NO346323B1 - Ski bindings - Google Patents

Description

Field of the invention

The present invention relates to a ski binding.

Background

Modern ski bindings with dedicated boots

Modern ski bindings are designed so that the boot can turn around an axis that runs under the front part of the boot and stands approximately across the longitudinal direction of the ski. The ration axis consisting of two or more parts where the elastic reset is taken care of by a dedicated element independent of the boot's axis of rotation. This is often solved by integrating a cylinder into the front part of the boot which is retained by one or more partially enclosing elements for rotation around a fixed axis. Examples of this are Rottefella NNN, Fischer Turnamic. Another well-known technique is, for example, Dynafit Tech bindings. Here, the boot's axis of rotation is taken care of through specific holes in the front of the boot's side edge, where cylinders from the binding engage and hold the boot from each side.

Boot-independent ski bindings.

There are a few manufacturers of boot-independent ski bindings on the market. Examples of this are OAC EA Universal binding (https://www.skinbased.com/product-page/oac-ea-binding) and Patrol Ski binding (http://serketusa.com/patrol-ski-binding/). Common to this type of ski bindings is that the boot is fixed to the ski independently of the boot's axis of rotation and the axis of rotation is secured by retaining one or more elements around a cylinder. A significant disadvantage of existing boot-independent ski bindings is the lack of elastic reset of the boot from a raised position to a position parallel to the ski. This means that these systems have limited spread compared to modern ski bindings with a dedicated boot as the advantage of being boot independent does not compensate for the reduction of power transfer and control over the ski that modern ski bindings with dedicated boots make possible.

US 4142734 shows a boot-independent ski binding with a "uni-flexible" soleplate which may be of plastic or other material which will easily bend about an axis lying in the plane of the soleplate, but which resists bending in a plane normal to the plane of the soleplate.

EP 2882506 describes a snowshoe where the binding joint is integrated with the snowshoe's bearing surface in a mono-construction, where the binding joint is in the form of several corrugations which provide a multiaxial joint, and which provides a snowshoe which avoids the disadvantages of snowshoes with monoaxial joints and which has a more robust construction with fewer parts.

Summary of the Invention

It is an aim of the present invention to produce a ski binding which has the advantages of the boot-independent type and which also has the advantages with regard to power transmission and control associated with boot-dependent ski bindings.

This is achieved with a ski binding as it appears from the subsequent patent claims.

More specifically, the invention comprises a ski binding with a longitudinal sole part, means for attaching a ski boot to the sole part, a fastening part designed to attach the sole part to a ski, so that the sole part extends in the longitudinal direction of the ski, as well as a monoaxial joint which hinges the sole part to the attachment part, where the joint is in the form of at least one corrugation which runs across the longitudinal axis of the sole part. Furthermore, the joint includes guides on one side of the joint which are arranged to engage in corresponding grooves on another side of the joint.

The ski binding with an integrated monoaxial joint for elastic resetting according to the invention enables the attachment of various boots for use on skis by the axis of rotation under the front part of the boot being taken care of by a device for foot attachment with an integrated monoaxial joint. By moving the axis of rotation away from the boot, the need for dedicated and specially adapted boots for the cross-country binding is also removed. This means that the binding system is independent of the boot, while at the same time the power transfer and control over the ski from the foot is taken care of. This provides good skiing technique and economy of labor also with footwear other than dedicated boots for use with ski bindings. Tests show that such a ski binding is precise in use and provides new areas of application. The ski binding according to the invention has integrated functions and thus comprises fewer parts than in the known technique and will thus reduce the risk of critical defects and reduces the complexity of production. This design of the joint stiffens the joint when the sole part is tilted up and increases the torsional stiffness of the joint.

According to a further preferred embodiment of the invention, the ski binding additionally comprises a longitudinal platform arranged to engage in a longitudinal recess on the underside of the sole part.

This design ensures good contact between binding and ski when the sole part is lifted up, and makes the binding good and stable in use.

Brief description of the drawings

The invention will now be described in detail with reference to the accompanying drawings, where:

Fig 1 shows a ski binding according to the invention seen in perspective and in a parallel arrangement,

Fig 2 shows a ski binding according to the invention seen in perspective and in an upturned arrangement,

Fig 3. shows the ski binding in Fig 1 seen from the right side,

Fig 4 shows the ski binding in Fig 2 seen from the right side,

Fig 5 shows the ski binding in Fig 1, seen from above, and

Fig 6 shows the ski binding in Fig 1, somewhat enlarged in relation to Fig 5, seen from above.

Detailed description

The present invention relates to a ski binding for foot attachment of a boot on skis, preferably cross-country skiing, for turning the boot around an axis which runs under the front part of the boot and stands approximately across the longitudinal direction of the ski and which enables elastic resetting of the boot from an upturned position to a position approximately parallel to the ski.

The ski binding comprises an integrated monoaxial link 2 which comprises one or more springy, preferably flexible and elastic corrugations 7 mainly normal to the ski's longitudinal direction and positioned so that rotation of a boot about an axis that runs under the front part of the boot is taken care of by one or more springy, preferably flexible and elastic corrugations 7, so that the rotation of a boot about an axis that runs under the front part of the boot is allowed to move with increasing torsional resistance towards a turned-up position, while at the same time elastic reset of the boot from a turned-up position to a position approximately parallel to the ski is made possible .

