EP0247104A1 - Ski binding for cross-country or touring skiing. - Google Patents

Abstract

Ski binding described below with a retaining envelope (40) which moves with a pivoting part (30) and which, to ensure a transition between an open position and a closed position relative to the part, is pivotally mounted on a horizontal transverse axis (20) which resists ski movements, the closed position of the binding being locked by a spring locking element (60). The pivoting part (30) has a blocking element (32) which, in the closed position of the fastener, engages in a recess on the retaining casing (40). Said casing (40) covers the front protuberance (101) of the sole of a ski boot (100), while the locking element (32) also descends through an opening (104) in the protuberance (101) of the sole. In the open position of the fastener, on the other hand, the locking element (32) is distant from the interior of the retaining envelope (40). According to the invention, the retaining casing (40) and the pivoting part (30) are pivotally mounted on a common transverse axis (20), fixed on a support block (10). The combined pivoting of the retaining casing (40) and the pivoting part (30) is carried out against the action of an elastic element (90). The pivoting part (30) carries, on a protrusion (33) oriented upwards, the locking piece (60) which, in the fixing locking position, engages in the retaining envelope (40). A spring (70) separates the retaining envelope (40) from the pivoting part (30).

Description

 Ski binding for a cross-country or touring ski

t The invention relates to a ski binding for a cross-country or

^" * ^• touring skis according to the preamble of claim 1.

A ski binding of the type mentioned at the outset is described in AT-B 357.081. This binding is created by inserting the sole extension of the ski boot into a holding shell, with converging side walls of the bracket supporting the insertion. When the holding shell is subsequently pressed down, which causes the binding to lock, locking pins penetrate clearances in the holding shell and openings in the sole extension of the ski boot. Disadvantages of this binding are that the retaining plate tilts with its sole plate about an axis lying relatively far back, and that the pivot axis for the relative movement of the retaining shell and the pivoting part carrying the locking pin lies substantially above the ski surface, which is a natural rolling movement of the sole of the foot the top of the ski prevented. Inserting the ski boot into the holding shell from bottom to top is not natural and therefore uncomfortable. In addition, the anchoring of the holding shell on the side surfaces of the ski is unfavorable for reasons of strength. In addition, an arrangement of a movable element protruding outward from the side surfaces of the ski is disruptive in the movement sequence.

The object of the invention is to adapt the entry into the binding with the ski boot and the walking to the natural movement of the foot in a ski binding of the type mentioned at the beginning and to create a compact arrangement of the entire ski binding.

The set goal is achieved according to the invention by the characterizing features contained in claim 1. *

The inventive measures a simple and safe ^~ stepping into the binding and a natural motion sequence is ensured when walking. The entire binding is compact, so that there are no components that would protrude from the side of the ski. The invention also relates to a ski binding for a cross-country or touring ski according to the preamble of claim 2.

In this ski binding, which is described in an older, not previously published European application (No. 851121 7.5) by the applicant, which forms an internal state of the art, the holding shell and pivoting part can be pivoted about a common transverse axis against an elastic element, which is held by a bearing block mounted on the ski, the transverse axis being located in the front region of the two components mentioned and a spring holding shell and swivel part acting in the sense of a spreading apart. Furthermore, the bolt is mounted on an extension of the swivel part on an axis and, in the closed position of the binding, engages in a transverse web of the holding shell provided with a locking groove. This version has generally proven itself, but the mounting of the ski boot was unsatisfactory because it wobbled in the holding shell. Furthermore, the presence of snow in the binding caused difficulties when getting in. In addition, there was no measure to prevent the bolt from being opened unintentionally by hitting obstacles while walking. The dimensions of the spring used to spread the holding shell and the swivel part are limited in terms of their design and therefore also in their effect due to the design. When getting in, the low closing force could cause the holding shell to pivot downwards before the ski boot was firmly seated in the holding shell.

The invention has several objects to overcome the disadvantages of this older solution, which are discussed below. The first task is to improve the retention of the ski boot in the holding shell, if necessary, even when there is snow in the binding.

This aim is achieved according to the invention by the characterizing features contained in claim 2.

The inventive measures according to the characterizing features of claim 2 ensure good retention of the ski boot in the holding shell. Due to the features of claim 3, the optimal angle of the contact surfaces is fixed at approximately * 5 °, so that on the one hand the longitudinal displacement of the ski boot does not become too great when there is snow on the contact surfaces, which would be the case at smaller angles and thus to a large one Would load the locking pin or the hooking element, and on the other hand the ski boot is still provided with sufficient lateral support by the contact surfaces, which would no longer be the case at larger angles. This feature makes the bond less sensitive to tolerance determinations.

By interacting the features of claim • the front area of the ski boot is designed in a particularly advantageous manner.

The features of claim 5 allow a particularly good fit of the hooking element on the locking pin.

The features of claims 6 and 7 represent other advantageous embodiments of the hooking element.

The features of claim 8 determine the support surfaces on the ski boot with which it is supported on the contact surfaces of the holding shell. The features likewise determine the guide surfaces of the ski shoe, namely that the lower guide surface of the ski shoe rests on the bottom of the holding shell and the upper guide surface rests on the guide strips of the holding shell from below.

