disposed slightly above the pulley 13 a drive plate 18 substantially in the housing. 6 In the example illustrated here, these drive pulley 18 is also arranged substantially in the housing 6 and is formed as a driving disc with two eccentrically arranged drive pin 19 projecting to one another approximately diametrically opposite each other and from the bottom of the drive disc 18 downward against the sheave. 13 By an appropriate arrangement and mounting of this drive pulley 18 in the housing 6 results in the co-ordination with the sheave 13 a kind of Geneva mechanism by which - as best seen in Figure 4 is - during a rotational movement of the drive pulley 18 in the direction of arrow 20 the driving pin 19 successively come with successive in circumferential direction of the guide grooves 17 of the formed as a geneva pulley 13 into engagement and thereby drive the sheave in the direction of arrow 21 when the traction wire tensioning elements 8, 9 wound with their ends 8a and 9a of the sheave 13 to be (in the sense of tightening of the shoe closure flaps); a reverse rotational movement causes unwinding of the traction wire tensioning elements 8, 9 (in the sense of releasing the shoe closure flaps).
The housing 6 is covered at the top by a cover 22, which extends parallel to the main vertical axis 1a at its lower mounting pins 23, 23a, of which a mounting pin 23a at the same time a rotary bearing pin for guiding and supporting the pulley 13 forms (see. Also figure .3). This fastening pin 23, 23 preferably have threaded holes 23' and 23a' are screwed into the housing base 6a introduced screws 24 to thereby cover the housing 22 via the mounting pins 23, 23a is detachably connected to the housing bottom 6a. As illustrated in the drawing only two fastening pins 23, 23a, it goes without saying that distributed over the circumference of the housing cover 22, more than two such fastening pins may be provided.
Coaxial with the main vertical axis 1a of the twist lock 1, the housing cover 22 has a recess 25 for receiving the drive pulley 18 and a cylindrical bearing bore 26, in which one is mounted centrally upwardly projecting pin 27 of the drive pulley 18 and guided the lower, cylindrically shaped end 27a , The upper end 27b of this pin 27 projects beyond the bearing bore 26 also upwards and is provided with an external square (see. Also Figure 4, left half), wherein also centrally a tapped hole 27c is provided in the pin 27.
In the top of the casing 22, a toothed ring is incorporated 28 having a plurality of engagement teeth 29, the part of a still to be explained in more detail pawl means (see FIG. 5 and 6 also). This toothed ring 28 has in the present case twelve evenly distributed over the circumference engaging teeth 29; this number of the engaging teeth 29 can be adapted to the particular desired fine adjustment of the rotary closure. 1
Portion of said pawl means is also a locking pawl 30 which are formed in the manner of a two-armed lever and pivotally mounted in an adapted, via a pivot shaft 31 in the region above the toothed ring 28 located through hole 32 of a washer is pivotally supported 33 (see FIG. See also the Fig. 3, 5 and 6). The pawl 30 has 30a (at its one lever arm) and an upper tooth projection 30b (at its other lever arm) has a lower projecting tooth. 30a with the lower projecting tooth, the pawl 30 engage the teeth 29 of the toothed ring 28 (as in Figure 3 and 6.), while the upper projecting tooth 30b of the pawl 30 in a 7 incorporated in the underside of the rotary knob, such ring sector-shaped control recess 34 projects, which - as can be seen in particular from Figure 6 - which at its one end, a ramp-like increasing control surface 34a which is engageable with a corresponding mating surface of the upper projecting tooth 30b of the pawl 30 is engaged and their meaning is explained in more detail later.
Arranged between the turning handle 7 and the housing cover 22. Between disc 33 is mounted with a lower cylindrical central recess 33a in a central cylindrical bearing projection 22a on the upper side of the housing lid 22 freely rotatably and guided. It further comprises a centrally located on the main axis 1 a square through hole 35, into which engages the externally square upper end 27b of the drive wheel pin 27, so that a rotationally fixed connection between the drive pulley 18 and the intermediate disk is formed 33rd
The pawl 30 is preferably - as in the Figure 2, 5 and 6 illustrates - by means of two arranged on both sides of bearing blocks 36 inserted from above in the through hole 32 in the intermediate ring 33 and fixed. In these bearing blocks 36, the ends of the pivot shaft 31 protrude, wherein in the region between a bearing block 36 and the pawl 30 is a coil spring 37 disposed on the pivot axis 31 in such a way and connected to pawl 30 and bearing block 36 in such a manner that the locking pawl 30 with its lower projecting tooth 30a is resiliently biased toward the engaging teeth 29 of the toothed ring 28th The provided with a cover-like widening 7a turning handle 7 covers the intermediate disc 33 from above, whereby a 33 protruding, central, cylindrical bearing projection of the top surface of the washer 33b in a central, likewise cylindrical recess 7b on the underside of the turning handle 7 for the purpose of its guiding and storage intervenes. Coaxial with the main vertical axis 1a of the twist lock 1 is provided in the turning handle 7, a central stepped bore 38, can be used by a shoulder screw 39 so that its lower threaded end 39a can be screwed into the threaded hole 27c of the drive wheel pin 27, around the to create particular in Figure 3 shown co-ordination of the rotary closure. 1 The shoulder screw 39 may be designed in the form of a hexagon socket screw and completely submerged in the bore 38th
