Release mechanism for a ski binding

Abstract

The present invention relates to a release mechanism for a ski binding system, wherein the system comprises a ski shoe wherein pins moveable in each direction are arranged and at least one intermediate spring element, wherein the pins are adapted to slide in a barrel between a protruding and a retracted position, The system comprises a frame with two vertical parts arranged on a ski, wherein each vertical part has an opening each for receiving a pin protruding sideways out of the ski shoe, two bails with claws at one end and brought together in a manipulator at the other end, wherein the claws and the manipulator are adapted so that they can move synchronously into the openings in the opposite direction of the pins.

Claims

1. A release mechanism for a ski binding system, wherein the mechanism comprises: a ski shoe wherein pins, one moveable in each direction, and at least one intermediate spring element are arranged, wherein the pins are adapted to slide in a barrel between a protruding and a retracted position, a frame with two vertical parts arranged on a ski, wherein each vertical part has an opening each for receiving a pin protruding sideways out of the ski shoe, two bails, each with one claw at one end and brought together in a manipulator at the other end, wherein the claws and the manipulator are adapted so that they can move synchronously into the openings in the opposite direction of the pins.

2. A release mechanism according to claim 1, wherein the manipulator is selected among the group comprising: rocker arm, pushbutton, toggle switch, and hook.

3. A release mechanism according to claim 1, wherein the frame constitutes a U-shaped bracket, wherein the vertical parts are attached to a horizontal part.

4. A release mechanism according to claim 1, wherein the vertical parts comprise tracks, which are configured as sloping ramps receiving, guiding and pressing the pins into the openings when the ski shoe is placed in the tracks.

5. A release mechanism according to claim 1, wherein each of the bails has an essentially longitudinal segment fixed in suitable, longitudinal tracks or channels in the binding, and wherein the bails and the manipulator are arranged in front of the frame.

6. A release mechanism according to claim 1, wherein the claws are adapted to move synchronously into the openings, when the bails are rotated about their longitudinal axes via the manipulator.

7. A release mechanism according to claim 1, wherein the manipulator is spring-biased.

8. A release mechanism according to claim 1, wherein the claws are formed by own parts or the bails in themselves.

Description

BRIEF COMMENTS ON THE DRAWINGS

(1) The above-mentioned objects as well as further objects, characteristics and advantages of the present invention, will also to a larger extent be understood by means of the following illustrative and non-limiting description and with reference to the accompanying figures of a possible embodiment of the invention, wherein:

(2) FIGS. 1a-e show a possible embodiment of the system according to the invention in perspective, partially expanded, from the side and from above, respectively,

(3) FIGS. 2a-b show the embodiment from the side and along the section A-A while the ski shoe is fixed in the binding,

(4) FIGS. 3a-b show the embodiment from the side and along the section B-B, while the ski shoe is being synchronously released from the binding,

(5) FIG. 4a corresponds to FIG. 2a, FIG. 4c shows section D-D from FIG. 4b, and FIG. 4d shows the detail F from FIG. 4d,

(6) FIGS. 5a-d correspond to FIGS. 4a-d, but now in the released state, FIG. 5c showing section E-E from FIG. 5b, and FIG. 5d shows the detail FIG. 5d,

(7) FIG. 6 shows an alternative embodiment of the bails and claws, and

(8) FIG. 7 shows yet another embodiment of the bails and claws.

DETAILED DESCRIPTION

(9) FIGS. 1a-e, FIGS. 2a-b and FIGS. 3a-b show a first embodiment of the present invention. A binding 1 comprises a U-shaped bracket 2 with two upwardly protruding, vertical parts 3, 4 adapted to receive transverse, protruding, moveable pins 11 projecting from a ski shoe 20. The pins 11 fit into holes 5 in the bracket 2. The bracket 2 can comprise tracks 6 configured as sloping ramps that receive, guide and press the pins 11 into the openings 5.

(10) Though the frame 2 is shown as a U-shaped bracket, wherein the vertical parts 3, 4 are attached to a horizontal part 16, other configurations are also imaginable, e.g. a bracket that visually looks like a 75 mm toe iron, a II-, H- or Y-shaped solution etc.