The features of claims 9 and 10 describe various openings in the holding shell, by means of which it is ensured that snow in the binding is pressed out when boarding. In cooperation with the features of claims 5 and 6, the snow in the binding is led to the perforations of the holding shell.

The features of claim 11 represent a structural design of the surface of the locking pin on which the hooking element slides down to its final position while getting into the binding. The dimensioning of the distances between the support surfaces and the hooking element is selected so that the hooking element is under tension when the ski boot is inserted into the binding.

The second task is to provide the latch with additional security without increasing the number of components.

This goal is achieved according to the invention by the characterizing features contained in claim 12.

Due to the measures according to the invention according to the characterizing features of claim 12, the bolt has a further lock, so that an unintentional unlocking is not possible while walking due to blows and impacts.

The third task is to ensure that getting into the binding always takes place under controlled conditions.

This goal is achieved according to the invention by the characterizing features contained in claim 13.

The measures according to the invention, according to the characterizing features of claim 13, result in an increase in the closing force of the holding shell when entering the binding without additional parts and without reinforcing the springs to be used, in order to always ensure entry into the binding under controlled conditions .

The features of claim 14 cause that the pivot angle of the bolt when closing the binding is equal to the minimum pivot angle when opening the same.

Due to the design according to the features of claim 15, the position of the bolt and the holding shell to each other is determined in the open position of the binding. In all the configurations described above, the bolt must be held by the user with the ski stick in the position in which he releases the pivoting part during the entire step-off process.

The invention therefore has the fourth object of also eliminating this disadvantage and creating a ski binding in which the user has the possibility of being supported on the cross-country ski trail with both ski poles during the alighting process.

Starting from a ski binding according to the preamble of claim 1 or 2, this object is achieved according to the invention by the features of the characterizing part of claim 16 or 17.

A ski binding for cross-country skiing according to DE-Al 34 05 861 has a base plate arranged under the ski boot sole, which continues towards the ski tip in two cheeks, between which a handle lever, which is under the influence of a leg spring, is pivotably arranged on a transverse axis . The leg spring presses the handle lever against a hold-down for the ski boot sole, which can be pivoted about a further transverse axis arranged between the cheeks, on which a step spur is also mounted. The end of the latter engages in a recess in the sole of the ski boot from below.

In the entry position of the binding, the hold-down is held by the handle lever in that a guide curve of the handle lever engages over a cam of the hold-down. When the sole of the ski shoe approaches the base plate when entering, the cam moves along the guide curve, and when the culmination point is exceeded, the hold-down device is pivoted into the locked position.

This binding has the disadvantage that the step movement of the skier is brought about only by the elasticity of the sole of the ski boot, but not by an articulated flap in the binding. This known solution therefore differs generically from the object of the invention. Of course, there are various solutions for the practical design of the locking element. However, the construction according to claim 18 has proven to be particularly useful. With this construction, only an additional leg spring is required to achieve the desired effect.

As such, it would be possible to provide a flattened portion in the bottom of the arcuate groove to fix the leg of the leg spring, which protrudes into the groove of the bolt, and which is relatively weak, to which the spring end is held by friction. However, this could occasionally cause the latch to pivot unintentionally. This is prevented by the measure of claim 19.

The subject matter of claim 20 eliminates the risk of the end of the leg of the leg spring being spiked in the bolt.

The measure of claim 21 makes it possible for the bolt to automatically return to its locking position as soon as the end of the leg has been pressed by the crosspiece of the shark shell over the locking projection of the groove.

Due to the features of claim 22, the operational reliability of the ski binding is increased, since the required spring force is distributed over two halves of a bracket, whereby the risk of kinking the loaded leg of the leg spring is significantly reduced.

Further features, advantages and details of the invention will now be described in more detail with reference to the drawing, which shows two exemplary embodiments with regard to the design of the holding shell and ski boot, as well as two configurations for the bar. Show it:

Fig.l ski binding according to the invention in the open position and thus in Ein¬ position Fig.2 ski binding in the driving position cut along the line II in Fig.5 Fig.3 ski binding in the closed position, but without stress from the ski boot 3a detail from Figure 3 on an enlarged scale

Fig. 4 ski binding in walking position

Fig.5 Ski binding in driving position in top view

6 first embodiment of the holding shell of the ski binding with inserted ski boot in a top view

Fig.7 first embodiment of the ski boot in side view

8 shows a second embodiment of the holding shell of the ski binding with the ski boot inserted in a top view

Fig.9 second embodiment of the ski boot in side view

Fig. 10 ski binding similar to Fig. 1

Fig.il maximum pivoting of the bolt when closing the holding shell

Fig. 12 Ski binding analog to Fig. 2

Fig. 10 and 12 show the ski binding with the specification of further geometric conditions, omitting unnecessary details

Fig.13 to 20 a modification of the bolt, wherein

Fig. 13 Ski binding in the riding position

Fig. 14 section along the line XIV-XIV in Fig. 13

Fig. 15 Ski binding with unlocked latch

Fig. 16 Ski binding during the alighting process in the longitudinal center section

Fig. 17 to 20 details of the ski binding on a larger scale compared to Figs. 14 to 16

Fig. 21 a modification of the locking element in the diagram.