In this embodiment of the twist lock 1 is further of importance that the turning handle 7 by creating a blank path LW limited relatively rotatably mounted (Figures 4 and 7) on the upper side of the washer 33 and is guided. To achieve this idle path LW one hand, the turning handle 7 on its underside (preferably in the present example, as the control recess 34, diametrically opposite) a downwardly projecting drive pin 40 which engages in an approximately annular sector-shaped recess 41 from the upper side in the intermediate disc is worked 33, extends in the present case in the circumferential direction over an angular range of approximately 30 ° and with their pointing in the circumferential direction ends of stop ends 41a, 41b forms. These stop ends 41a, 41b define, when they come in one or the other direction of rotation of the turning handle 7 to the drive pin 40 in abutment, the free travel LW this rotary handle this means 7 that, when by the co-ordination of turning handle 7 and the washer 33 of the turning handle 7 is rotatably supported its rotational movement in one direction or the other (arrow 20 in Figure 4) corresponding to the length of the idle path LW limited relatively freely rotatable on and relative to the intermediate disc 33 and guided. The length of this idle path LW is abgestimt to the circumferential length of the cam groove 34, the upper projecting tooth 30b of the pawl 30 which is engaged as a kind of control projection. Accordingly, when the turning handle 7 - according to the arrow 20 in Figure 4 - is rotated in the direction of tightening rotation of the rotary shutter 1, then this turning handle 7 moves initially alone or freely relative to the drive plate 33 as far until its driving pin 40 with the corresponding stop end engages the recess 41a 41st In this way, the upper projecting tooth 30b of the pawl 30 passes through the action of the spring preload completely in the control recess 34 (as shown in Figures 3 and 5 is illustrated), while the lower projecting tooth 30a of the ratchet with the engaging teeth 29 of the toothed ring 28 resiliently engages is pressed. In a further tightening rotational movement in the direction of arrow 20 in Figure 4, the pulley is rotated in the direction of arrow 21 13 via the Malthäserkreuzgetriebe, so that the respective ends 8a and 9a of the traction wire tensioning elements 8, wound on this pulley 13 9 and thus the shoe closing flaps are tightened. Here, the pawl 30 successively comes to the circumferential direction distributed teeth 29 of the toothed ring 28 in engagement. After completion of the tightening rotation by the turning handle 7, the rotary setting of the rotary closure 1 then reached is locked into the tightening position by the pawl engagement position. In this way, the associated ski boot can be extremely sensitive and millimeter closed. counter to the arrow 20 in Figure 4 - - Then, when the rotation lock 1 is intended to be released in order to open the boot again, then the turning handle 7 is turned back in the direction of the release rotational movement, whereby the turning handle 7 according to the free travel of LW initially alone again and to rotate freely rotate relative to the intermediate disc 33, until its drive pin 40, the opposite free travel-end position at the abutment end 41b in the recess 41 has been reached, as illustrated in Figure 7. In this idle travel-end position, the ramp-like rising cam surface 34a has the same over the facing him surface of the upper projecting tooth pushed 30b of the pawl 30, thereby - contrary to the spring bias - the lower projecting tooth 30a of the pawl 30 from the engaging teeth 29 of the toothed ring 28 except engagement has been brought. In this way, the pawl is brought into its unlocked position 30 and is retained therein as long as the turning handle 7 is rotated toward the release-rotational movement or the drive pin 40 is held by this rotary knob 7 in the embodiment shown in Figure 7 idle travel-end position. The so UNLOCK te pawl means thus permits easy actuation of the Maltese cross transmission in such a manner that the pulley 13 is rotated counter to the arrow 21 in Figure 4 and thereby the traction wire tensioning element ends 8a and 9a can be unwound from the pulley 13 back to the boot to solve -Schließlappen or open.