The purpose of the present invention is to produce a binding system where the rotation scissors with elastic reset are in an integral part and the axis of rotation under the front part of the boot is taken care of by the binding itself independently of the boot in such a way that when using this the heel of the boot can be lifted freely, where fixation of the boot is provided by a device for foot attachment, comprising an integrated monoaxial link 2 arranged to be connected to the boot, as well as a platform for connecting to skis - rear part 3 and a fastening part for connecting to skis - front part 4. The advantage of this is that the use of skis, preferably cross-country skiing, can take place without the use of dedicated boots adapted to the individual ski binding, while ski technique can be safeguarded by the elastic reset that provides a precise and improved power transfer from boot to ski. It is a well-known problem that ski boots are best used when attached to a ski. For example, they are rarely suitable for use on smooth surfaces, or in extreme cold. The use of boot-independent ski bindings thus enables an extended range of use for the boot.

The invention thus relates to a ski binding with an integrated monoaxial link, comprising a device for foot attachment 1 with an integrated monoaxial link 2 and platform for connection to skis 3 -4. This is achieved according to the invention by the fact that the ski binding's device for foot attachment 1 and integrated monoaxial joint are connected in a structural unit, a monoconstruction. The joint's axis of rotation is achieved by extension and compression as a consequence of the joint's geometry. The geometry in joint 2 comprises one or more folds which increase the mobility of the material normally in the longitudinal direction of the ski 5, and thus provide rotation of the device for foot attachment 1 so that rotation of a boot about an axis that runs under the front part of the boot is taken care of.

The ski binding's joint has freedom of movement about an axis and the joint's increasing torsional resistance is controlled through the joint's rotation angle α. By rotation angle is meant the angle between the ski 3 and the device for attaching the foot 1 in the axis for turning the boot. The angle can be between 0-60 degrees according to the horizontal plane, preferably between 5 and 45 and absolutely best between 15 and 25 degrees.

More specifically, the ski binding according to the invention comprises a device 1 for attaching the boot to the ski binding, Fig. 1. The device 1 comprises a sole part 8 which is arranged to receive the boot, the sole part being folded up along the sides and thus going around the sides and under the front part of the boot. Straps 9 are attached to the sole part 8 and go around the heel of the boot. A lace 10 is attached to the upper side of the straps 9 to fasten the boot to the ski binding.

It is also possible to use other devices to attach the boot to the ski binding, such as hoops or buckles.

In front of the sole part 1, a monoaxial joint 2 is integrated. In front of the joint 2, there is a fastening part 4 for attaching the sole part 1 to the ski 5. The joint 2 hinges the sole part 8 to the fastening part 4, and allows the sole part to be lifted up from the ski 5 at the rear edge as shown in Fig. 2 and 4. The joint 2 consists of one or more corrugations or grooves 7. The figures show a joint with a corrugation which forms a gap between the sole part 8 and the attachment part 4, and where it is placed in the gap guides 11 arranged to engage in corresponding grooves 12 on the opposite side of the slot when the sole part is tilted up (Fig. 2). This arrangement serves to stabilize the sole part when it is tilted up and reduces the load on the joint itself.

Under the sole part 1, a platform 3 is attached to the ski 5. The platform 3 comprises a wide rear part which is to support the boot heel, as well as a narrower front part which cooperates with a channel-shaped recess at the bottom of the sole part (not shown). The platform is designed to engage the recess in the sole part when the sole part rests against the ski as shown in Fig. 1 and 3. The platform can be attached to the ski with screws at the front and rear edge of the platform.

Fig. 1 shows the ski binding in perspective, and where it lies down towards the upper side of the ski 5 and Fig. 3 shows the ski binding from the opposite side, still with the sole part lying down towards the ski 5.

Fig. 2 shows the ski binding with the sole part 1 bent up from the ground. Fig. 4 shows the bond from the opposite side, and shows how it is bent up with a rotation angle α.

Fig. 5 shows a ski seen from above, where the ski is equipped with a binding according to the invention.

Fig. 6 shows the ski binding in greater detail, seen from above. The fastening part 4 comprises guides 12 arranged to engage in corresponding grooves on the opposite side of the link 2.

Claims (2)

Patent claims 1. Ski binding including: a longitudinal sole part (8), means (9, 10) for attaching a ski boot to the sole part (8), a fastening part (4) designed to fasten the sole part (8) to a ski (5), so that the sole part (8) extends in the longitudinal direction of the ski (5), a link (2) which hinges the sole part (8) to the fastening part (4), where the link (2) is in the form of at least one corrugation (7) which extends across the longitudinal axis of the sole part (8), the link (2) being a integral monoaxial joint, connected in a structural unit, a monostructure; and characterized in that the joint (2) comprises guides (11) on one side of the joint which are designed to engage in corresponding grooves (12) on the opposite side of the joint. 2. Ski binding according to claim 1, where the ski binding additionally comprises a longitudinal platform (3) arranged to engage in a longitudinal recess on the underside of the sole part (8).