The first embodiment according to FIGS. 1 to 7 and 10 to 12 represents a ski binding for a cross-country or touring ski 1 and an associated ski boot 100. A bearing block 10 is mounted on the top of a ski 1 by means of indicated screws 2. It consists of a base plate 11 with two walls 12, which begin at the front end of the base plate 11 facing the ski tip and lead approximately to the middle of the base plate 11 and carry a transverse axis 20 in the latter area. The base plate 11 carries at its front end a rib 13 and at its rear end a support surface 14 in which the screws 2 are countersunk.

A pivoting part 30 is attached to the transverse axis 20 and rests with its bottom 31 on the bearing surface 14 of the bearing block 10. The floor 31 has on its side facing away from the ski 1 from the longitudinal axis of the binding slopes 31a sloping outwards. At the end remote from the transverse axis 20, the bottom 31 carries a locking pin 32 or bar. A holding shell 40 is also attached to the transverse axis 20, the bottom surface 41 of which has an exemption 41b for the locking pin 32 and further openings 41a (FIG. 6). Guide strips 45 are connected at the top to the side walls 42 of the holding shell 40, which are connected in their front part to a transverse web 43 which carries a latching groove 43a and in their rear area remote from the transverse axis 20.

An extension 33 of the pivoting part 30, which projects upwards from the transverse axis 20, carries at its upper end an axis 50 to which a bolt 60 designed as a two-armed lever is articulated, which on its arm facing the holding shell 40 has a groove-shaped stop 63 (FIG. 10 -12) and a detent 61, and on the side of the ski 1 facing away from its second arm carries a recess 62.

Corresponding cavities 31b are provided in the bottom 31 of the pivoting part 30 for a spring 70 about the transverse axis 20, which holds the holding shell 40 and the pivoting part 30 in the sense of spreading apart. A locking spring 80 around the axis 50 acts on the locking bar 60 in the closing direction to the holding shell 40.

In the front part of the bearing block 10, an elastic element 90 is used in such a way that its recess 91 comes to rest over the rib 13 of the base plate 11 and is supported on the pivot part 30 with its part facing away from the rib 3. The elastic element 90 has a bore 92 ^′ in order to be able to use the screw 2 unhindered when mounting the binding on the ski 1.

The ski boot 100 according to FIG. 7 to be inserted into the binding has in its front area a sole extension 101 which is formed from extensions 101a and a U-shaped hooking element 102 cast into it with its legs 102a. Between the hooking element 102 and the end face An opening 104 is formed in the sole 103. When viewed from the side, the front region of the sole has wedge-shaped guide surfaces 105a, 105b, the lower guide surface 105b being intended to rest on the bottom surface 41 of the holding shell 40. The angle between the upper 105a and lower guide surface 105b is the same as the angle between the bottom surface 41 and the guide strips 45 of the holding shell 40, since when the ski boot 100 is inserted into the binding, the upper guide surface 105a abuts against the guide strips 45 of the holding shell 40 from below should. The sole area provided with the guide surfaces 105a, 105b has support surfaces 106 which, when the ski boot 100 is inserted, lie parallel to the contact surfaces 44 of the holding shell 40.

In a second embodiment according to FIGS. 8 and 9, there are openings 42'a in the side walls 42 'of the holding shell 40 ¹ which widen outwards. The ski boot 100 'belonging to this embodiment has beveled surfaces 102'c on the outer surface of the hooking element 102' surrounded by sole material.

When entering the binding according to FIG. 1, the ski boot 100 is inserted with its guide surfaces 105a, 105b into the holding shell 40 obliquely from above until it engages with the hooking element 102 on the locking lug 61 of the latch 60, and then depressed, the holding shell 40 against the force of the spring 70 and partially against which the locking spring 80 is pivoted down. The locking pin 32 penetrates the opening 104 in the sole extension 101 of the ski boot 100 from below. The slope of the linear section 32a of the locking pin 32 serves in the first phase of the depression of the holding shell 40 to facilitate the threading of the locking pin 32 into the opening 104 until the ski boot 100 with its support surfaces 106 rests on the contact surfaces 44 of the holding shell 40. In the second phase, the hooking element 102 continues to move along the linear section 32a, but with increasing tension. In the third phase of depressing, from (transition point 32c from the linear section 32a to the circular arc section 32b, the tension remains constant as the hooking element 102 moves along the circular arc section 32b to its final position, since the circular arc section 32b has its center in the transverse axis 20. At the same time, the crosspiece 43 slides down on the inside of the locking lug 61 by pressing it in the opening direction (Fig. 10-11) until the locking lug 61 engages in its locking groove 43a and thus fixes the position. The entry into the binding takes place against an entry force which is higher than that of the spring 70 designed as a setting spring, in that the locking spring 80 is additionally acted upon when the holding shell 40 is pivoted. This solution results simply from constructive measures in the design of the bolt 60 and the crosspiece 43 of the holding shell 40, as a result of which the pivoting angle (or) of the bolt 60 is increased when the bolt 60 is entered and the bolt spring 80 is thus compressed more. Climbing in against the increased spring force prevents premature, uncontrolled closing of the binding as long as the ski boot 100 is not firmly seated in the holding shell 40. Snow in the binding is pressed out in the first embodiment through the openings 41a in the bottom surface 41 of the holding shell 40 during the boarding process. In the second embodiment, the snow is guided through the beveled surfaces 102'c on the hooking element 102 * to the openings 42'a in the side walls 42 'of the holding shell 40 * and pressed out by the latter. In addition, snow located between the swivel part 30 and the holding shell 40 is conducted outwards through the inclined surfaces 31a on the bottom 31 of the swivel part 30.