In the embodiment described above, the rotary movement of the turning handle 7 by means of a Maltese cross transmission (driver plate 18 and formed in the form of a Maltese cross disc pulley 13) is transmitted to the pulley 13, whereby a stepwise or batchwise tightening the traction wire tensioning elements 8, 9 is brought about. However, a gear drive to transmit the rotational movement of the turning handle 7 on the sheave 13 instead of such a Maltese cross transmission whereby a substantially continuous tightening of the traction wire tensioning elements 8, 9 can be made possible.
Detailed views of an embodiment of a gear drive are in the 9 and illustrates 10th The pulley 13 itself may in turn be similarly executed substantially and stored as described above. At its top, in this case, however, - is coaxial to it - an approximately disc-shaped gear 50 is fixed (for example - as indicated - pinned) having provided on the outer peripheral edge of teeth 51. This gear 50 is a drive pulley 18' in drive connection, said drive pulley 18' via its projecting pin 27 'may be arranged together in the same manner with the other parts of the rotary closure upwardly as the drive pulley 18 in the previous example. The only difference of this drive pulley 18' to the drive wheel 18 is to be seen in that it has a suitable number of drive teeth 52 at its peripheral edge, which are in engagement with the teeth 51 of the gear 50th In this manner, the drive pulley 18' forms a kind of drive pinions for the gear 50 of the sheave. 13
Even when using this gear drive according to Figure 9 and 10, the above-mentioned pawl means ensures reliable locking and unlocking of the closure positions.
In the above-described embodiments, is disposed between the intermediate disc and the pulley, that is provided as the drive for this pulley once a Maltese cross transmission (Fig. 2 to 8) and on the other hand, a simple cylindrical (Fig. 9 and 10). According to a further advantageous embodiment of the invention, a further possibility for driving the pulley is that a planetary gear is provided between the intermediate see disc and the pulley. Such an embodiment is described hereinafter in particular with reference to FIGS. 11 and 12. For this purpose, will first be mentioned that in particular in Fig. 11 for simplicity only arranged in the area of the flat housing and the housing cover rotation lock parts are illustrated, while the overlying parts to the rotary handle and the pawl have been omitted, since these parts can be realized practically identical and can function in the same manner as previously described in detail particularly with reference to FIGS. 2 to 8. 11 and 12, the parts which are at least approximately similar to parts of the embodiment according to FIGS. 1 to 8 further are denoted by the same reference numerals, but with the addition of a double stroke in these figures..
The interest here overall construction of this further embodiment is first explained with reference to FIG. 11. Thereafter, the rotation lock of this example includes, in turn, a flat, on the shaft of a ski boot to be fixed housing 6" on which a housing cover is removably attached 22" above, which can be done for example by only indicated in chained lines, distributed over the circumference screws 53rd
It is the same important to point to a particular embodiment option of the housing cover 22". This housing cover 22" may comprise an upwardly protruding annular peripheral edge 54 which defines an upwardly open, cylindrical recess 55 in which the indicated intermediate disc only dot-dash lines 33" is suitable as well as freely rotatably received in diameter and height.
The sheave 13" is in this case likewise in a well-matched in diameter and depth recess 12" freely rotatably and arranged (as in the first embodiment), but this recess is 12" provided centrally in the substantially cylindrical housing 6". Accordingly, the cable pulley is mounted 13" via one of its lower downwardly projecting bearing projection 13"a centrally in the flat housing 6" by this bearing projection is fittingly received and freely rotatable 13"a in a central bore 56 of the housing bottom 6a".
As has already been mentioned above, is located in this case between the intermediate disc 33" and 13" of the pulley a planetary gear for driving the pulley 13". For this purpose, the drive pulley is designed for the cable pulley in the form of a driving sun gear 18" and arranged centrally in an internally toothed gear rim 57 which surrounds 13" the pulley in the region of their upper side and rotatably supported by the flat housing 6". With this input sun gear 18" one hand and the internally toothed gear ring 57 on the other hand is at least one planetary gear 58 in meshing engagement; in the present case are - as is apparent particularly from Fig. 12 - preferably three such planet gears 58 are provided in a uniform circumferential distribution within the ring gear 57th These trained in the form of small pinions planetary gears 58 are freely rotatably mounted on the upper side of the sheave 13" by being plugged onto corresponding, upwardly projecting, cylindrical bearing pins freely rotatable and loose.
