EP0545965B1 - Buckle for shoes, in particular ski boots - Google Patents

Abstract

A buckle (1) for shoes, in particular ski-boots, has a first tensioning element (8) and a clamping lever (3) fastened to a first flap (2) and capable of pivoting transversely to the longitudinal direction of the tensioning element (8). A second tensioning element (10) can be linked to the first tensioning element (8) in one position of a plurality of adjacent positions in the longitudinal direction of the tensioning element (8). The second tensioning element (10) is fastened to a second flap (12) other than the first flap (2). The clamping lever (3) and/or the second tensioning element (10) is linked by an eccentric (13) to the respective flap (2, 12). The eccentric (13) has a bearing pin (15) movable in the longitudinal and transverse directions of the tensioning elements (8, 10), allowing precise adjustment of the whole effective length of the clamping buckle (1). The eccentric is formed of a toothed disk upon which is arranged the bearing pin (15) of the tensioning element (10) or of the clamping buckle (3). The toothed disk can be clamped against the respective flap (2, 12) by a pin (17) other than the bearing pin (15) that extends through the toothed disk (13).

Description

The invention relates to a buckle for shoes, in particular ski boots, with a first tension member and a tensioning lever which can be pivoted transversely to the longitudinal direction of the tension member and is fixed to a first tab and with the first tension member in one of a plurality of positions lying next to one another in the longitudinal direction of the tension member connectable second tension member, which second tension member is fixed on a second flap different from the first flap, the fixing on the respective flap being effected via an eccentric whose loader axis can be displaced in the longitudinal and transverse directions of the tension members.

Buckles of the type mentioned at the outset are used, for example, to lock ski boots, wherein a flap of a boot is tensioned against another rag. The closing force is introduced in the instep and shaft area essentially transversely to the longitudinal axis of the shoe and thus in the circumferential direction of the cross-sectional contour, which enables a relatively exact adaptation to the respective foot. In order to be able to apply a corresponding tension across such circumferential forces transversely to the longitudinal direction of the shoe, a relatively stable construction of the buckles is generally required, and both the fixing of the tension members and the tension members themselves are subjected to high forces. When using plastics as the material for the shell parts of the flaps to be joined together and as the material for the tensioning levers and tension members, the respective bearing points or fixing points are subjected to high stress. In particular at lower temperatures, plastics tend to become brittle, so that the anchors can be torn out to fix the tensioning lever or the tension member and the tension member can tear in the region of the articulation points.

AT-PS 304 306 already shows a buckle for ski or mountain shoes, in which the drawbar is adjustably arranged by means of an intermediate piece in a holder fastened to the locking flap. When the shoe is closed, a tensioning lever, which is arranged on the other locking flap and engages with catches, engages in the pull strap.

Tensioning buckles of the type mentioned at the outset are known in principle, ladder-like hook strips being known for connecting tension members which interact with one another in mutually different, adjacent positions. Such hook strips allow the buckle to be fixed in a plurality of positions, which, however, are offset from one another by at least the distance that is required for the teeth of such a hook strip, taking into account the required stability as the material thickness. As a result, the closing force of such buckles can only be adjusted in stages and cannot be adjusted continuously. In order to enable a continuous adjustment of the closing force in such buckles, it has become known to connect a tension member to a tensioning lever via a bolt thread. By turning such a tension member, the effective length can thus be adjusted and a certain degree of fine adjustment can be achieved in the area between the distance between adjacent hooks. Due to the curved outer contour of the shoe, it is also necessary in such designs to rotate the tension member through 360 ° in order to allow a safe engagement in the hook strip again. Such an adjustment by 360 ° corresponds to a change in length by a complete thread, so that a continuous fine adjustment is not possible even with these designs. The relative rotatability of the tension member to the tendon also leads to the fact that when the buckle is in the open position an automatic rotation can occur, which complicates the closing process of the buckle because the correct position for inserting the tension member into the hook strip of the second tension member must be sought again. Usually, flexible straps or wire brackets are used as tension members, and in such cases, relatively wide components were required in view of the required closing force.

The invention now aims to develop a buckle of the type mentioned in such a way that a continuous adjustment of the effective closing length is readily possible and at the same time a stable connection of two locking tabs is achieved with small dimensions, in particular with little expansion in the longitudinal direction of the shoe . Furthermore, the present invention aims to avoid overstressing the bearing points for such a tension member or for a tensioning lever and to ensure a certain degree of relative rotatability of the individual parts with respect to the buckle even when all buckle parts are made of plastic, without the risk of tearing to increase at such bearings. To achieve this object, the buckle according to the invention essentially consists in the fact that the eccentric is formed by a tooth plate on which the bearing axis of the tension member or the tensioning buckle is arranged, and that the tooth plate has a toothing plate with a tooth element that is different from the bearing axis penetrating axis can be clamped against the respective tab. Characterized in that the eccentric is formed by a tooth plate, on which the bearing axis of the tension member or the tensioning buckle is arranged, and that the tooth plate can be tensioned against the respective tab by means of a tension member with an axis different from the bearing axis and passing through the tooth plate created the possibility of changing the effective length of a tension member by relative rotation, such a change being made possible by means of such an eccentric.