In the position of the holding shell 40 completely lowered to the ski 1, when it rests on the support surface 14 of the base plate 11, as is the case in the driving position according to FIG. 2, the hooking element 102 has its lowest position in the circular arc section 32b of the locking pin 32 taken while the locking lug 61 of the bolt 60 bears against the wall 43b lying in the closing direction of the bolt 60. In this position, which is also assumed when standing, the bar 60 can be opened by inserting a ski stick tip into its recess 62 and exerting pressure against the force of the bar spring 80, the ski shoe 100 coming out of the engagement of the locking pin 32 by lifting and can then be pulled out of the holding shell 40. 3 shows the binding in the closed position, but without load from the ski boot 100. Due to the action of the spring 70, the holding shell 40 rises until the catch 61 of the bolt 60 lies completely in the catch groove 43a. In this position, from which the engagement of the locking lug 61 of the bolt 60 in the crosspiece 43 of the holding shell 40 is shown on an enlarged scale in FIG. 3a, the bolt 60 cannot be opened. In FIG. 3a, the path of the latching lug 61 is drawn as a circular arc 200a around the axis 50 when the bolt 60 is pivoted in the opening direction in a dash-dotted line. However, the bolt 60 is prevented from this pivoting by a raised region 43c of the wall of the crossbar 43 lying in the opening direction of the bolt 60, which thus represents an additional safeguard for the bolt 60. When a ski boot 100 is inserted into the binding, it passes through the position according to FIG. 3 in the first phase of walking. As a result of the relative movement of the holding shell 40 relative to the swivel part 30, the hooking element 102 of the ski boot 100 lies in this position in the upper region of the circular arc section 32b of the locking pin 32. When the ski boot 100 is raised further according to FIG. 4, the latching position remains between the latch 60 and the crossbar 43 of the holding shell 40 on the one hand and the position of the hooking element 102 in the circular arc section 32b of the locking pin 32 on the other hand, whereby the holding shell 40 and the pivoting part 30 form a unit and jointly pivot counterclockwise against the force of the elastic element 90. Snow that accumulates in the binding while walking is pressed out of the binding by oblique snow-pressing surfaces 15, 31c, which are formed both on the base plate 11 and on the underside of the pivoting part 30.

Among other things, it is essential to the invention that the bolt 60 and the crosspiece 43 of the holding shell 40 are matched to one another in such a way that the bolt 60 assumes a precisely defined position in the open and closed position of the binding. This position is determined by the position of the latch 60 and the holding shell 40 relative to one another, which, in the open position of the binding, is caused by an elevation 43d of the transverse web 43 resting on the flute-shaped stop 63 of the latch 60 and in the closed position by the engagement of the latch 61 of the latch 60 on the wall 43b lying in the closing direction of the bolt 60 results in the locking groove 43a of the cross piece 43. In the exemplary embodiment according to FIGS. 10 to 12, the bolt 60 and the crosspiece 43 of the holding shell 40 are matched to one another in such a way that the position of the bolt 60 is the same in the open and closed position of the binding. Both when opening and when closing the binding, the cant 43d of the crossbar 43 of the holding shell 40 and the locking lug 61 of the bolt 60 slide past one another, the retaining shank 40 pivoting in one direction and the bolt 60 performing a rocking movement in which he reaches a maximum swivel to then return to his starting position. The position of the maximum pivoting is given by the intersection 200 of two curves, namely by the circular arc 200a, which the locking lug 61 about the axis 50, and the circular arc 200b, which the elevation 43d of the crosspiece 43 describes about the transverse axis 20. Since in the exemplary embodiment the position of the bolt 60 is the same when the binding is closed and open and the intersection 200 has a fixed position, the pivoting angle (<&) of the bolt 60 when closing the binding is identical to the minimum pivoting angle (, 4) at the opening of the bond. FIG. 11 shows the pivoting of the latch 60 and the holding shell 40 with the omission of all other components, only the transverse web 43 of the holding shell 40 being shown. The position of bolt 60 and holding shell 40 in the open position of the binding is illustrated in full lines. When the binding is closed, that is, the holding shell 40 is pivoted down, the crossbar 43 slides down with its elevation 43d on the inside of the locking lug 61, whereby it acts on the bolt 60 in the opening direction until it reaches the position of its maximum pivoting, which is shown in FIG 1 is held with dashed lines. After this position has been exceeded, the holding shell 40 pivots further and the latch 60 rests with its latching lug 61 on the wall 43b of the transverse web 43 lying in the closing direction of the latch 60, the latch 60 having returned to its starting position. The position of the crosspiece 43 when the binding is closed is shown in FIG. 11 with a dotted line.