The sheave 13" has a preferably continuous central guide bore 60 in which a centrally protruding from the input sun gear 18" downwardly projecting guide pin 61 is guided in a freely rotatable and mounted.
From the opposite side of the driving sun gear 18" turn is - similarly as in the first embodiment - an also been associated pin 27" centrally upwardly, having a lower, cylindrically shaped end 27a" and subsequent thereto upwards upper end 27b" provided with a external square is provided. While - is mounted centrally in turn substantially similar as in the first embodiment-the cylindrically shaped lower end 27a" in a cylindrical bearing bore 26" of the housing cover 22" and out of the outer square of the upper pin end 27b" projects into the matching rectangular through opening 35" of the washer 33", so that between this upper Zap fenende 27b" (and hence also between the input sun gear 18") and the washer 33" in turn results in a rotationally fixed connection.
The internally toothed gear ring 57 is generally formed in the shape of a flat ring, and is further in a fitting inserted rotationally upwardly open recess 62 of the housing 6". The latter could for example be done by an annular ring gear is determined simultaneously with the screws 53 for fixing the housing cover 22" or for example, that engages at least one circumferential shoulder of the ring gear in a corresponding recess at the top of the housing 6". In the present case, the ring gear 57 is thus used against rotation in the recess 62 of the housing 6" that this internally toothed ring gear 57 is carried on its outer circumference side 63 in the form of a polygon, preferably in the form of a hexagon or octagon (as shown in Fig. 12); the recess 62 is polygonal on its inner peripheral side (preferably hexagonal or octagonal) is accordingly carried out in an accurate adjustment. Therefore, the internally toothed gear rim 57 needs to be inserted during assembly of the rotary closure only loosely in the recess 62nd
It is understood, moreover, obvious that the axial height of the driving sun gear 18", of the internally toothed gear ring 57 and the Planetenrä of 58 is approximately the same size, as can be seen also from FIG. 11.
For the formation of the housing cover 22" should also be mentioned that in its upper surface, is explained in detail in substantially similar manner as described with reference to the first embodiment, a toothed ring is incorporated 28" with a plurality of engagement teeth 29", with the illustrated in detail here pawl (30) interact. Further, the housing cover may also comprise 22" in the region of its outer circumference a downwardly projecting rim-like collar 64 which engages a mating Umfangsausdrehung 65th The outer circumference of the housing and housing cover 6" 22" are cylindrical and flush with each other.
Another advantageous embodiment of this turning handle will be explained in particular with reference to FIG. 13 with FIG. 11.
dashed, as in FIG. 4 (but without reference numeral) indicated, are attached to the inner ends 8a and 9a of the traction wire tensioning elements 8 and 9 approximately cylindrical nipples which are inserted positively and releasably into bores of the sheave 13 and 13" ,
Referring to FIG. 11 of the nipple 66 is now at the inner end, z. B. 9a", of a tow rope tensioning element protruding 9" of the sheave 13" down and be guided in an incorporated into the bottom of the flat housing 6a" 6" groove 67, whose course can be seen in particular from FIG. 13. This groove 67 is now shown in FIG. Be in the form of a nearly full circle ring 13, but 67a and 67b of this groove form the two opposite ends 67 with the cooperating downwardly protruding nipple 66 stops, the rotary movement of the sheave 13" in both directions of rotation limit such that the sheave 13" in this case - may perform almost one full revolution in its loosening or tightening - between the two groove ends 67a and 67b.
the illustrated a modified embodiment previously particular reference to FIG. 13 and the rotational movement of the sheave limiting groove in the housing base 6" is based Fig. 14 explained, in which similar parts as in Figs. 11 and 13 are provided with the same reference numerals.
. In the cut Grundrißdarstellung this Figure 14 it can be seen that said groove 68 is carried out in the bottom of the housing 6" in this case in the form of a spiral, for example - as shown - representing a half times revolution. in turn, the opposite ends 68a and 68b of the spiral groove 68 act as end stops for the in this groove downwardly protruding nipple 66 on ren held end of a tow rope tensioning element. Thus, the nipple 66 can follow the spiral groove 68, it is expedient in the radial direction, limited movement in the sheave 13" maintained. Referring to FIG. 14, the pulley 13" thus the length of the spiral groove 68 can perform corresponding half times revolution with its solvent or tightening rotation.
Finally it should be noted that this invention rotation lock may be at least partially made of metal or an impact-resistant, wear-resistant plastic or of a suitable combination of such metal and plastic parts.