The toothed plate can be held securely in the respectively desired position by pressing against a locking tab, and the eccentric effect results from the fact that the circumference of such a toothed plate, on which the tensioning buckle or the tension member is pivotally mounted, by rotating about the axis of the tensioning member can be moved in the longitudinal direction of the tension member or the tendon. This significantly larger scope now also leads to the fact that the bearing forces are better absorbed, and the risk of overstressing is also significantly reduced when plastic hook strips or parts of the tension member or tensioning buckle are formed. In principle, the tooth plate can be pressed against the closing flap underneath by means of a screw which engages in a nut thread connected to the closing flap. According to a preferred development of the tensioning buckle according to the invention, however, the design is such that the tensioning member for the toothed plate can be raised and lowered by a lever which is pivotably articulated on the tensioning element and supported on the toothed plate, so that the eccentric is rotated by raising and lowering the tensioning element around the axis of the tendon is facilitated or blocked.

The construction according to the invention is particularly suitable for buckles which consist exclusively of plastic parts, whereby only the respective pivot axes of the tension member on a bearing component and the pivot axis of the first tension member on the tension lever and, for example, a rod-shaped locking member for insertion into a hook strip can consist of metal. In order to ensure a high degree of stability with small dimensions in the case of such plastics, the design is advantageously made such that the first tension member connected to the tensioning lever is formed by an essentially rigid part which is curved in cross section. Such a tension member, which is curved in cross section, can have high tensile forces with small dimensions record and can also be curved in the view transversely to the direction of pull, in order to enable good adaptation to the outer contour of a shoe in this way with rigid training. The double curvature leads to a high degree of stability and tensile strength in the smallest dimensions.

As already stated above, for the rough adjustment of the closing force, the design can be made in a manner known per se so that the second tension member which can be connected to the first tension member is designed as a hook strip with a plurality of hooks lying next to one another in the longitudinal direction of the second tension member. In order not to hinder a certain amount of pivoting at the points of the fixing of the tensioning lever or tension member and to ensure an exact adjustment in each closed position of the tension member in such a design with a curved cross-section tension member and to ensure an exact adjustment, the training is advantageously made such that the first tension member in the projection onto the second tension member has an arcuate end and the second tension member has a stop corresponding to the arc shape for the first tension member in the position of the hook strip adjacent to the eccentric. In the closed position, with such a design, the two tension members can be adjusted to one another with the shortest possible adjustment and thus with a maximum closing force, an essentially closed outer contour can be achieved, which results in a lower risk of injury. The risk of injury can be further reduced by the fact that the eccentric cooperates with the hook strip and is arched in cross-section outside the area having the hooks, which moreover achieves a particularly aesthetic outer contour.

The tensioning buckle according to the invention for shoes, in particular ski boots, is explained in more detail below on the basis of exemplary embodiments schematically illustrated in the drawing. 1 shows a section through a buckle according to the invention in a partially opened state; 2 shows a view in the direction of arrow II of FIG. 1 on the buckle in the closed state, FIG. 1 showing a section along line II of FIG. 2; 3 shows an exploded view of the eccentric and the tensioning element of the tensioning buckle in the embodiment according to FIGS. 1 and 2, and FIGS. 4 and 5 show a modified embodiment of an eccentric and a tensioning element for fixing the same in or lifted off from the flap connected position.

The buckle 1 shown in FIGS. 1 and 2 comprises a clamping lever 3 fixed to a first tab 2 of a ski boot, which is pivotable about an axis 4 on an anchor component or bearing component 6 fixed to the tab 5, for example via riveting or screwing 5 is articulated. A tension member 8 is pivotally attached to the tensioning lever 3 about a further axis 7, the tension member 8 being formed by an essentially rigid and curved part, which at its end facing away from the pivot axis 7 has a locking member formed by a bolt or an axis 9 for cooperation with a second tension member 10. The first tension member 8 is hollow in the area in which the second tension member 10, which is designed as a hook strip with sawtooth-like projections 11, is immersed in or overlapped by the saw teeth 11 in cooperation with the saw teeth 11, or is overlapped by the latter. tunnel-shaped. The second tension member 10 can be fixed to a flap 12 different from the first flap 2, an eccentric 13 being provided for a displacement in the longitudinal direction of the tension members 8 and 10 for fine adjustment of the entire effective length of the tensioning buckle 1, which is formed by a toothed plate, the teeth are indicated at 14. The tooth plate or the eccentric 13, the axis denoted by 15 is penetrated by a tendon 16, the axis 17 of which is different from the axis 15 of the eccentric. The eccentric is rotatably mounted in a recess 18 of the tension member 10, which is dimensioned to accommodate the forces over a large area, the fixing in this embodiment being carried out by screwing the tension member 16 in an abutment component 19 provided in the tab 12, as is shown with reference 3 will be seen in more detail. According to the relative position of the axes 15 and 17 to each other, the tension member 10 is displaced in the direction of the double arrow 20, so that any fine adjustment of the entire effective length of the tensioning buckle is made possible. After the desired length has been set by rotating the eccentric 13 in the recess 18, the clamping member 16 is screwed into the abutment component 19 and the eccentric 13 is securely fixed on the surface of the flap 12 via the toothing 14. The distance between the Axes 15 and 17 or the maximum possible adjustment path when the eccentric is rotated is selected such that it is at least equal to the distance between two teeth 11 of the tension member 10 in order to actually enable fine adjustment over the entire area lying between two teeth 11 .