The ski binding shown in FIGS. 13 to 20 corresponds, except for the design of the bar and its locking element, to the structure according to what has been described so far. For this reason, the other components are the Provide ski bindings with identical reference numbers, even if they differ slightly from the configurations shown above. For better distinction, the bolt and its locking element have been labeled with numbers over 300.

An additional leg spring 306 is arranged on the transverse axis 20 in addition to the spring 5 as a locking element for the bolt 360, and is operatively connected to the bolt 360 in a manner to be described in more detail.

In the lever arm of the latch 360 carrying the latching lug 361, a groove 364 with a rectangular cross section is excluded. A locking projection 365 is formed on the bottom of the groove 364 near its end remote from the axis 50. Between the locking projection 365 and the end of the groove 364 adjacent to the axis 50, the groove 364 runs in an arc.

The above-mentioned additional leg spring 306, one leg 306a of which is anchored in the pivoting part 30, engages in the groove 364 with its other leg 306b. The end 306c of this leg 306b, as shown in FIGS. 17 to 20, is designed in the form of a circular arc. But it can also play a role. If a normal plane is placed on the leg neck at the point of contact of the end 306c of the leg 306b with the base of the groove 364, this includes an angle JT ^ with a tangential plane to the base of the groove, which angle is greater than the friction angle between the materials of the bolt 360 and the Leg spring 306 is.

For a better understanding of the effects that can be achieved through the further development of the bar 360, the function of the ski binding according to the previous embodiments is briefly repeated first and then the function of the further developed embodiment is discussed. Fig. 17 corresponds to the driving position of the ski binding, as shown in Fig. 14, and Fig. 18 corresponds to the ski binding with the bolt released. 19 and 20 show intermediate positions of the bolt and one leg of the leg spring during the alighting process. The function of the ski binding according to the previous embodiments is as follows: When getting into the opened binding, the ski boot, not shown here, is inserted obliquely into the holding shell 40 from above.

Thereupon, the ski boot together with the holding shell 40 is pivoted downward over the position according to FIG. 16 into the position according to FIG. 14 and held by the locking pins 32 which penetrate the through openings of the sole extension. The latch 360, which can be pivoted about the axis 50, slides with its locking lug 361 over the crosspiece 43 of the holding shell 40 (see FIG. 16) and is finally locked in the locking groove 43a of the crosspiece 43 (see FIG. 14). . The binding is thus closed, and the holding shell 40 and the pivoting part 30 can be pivoted together about the transverse axis 20 against the action of an elastic element (not shown here) (see element 90 in FIG. 1).

However, if the skier wants to get out of the binding with his ski boot, he presses the tip of his ski pole into the recess 362 of the lock 360, whereby this is pivoted counterclockwise against the force of the locking spring 80 in FIGS. 14 and 17. At the same time, the locking lug 361 is lifted out of the locking groove 43a of the crossbar 43 of the holding shell 40, so that the latter can pivot relative to the pivoting part 30 until the locking pins 32 have left the cutouts in the sole extension of the ski boot. The skier must hold down the bolt 360 in the open position during the entire disembarkation process.

In order to facilitate this exit process, the latch 360 is held in the pivoted position after the further development according to the invention by the leg 306b of the leg spring 306 (see FIGS. 15 and 18). As a result, the skier does not have to hold the latch 360 in the depressed state during the exiting process, but can be supported on the cross-country trail with his two ski poles when exiting the binding.

During this disembarkation, by pivoting up the holding shell 40 of the leg 306b, the leg spring 306 passes through with a short free travel pressed the cross bar 43 of the holding shell 40 over the locking projection 365 of the bolt 360, the locking lug 361 having already reached the upper end region of the cross bar 43 of the holding shell 40 (see FIG. 19). It is thereby achieved that the leg spring 306 is pivoted back (pressed) into its ready position when the holding shell 40 is pivoted further upwards by means of the crossbar 43 and supported by the locking spring 80.

Thus, the leg spring 306 is inevitably returned to its starting position in the event of an arbitrary exit. The above-mentioned free travel is dimensioned such that the top of the crosspiece 43 of the holding shell 40 is overlapped by the locking lug 361 of the latch 360 during the alighting process, so that re-engagement or locking is prevented (see FIGS. 19 and 20). The binding is thus prepared for a new boarding process.

The leg spring shown in FIG. 21, which corresponds to the leg spring 306 of the preceding exemplary embodiment according to FIGS. 13 to 20, is designated in its entirety by 316. This leg spring 316 is - seen from the side - approximately U-shaped. It has two legs 316a which are anchored in the swivel part 30 of the binding. The other two legs 316b are connected to one another by a crossbar 316c. This crossbar 316c is guided in the correspondingly wide groove of the bolt 360. The turns 316d of the leg spring 316, which are located between the legs 316a and 316b, are arranged on the transverse axis 20 of the ski binding mounted in the bearing block 10.