(11) The solution comprises two bails 7 each of which is provided with claws 8 at one end. At the other end, the bails 7 are configured, so that they come together in a manipulator or rocker arm 9, while simultaneously having an essentially longitudinal segment 10, which is secured in suitable, longitudinal tracks in the binding 1. When the rocker arm 9 is pressed down, as shown in 3a and b, the bails 7 are rotated about the longitudinal segments 10, causing the claws 8 to rotate synchronously towards each other. The claws 8 are configured so that the rotate into the openings 5 from the outside. The bails 7, or part of the bails 8, e.g. the longitudinal segments 10 as shown in the figures, are adapted so that they are rotated about their longitudinal axes.

(12) The rocker arm 9 can be replaced by another form of manipulator, e.g. a pushbutton, toggle switch, and hook. Manipulator means something that can be operated with the hands, but it is understood that this can also take place via a pole, by stepping on the manipulator etc. In FIGS. 1 b and c, a bias spring 17 can be seen vaguely, which biases the manipulator, and thereby also the bails 7 and the claws 8, in a predetermined position. In this case, the bails 7 and the claws 8 are biased outwardly, so that the ski shoe 20 can be stepped into the binding 1 without any kind of resistance. The function of the bias spring 17 in the shown embodiment is primarily to avoid slack and sounds, so as to offer a good user experience.

(13) FIGS. 2a-b show, from the side and along section A-A, respectively, how the pins 11 project into the holes 5 when the ski shoe is attached to the binding 1. The claws 8 can touch the end of the pins 11, but with no or insignificant force.

(14) FIGS. 3a-b show, from the side and along section B-B, respectively, how the claws 8 compress the pin 11 synchronously when the rocker arm 9 is pressed down, e.g. by manual power or by means of a pole tip. This causes the pins 11 to be compressed synchronously and out of the holes 5, so that the shoe can be released from the binding 1.

(15) The configuration of the pins 11 and the openings 5, with small tolerances and right angles as well as the minimal tolerances laterally, when the shoe is located in the space between the two upwardly protruding, vertical parts 3, 4 of the U bracket 2, means that shoe is not easily, if at all, released if the pins 11 are not synchronously compressed by the release mechanism. If only one pin 11 is pressed sufficiently far into the shoe, the geometry of the pins 11 and the openings 5 will cause the shoe to get stuck in the binding 1. As there is a risk that it will not be possible to twist the shoe out of the U bracket, it is essential that the rotation of the bails, and hence the claws 8, is synchronous, so it is ensured that both pins 11 are pressed sufficiently strongly together when the user wishes to release the ski shoe 10 from the ski (not shown) by pressing down the rocker arm 9. It is understood that a manipulator 9 and the bails 7 can also be configured, so that the synchronous compression of the claws 8 takes place when the manipulator 9 is pulled up, twisted, released or through another movement. It is also understood that the manipulator 9 can consist of several connected or interacting parts.

(16) According to the present invention, the configuration and rotation of the bails 7 and the claws 8 must be such that when the rocker arm 9 is pressed down (or optionally up), a synchronous compression of the pins 11 arises. The rotation of the claws 8 into the openings 5 must give an axial component of force sufficient to compress the pins 11 synchronously and predictably. In addition, the bails 7 and the claws 8 could have components of force that progress in other planes that the axial plane through the openings 5, depending on the hinging of the bails 7 in the binding and possibly the configuration of the claws 8. Various alternative configurations could give variations of the sizes and directions of the components of force, but, as mentioned, what is most important is that the rotation of the claws 8 into the openings 5 must give an axial component of force sufficient to compress the pins 11 synchronously and predictably.

(17) FIGS. 4a-d and FIGS. 5a-d more specifically show the binding system in interconnected and released states, respectively. Details 4d and 5d show how the ends of the bails 7 slide back and forth in holes in the rocker arm 9 when it is pressed down.

(18) FIGS. 6 and 7 show alternative embodiments of the claws 8. These can consist of own parts of various configurations or be constituted by a curved end of the bails 7.