In the closed position of the tensioning buckle shown in FIG. 2, the shortest possible position is shown via the bolt 9 in cooperation with the teeth 11 of the tension member 10. It can be seen that the first, with the tension lever 3 cooperating tension member 8 has an arcuate end 21, which cooperates with a corresponding contour stop 22 of the second tension member 10, so that there is a substantially flush surface of the buckle in the closed state . In the illustration according to FIG. 2, the eccentric is also arranged in the position in which there is the shortest possible total length the tensioning buckle 1 results, as can be seen directly from the relative arrangement of the axis 15 of the eccentric plate 13 and the axis of the tensioning member 16.

In the representation according to FIG. 3, it is clearly evident that the tensioning member 16 passes through the eccentric 13 designed as a toothed plate, a thread 23 for a screw connection or fixing in the abutment component 19 being indicated. The flap 12 was not shown in this illustration for the sake of clarity.

In the embodiment according to FIGS. 4 and 5, a modified tendon is shown for the eccentric 13, which in turn is designed as a toothed plate, in which case the tendon formed by a bolt or tube 24, the axis of which is again designated 17, by one an axis 25 on the eccentric 13 pivotally articulated lever 26, which is movable in the sense of the double arrow 27, can be raised and lowered in the sense of the double arrow 28. The movement of the tension member 24 in the sense of the double arrow 28 takes place by an eccentric arrangement of the axis 25 in the lever 26, and by folding the lever 26 a component 29 connected to the tension member 24, which with the tab not shown in detail resembles the abutment component 19 is connected, is pressed against the toothing 14 and thus the eccentric 13 is securely fixed. As in the previous exemplary embodiment, the eccentric or toothed plate 13 can in turn be rotated in a recess in the tension member 10 (not shown in more detail) about the axis 15 for fine adjustment of the overall length. Furthermore, the eccentric 13 has a curved outer contour 30 which is essentially flat in the closed state.

In addition or as an alternative to fixing the tension member 10 via an eccentric with an associated possibility of fine adjustment of the relative position and thus the total length the tensioning buckle, the tensioning lever 3 or its component 6 fixed on the tab 2 can also be displaceably fixed in its position via an eccentric instead of the fixing 5.

Claims (6)

1. A buckle (1) for shoes, in particular ski boots, having a first tension member (8), having a clamping lever (3) tiltable transversely to the longitudinal direction of the tension member (8) and fixed to a first strap (2) and having a second tension member (10) which can be connected to the first tension member (8) in one of a plurality of adjacent positions in the longitudinal direction of the tension member (8), the said second tension member (10) being fixed to a second strap (12) different from the first strap (2), fixing to the respective strap (2, 12) being carried out via an eccentric (13), the bearing axis (15) of which is displaceable in the longitudinal direction and the transverse direction of the tension members, characterised in that the eccentric (13) is formed by a toothed plate on which the bearing axis (15) of the tension member (10) or clamping buckle (3) is arranged, and in that the toothed plate can be clamped against the respective strap (2, 12) via a clamping member (16) having an axis (17) passing through the toothed plate (13) and different from the bearing axis (15).
2. A buckle according to claim 1, characterised in that the clamping member (16) for the toothed plate (13) is formed so as to be raisable and lowerable by a lever (26) supported on the toothed plate (13) and tiltably articulated on the clamping member (16).
3. A buckle according to claim 1 or 2, characterised in that the first tension member (8) connected to the clamping lever (3) is formed by a substantially rigid part curved in cross-section.
4. A buckle according to claim 1, 2 or 3, characterised in that the second tension member (10), which can be connected to the first tension member (8), is formed as hooked strip having a plurality of adjacent hooks (11) in the longitudinal direction of the second tension member.
5. A buckle according to any one of claims 1 to 4, characterised in that the first tension member (8) has a rounded end (21) projecting towards the second tension member (10) and the second tension member (10) has a correspondingly rounded stop (22) for the first tension member (8) in the position on the hooked strip adjacent to the eccentric (13).
6. A buckle according to any one of claims 1 to 5, characterised in that the eccentric (13) co-operates with the hooked strip and is formed so as to be curved in cross-section outside the region having the hooks (11).

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