The invention is not restricted to the exemplary embodiments shown. The design of the crossbar from the holding shell with a raised area for additional securing of the bolt can also take place in the second embodiment according to FIGS. 8 to 9. Likewise, the closing force of the holding shell can also be increased in the second embodiment.

If the closing force of the holding shell is to be increased further, the position of the bolt in the open state of the binding must be stronger in its closing direction be twisted than when closed, so that the spring travel, which is covered when closing the binding, is greater. This could be achieved, for example, by means of a fillet-shaped stop milled deeper in the bolt. By means of different configurations of the bolt and crossbar, the position of the bolt can be varied when the binding is open and closed, and the size of the pivoting angle of the bolt can be changed when the binding is closed.

Furthermore, the end of the associated leg of the leg spring guided in the groove of the bolt can also be provided with a rounded, e.g. spherical, head be provided.

Claims

Patent claims:

1. Ski binding for a cross-country or touring ski with a retaining bracket (40, 40 '), which, both together with a pivoting part (30) carrying at least one locking pin (32), and relative for the purpose of transition between the closed and open positions to this is pivotally mounted about a ski-fixed, horizontal transverse axis (20), wherein in the closed position of the binding, which is fixed by a resilient bolt (60), the locking pin (32) of the pivoting part (30) into an exemption (1b, 4I 'b) the holding shell (40, 40') protrudes and the holding shell (40, 40 ') overlaps the front sole extension (101, 101') of a ski shoe (100, 100 '), while the locking pin (32) also has an opening ( 104,104 ') in the sole extension (101,101') from below, whereas in the open position of the binding the locking pin (32) is removed from the inside of the holding shell (40,400), characterized in that the joint pivoting of the holding shell (40, 40 ') and swivel part (30) about the transverse axis (20) attached to a ski-fixed bearing block (10) against an elastic element (90) that the holding shell (40, 40') and the swivel part (30 ) are each penetrated in their front area by the transverse axis (20) that the pivoting part (30) has in its front area an upwardly projecting extension (33) which carries the bolt (60) on an axis (50) which engages in the closing direction of the binding on a transverse web (43, 43 ') provided with a locking groove (43a, 43'a) of the retaining shells (40, 40'), and that a spring (70) retaining shell (40, 40 *) and swivel part (30) in the sense of spreading apart.

2. Ski binding for a cross-country or touring ski with a holding shell (40.40 '), which can be used together with at least one locking pivot pin (30) carrying the pivot pin (32), and also for the purpose of transition between the closed and open positions relative to the latter about a ski-fixed, horizontal transverse axis (20), wherein in the closed position of the binding, which is supported by a resilient bolt ( 60) is fixed, the locking pin (32) of the swivel part (30) protrudes into a free position (41b, 41'b) of the holding shell (40, 40 ') and the holding shell (40, 40') the front sole extension (101 , 1010 of a ski shoe (100, 1000 overlaps, while the locking pin (32) also penetrates an opening (104, 1040 in the sole extension (101, 101 ') from below, whereas, in the open position of the binding, the locking pin (32) from the The interior of the holding shell (40, 40 ') is removed, the joint pivoting of the holding shell (40, 400 and swivel part (30) about the transverse axis (20) attached to a ski-fixed bearing block (10) against an elastic element (90), the holding shell ( 40, 40 *) and the swivel part (30) are each penetrated in their front area by the transverse axis (20) and the swivel part (30) has in its front area an upwardly projecting extension (33) which is connected to an axis (50 ) carries the bolt (60), which engages in the closing direction of the binding on a transverse web (43, 430 of the holding shell (40, 400) provided with a locking groove (43a, 43'a), and wherein a spring (70) holding shell (40, 400 and swivel part ( 30) loaded in the sense of spreading apart, characterized in that the surface of the locking pin (32) facing the transverse axis (20) is formed from two sections (32a, 32b), of which the circular arc section adjacent to the ski (1) ( 32b) with the center of the transverse axis (20) and adjoining this by a linear section (32a) which extends obliquely away from the transverse axis (20), and that the holding shell (40,400 at the end of its side walls remote from the transverse axis (20) 42,42 ') two to L longitudinal axis of the binding converging contact surfaces (44.440 for the ski boot (100.1000 has.

3. Ski binding according to claim 2, characterized in that the contact surfaces (44,440 run symmetrically to the longitudinal axis of the binding and enclose an angle of approximately 45 ° therewith.

4. Ski boot, in particular in use with a ski binding according to claim 2, characterized in that the ski boot (100, 100 *) in its front region has lateral support surfaces (106, 1060 and in side view wedge-shaped guide surfaces (105a, 105b; 105'a, 105 'b), and in a known manner has a U-shaped hooking element (102, 1020) in plan view, which forms the opening (104, 104') between itself and the ski boot (100, 100 *), and that the crossbar (102b, 102'b ) of the hooking element (102, 1020 is cylindrical at least on its side facing the ski boot (100, 1000) (Fig. 6-9).