Claims

1. Rotary closure for a sports shoe, particularly a ski boot, containing

a) a (on the shaft 2, 4) of the shoe (to be fastened flat housing 6, 6"), is releasably secured on the top a housing cover (22, 22"),

b) a rotatably mounted in the housing pulley (13, 13") with provided in the circumferential region the drive elements (17, 51, 58),

c) two of the edges of zusammenzuziehenden closing flaps of the shoe-engageable, led out on opposite sides of the housing traction wire tensioning elements (8, 9) whose located within the housing inner ends (8a, 9a, 9a") approximately diametrically opposite each other on the pulley (13, 13") are fixed,

d) a likewise rotatably mounted in the housing, the driving elements of the pulley driving the drive pulley (18, 18', 18"),

e) arranged one on the outside of the housing, relatively rotatable to the rotary handle (7) which is connected in such a manner rotationally fixed to the drive pulley, that by its rotary motion the effective length of the traction wire tensioning members in opposite directions in the sense of tightening and loosening the shoe closure flaps is variable,

f) provided in the region between the rotary grip and the housing pawl means (28, 30, 33) having a plurality of locking positions for the tightening rotation of the rotary handle and a (with a plurality of engaging teeth 29, 29") provided with toothed ring (28 , 28") and an order (engageable pawl 30) in such a manner that the locking pawl is held at the tightening rotation of the rotary handle in its latch engaging position, while it is pivoted in the releasing rotational movement of the rotary handle into an unlocking position,

characterized by the following further features:

g) the toothed ring (28, 28") is (with its engaging teeth 29, 29") (in the top of the casing 22, 22") is incorporated;

h) a (between the turning handle 7) and the housing cover (22, 22") disposed intermediate disc (33, 33") carrying in one (in the region above the toothed ring 28, lying 28") of the housing cover through-hole (32), the pretensioned resiliently against the toothed ring pawl (30);

i) the locking pawl (30) carrying the washer (33, 33") is rotationally fixed to the drive pulley (18, 18', 18" connected).

is 2. Rotational fastener according to claim 1, characterized in that the turning handle (7) under creation of a blank path (LW) mounted for limited rotational movement relative to the upper side of the washer (33) and guided.