5. Ski boot according to claim 4, characterized in that the legs (102a) of the U-shaped hooking element (102) are surrounded by extensions (101a) of the sole extension (101) which have the guide surfaces (105a, 105b) and with connect their outer sides to the support surfaces (106) and that the extensions (101a), the end face (103) of the sole and the transverse web (102b) of the hooking element (102) enclose the opening (104) (FIGS. 6-7) ).

6. Ski boot according to claim 4, characterized in that the Einhak¬ element (1020 is surrounded at least on its outer surface with the sole material, the latter having front bevelled surfaces on its sides (102'c) which are at an angle of about 45 degrees (Fig.8-9).

7. Ski boot according to claim 4, characterized in that the Einhak¬ element has on its sides beveled surfaces which extend at an angle of about 45 degrees.

8. ski boot with ski binding according to claims 2 to 4, characterized in that the support surfaces (106, 1060 of the ski boot (100, 1000 parallel to the contact surfaces (44, 440 of the holding shell (40, 40 *)), and that the guide surfaces ( Support 105a, 105b; 105'a, 105'b) of the ski boot (100, 1000 on the bottom surface (41.410 or on guide strips (45.450 of the holding shell (40.400 (Fig. 6-9).

9. ski binding with ski boot according to claim 2 and 5, characterized gekenn¬ characterized in that the pivoting part (30) has a bottom (31) with from the longitudinal axis of the binding sloping outwardly surfaces (31 a, 31 c), and that in the front part Openings (41a) are provided in the bottom surface (41) of the holding shell (40), which are below and in front of the end face (103) of the ski boot (100) (FIGS. 1-4, 6).

10. Ski binding with a ski boot according to claim 2 and 6 or 7, characterized in that the pivoting part (30) has a bottom (31) with surfaces (31a, 31c) sloping outwards from the longitudinal axis of the binding, and in that in the side walls (420 of the holding shell (40 *) openings (42'a) are provided which lie in front of the beveled surfaces (102'c) of the sole extension (101 *) in the area of the hooking element (102 *) or the hooking element itself, which Openings (42'a) widen outwards (Fig. 1-4,8).

11. Ski binding with ski boot according to claims 2 to 4 and 8, characterized in that the hooking element (102) when getting into the binding with the ski boot (100) in the first phase of depressing the holding shell (40) along the linear section (32a) in the direction of the transverse axis (20), in the subsequent second phase, in which the support surfaces (106) of the ski boot (100) are supported on the contact surfaces (44) of the holding shell (40), continue along the linear one Section (32a), but under increasing tension, and in the last, third phase along the circular arc section (32b) under constant tension, the length of the circular arc section (32b) the hooking element (102) with the ski completely lowered the holding shell (40) projects so far that when the holding shell (40) is in the raised position - but not the pivoting part (30) - the hooking element (102) remains within the circular arc section (32b) bt (Fig.1-4).

12. Ski binding for a cross-country or touring ski with a holding shell (40), which together with at least one locking pivot pin (30) carrying the pivot pin (32), and also for the purpose of transition between the closed and open positions relative to the latter about a ski-fixed, horizontal transverse axis (20), wherein in the closed position of the binding, which is supported by a resilient bolt ( 60) is fixed, the locking pin (32) of the swivel part (30) protrudes into a free position (41b) of the holding shell (40) and the holding shell (40) overlaps the front sole extension (101) of a ski boot (100) while the locking pin ( 32) also penetrates an opening (104) in the sole extension (101) from below, whereas in the open position of the binding the locking pin (32) is removed from the inside of the holding shell (40), the joint pivoting of the holding shell (40 ) and pivoting part (30) about the transverse axis (20) fixed to a ski-fixed bearing bracket (10) against an elastic element (90), the holding shell (40) and the pivoting part (30) each in i Her front area is traversed by the transverse axis (20) and the swivel part (30) has in its front area an upwardly projecting extension (33) which carries the bolt (60) on an axis (50) which closes ¬ Direction of the binding engages on a cross bar (43) provided with a locking groove (43a) of the holding shell (40), and wherein a spring (70) loads the holding shell (40) and swivel part (30) in the sense of spreading apart, characterized that the transverse web (43) of the holding shell (40) has a raised area (43c) on its wall of the latching groove (43a) lying in the opening direction of the latch (60), the latch (60) being able to be opened arbitrarily in the direction of the ski lowered position of the holding shell (40) from the raised area (43c) is free (Fig.1-5).

13. Ski binding for a cross-country or touring ski with a holding shell (40), both with a pivoting part (30) carrying at least one locking pin (32), and also for the purpose of transition between the closed and open positions relative to the latter a ski-fixed, horizontal transverse axis (20) is pivotally mounted, wherein in the closed position of the binding, which is fixed by a resilient bolt (60), the locking pin (32) of the pivoting part (30) into one Release (41b) of the retaining shells (40) protrudes and the retaining shell (40) overlaps the front sole extension (101) of a ski boot (100), while the locking pin (32) also has an opening (104) in the sole extension (101) from below penetrates, whereas in the open position of the binding the locking pin (32) is removed from the inside of the holding shell (40), the joint pivoting of the holding shell (40) and pivoting part (30) about the transverse axis (10) fastened to a ski-fixed bearing block (10) 20) against an elastic element (90), the holding shell (40) and the swivel part (30) in each case being penetrated by the transverse axis (20) in their front area and the swivel part (30) in its front area has an upwardly projecting extension (33) which carries the bolt (60) on an axis (50) which, in the closing direction of the binding, engages a transverse web (43) of the holding shell (40) provided with a locking groove (43a) , and where e a spring (70) holding shell (40) and swivel part (30) loaded in the sense of a spreading apart, characterized in that when the binding is closed, the swivel angle () of the bolt (60) against its closing direction is approximately equal to or greater than the minimum swivel ¬ angle (ß) of the bolt (60) when opening the binding is (Fig.10-12).

14. Ski binding according to claim 13, characterized in that the position of the bolt (60) in the open and closed position of the binding is the same.

15. Ski binding according to claim 13, characterized in that the bolt (60) has a stop (63) on which the holding shell (40) abuts by means of an elevation (43d) of the crosspiece (43) when the binding is open.

16. Ski binding for a cross-country or touring ski with a holding shell (40, 400, which both together with a pivoting part (30) carrying at least one locking pin (32), as well as for the purpose of transition between the closed and open positions by one ski-fixed, horizontal transverse axis (20) is pivotally mounted, wherein in the closed position of the binding, which is fixed by a resilient bolt (360), the locking pin (32) of the pivoting part (30) into an exemption (41b, 41'b) Holding shell (40,400 protrudes and the holding shell (40,400 overlaps the front sole extension (101,101 ') of a ski boot (100,100'), while the locking pin (32) also penetrates an opening (104,1040 in the sole extension (101,101 *) from below, whereas in the open position of the binding, the locking pin (32) is removed from the inside of the retaining shells (40, 40 '), characterized in that the bolt (360) has a separate latching element (306) which can be brought into a latching and inactive position. is assigned that the latch (360) can be locked by the latching member (306) even in the position in which it releases the holding shell (40), and that this latching member is in during the exit process through the holding shell (40) ne ineffective position can be brought.

17. Ski binding for a cross-country or touring ski with a retaining bracket (40, 40 *), which both together with a pivoting part (30) carrying at least one locking pin (32), as well as for the transition between the closed and open positions is pivotably mounted relative to the latter about a ski-fixed, horizontal transverse axis (20), wherein in the closed position of the binding, which is fixed by a resilient bolt (360), the locking pin (32) of the pivoting part (30) into an exemption (41b, 41'b) of the holding shell (40,400 protrudes and the holding shell (40,40 *) overlaps the front sole extension (101,101 ') of a ski boot (100,1000), while the locking pin (32) also has an opening (104,1040 in the sole extension ( 101, 101 ') is penetrated from below, whereas in the open position of the binding the locking pin (32) is removed from the inside of the holding shell (40, 40 *), the joint pivoting of the holding shells (40, 400 and pivoting part (30) around the transverse axis (20) fastened to a ski-fixed bearing block (10) goes against an elastic element (90), the holding shell (40, 40 ') and the pivoting part (30) in each case in their front region from the transverse axis (20) enforced and the swivel part (30) has in its front region an upwardly projecting extension (33) which carries the bolt (360) on an axis (50) which, in the closing direction of the binding, has a locking groove (43a, 43 ' a) provided transverse web (43, 43 ') of the holding shell (40, 400), and wherein a spring (70) loads the holding shell (40, 40 *) and swivel part (30) in the sense of spreading apart, characterized in that the bolt ( 360) is associated with a separate latching element (306) which can be brought into a latching position and into an ineffective position such that the latch (360) can be latched by the latching element (306) even in the position in which it releases the holding shell (40) and that this locking member can be brought into its inactive position by the retaining braces (40) when getting out.

18. Sk binding according to claim 16 or 17, characterized in that the latching element is formed by an additional leg spring (306), one leg (306a) of which is supported on the holding shell (40) and the other leg (306b) with its free end is guided in a groove (364) of the bolt (360) which is rectangular in cross-section and arc-shaped in the longitudinal central section.

19. Ski binding according to claim 18, characterized in that a latching projection is arranged on the bottom of the groove (364) in its end region remote from the axis (50).

20. Ski binding according to claim 18 or 19, characterized in that the end (306c) of the leg (306b) of the leg spring (306) guided in the groove (364) of the bolt (360) is bent in a circular arc or provided with a roller.

21. Ski binding according to one of claims 18 to 20, characterized in that in each point of the arc of the groove (364) between the locking projection and the axis (50) of the bolt (360) adjacent end the tangent with a normal plane on the leg (306b) the leg spring (306) encloses an angle which is greater than the friction angle.

22. Ski binding according to claims 16 and 18 or 17 and 18, characterized in that the latching element is formed by a double leg spring (316) which is bow-shaped in plan view and whose crosspiece (316c) is in the groove (364) of the latch (360). is guided (Fig. 21).