3. Rotary closure according to claim 2, characterized in that the idle path (LW) of the rotary handle (7) by the stop ends (41a, 41b) is limited on the one in the intermediate disc incorporated (33), ring-sector-shaped recess (41) in which a by the underside of the turning handle projecting driver pin (40) engages, and in that the underside of the turning handle (7) has a ring sector-shaped control recess (34) is incorporated, having and at its one end, a ramp-like rising control face (34a) with which an upwardly directed control projection (30b) of the pawl (30) is engaged such that the pawl in one hand, with the tightening rotation of the rotary handle matching idle travel-limit position to its pawl-engaging position and in the other, matching with the release-rotary movement of the turning handle idle travel-end position by the control surface (34a) is held in its unlocking position.

4. Rotational fastener according to claim 1, characterized in that the housing cover (22) on its underside parallel to the axis of rotation (1a) extending the turning handle (7), with the housing bottom (6a) connectable fastening pins (23, 23a), of which the a (23a) at the same time a rotary bearing pin for the pulley (13).

5. Rotational fastener according to claim 1, characterized in that an upwardly projecting peg (27, 27', 27"), the drive pulley (18, 18', 18") has its lower, cylindrically shaped end (27a, 27a") (in a central bore 26, 26") of the housing cover (22, 22") is guided rotatably and the upper end (27b, 27b") rotationally fixed in a central through-opening (35, 35") of the intermediate plate (33, 33") engages, wherein (in the pin 27) threaded bore (27c) is provided in a by a central stepped bore (28) of the turning handle (7) introduced collar screw (39) is screwed.

6. Rotary closure as claimed in claim 5, characterized in that a Maltese cross transmission is provided between the intermediate disc (33) and the pulley (18), said sheave (13) at its top in the form of a Maltese cross disc with circumferentially spaced radial guide grooves (17) and the drive pulley (18) is designed as a driving disc with two eccentrically arranged drive pins (19), which are used in a rotational movement of the driver disc are alternately and in succession with the guide grooves in the Maltese cross disc in engagement.

7. Rotational fastener according to claim 5, characterized in that a spur gear is disposed between the intermediate disc and the pulley (13), wherein the pulley has at its upper side a gear (50) and the drive disc (18 ') is in the form of a drive pinion which meshes with the toothed wheel (50) of the cable pulley in meshing engagement.

8. Rotational fastener according to claim 5, characterized in that between the intermediate disc (33") and the pulley (13") is provided a planetary gear, wherein the drive pulley in the form of a driving sun wheel (18") is formed centrally in a surrounding the pulley in the region of their upper side rotationally fixed by the flat housing (6") carried internally toothed ring gear (57) is arranged and wherein with the input sun gear (18") on the one hand and the internally toothed ring gear (57) on the other hand at least one on top of the sheave (13") freely rotatably mounted planet gear ( 58) meshes.

9. Rotary closure as claimed in claim 8, characterized in that the pulley (13") is mounted on a on its lower projecting bearing projection (13"a) centrally in the flat housing (6"), and that in a central guide bore (60) of said pulley (from the input sun gear 18") is guided freely rotatable centrally by protruding below guide pin (61).

10. Rotational fastener according to claim 8, characterized in that the internally toothed ring gear (57) formed in the shape of a flat ring and in a suitable, upwardly open recess (62) of the flat housing (6") is inserted against rotation.

11. Rotary closure as claimed in claim 8, characterized in that the housing cover (22") has an upwardly protruding annular peripheral edge (54) delimiting an upwardly open recess (55) in which the intermediate disc (33") in diameter and height is appropriate, taken freely.

12. Rotational fastener according to claim 1, wherein approximately cylindrical nipples are fixed to the inner ends of the traction wire tensioning elements which are inserted positively and releasably into bores of the sheave, characterized in that the nipple (66) at the inner end (9a") of a protruding traction wire tensioning element (9") from the sheave (13") downwards and in an in-ground (6a") of the flat housing (6") inlaid groove (67, 68) is guided, whereby this downwardly protruding nipple (66) and the opposite ends (67a, 67b, 68a, 68b) of the groove form co-operating end stops to limit the rotary movement of the sheave.

13. Rotary closure as claimed in claim 12, characterized in that the groove (67) is in the form of a nearly full circle ring.

14. Rotary closure as claimed in claim 12, characterized in that the groove (68) running in a spiral shape and the cooperating nipples (66) bounded radially movable in the pulley (13") is held.