NO154256B - Ski bindings. - Google Patents

Description

The present invention relates to ski bindings, in particular bindings for use both for special cross-country and touring ski models.

The requirements for sports equipment have become stricter than ever. Leading companies that produce ski equipment have now started to produce ski boots with plastic soles, which makes it easier to steer the skis. This ratio turns out to be of great importance, because plastic skis allow increased running speed.

The use of plastic soles in the ski boots results in a significant reduction in the weight and size of the ski bindings. Reduction of the binding components that extend outside the ski itself makes it possible to go faster, because the direct contact between the bindings and the snow is reduced. In the area where snow is in contact with the ski, it is generally in a relatively packed state,

with the result that it provides a significant braking effect and noticeable

bart inhibits the speed on contact with the bond. But the plastic sole has to some extent weakened the reliability of the connection between ski boot and ski.

Especially advantageous versions of sports ski bindings are produced today by the Adidas company. A binding of this type is made as a plate with side members which are placed at an angle to the ski's longitudinal axis. The plate size and the angle of the side members to the longitudinal axis of the ski depends on the size and shape of the toe part of the boot sole. The plate is attached to the ski with screws.

Holes have been taken out in the front part of the side members, perpendicular to the ski's longitudinal axis, for inserting a splint. A through hole, perpendicular to the boot's longitudinal axis, is taken out in the toe section of the boot. The boot is attached to the ski by inserting the splint into the holes in the side members and in the toe part of the boot sole. One end of the pin is fitted with a half-ring with a strip cut out in the middle. The side members are connected to each other in the front part by a strip which is made in one with the binding and carries a strap which holds a button on the upper surface. To loosen the binding, the strap must be torn off the button and the cotter pin must be released by applying a force perpendicular to the ski's longitudinal axis.

This binding design is advantageous because of the simple construction and because it provides greater efficiency in the kick-off. The effectiveness of the kick-off is improved because the binding does not press the toe part of the boot sole against the ski. This allows the boot to move fairly freely in the vertical plane, as the splint acts as a pivot. The movement of the boot in the vertical plane is limited by the transverse strip which connects the side members to each other.

A disadvantage of bindings of this type lies in a relatively unreliable fastening, because the main force of the skier's kick-off is transferred to the splint.

In general, the resultant force produced by the skier's motion can be resolved into components for a three-coordinate system. The maximum loads from the skier's kick-off fall within the force components situated in the horizontal plane, and especially in the horizontal component which is directed along the ski's longitudinal axis. This force component is applied to the splinter, with the result that the splinter often breaks. It should be noted that there are certain limits to increasing the splint's cross-section, because such an increase can cause another disadvantage, namely weakening of the toe part of the boot sole, which in turn can break. If the splint's cross-section is increased together with the cross-section of the toe section of the boot sole, this toe section will become stiffer, the useless force used to bend the boot sole will increase and the efficiency of the skier's kick-off will thus be reduced. In this case, the skier will waste considerable effort to no avail. Another disadvantage of the binding is that it is not easy to handle, because the skier has to place the boot in such a way that three holes line up. When this is done, it is difficult to follow the fastening operation visually.

On the basis of the above-mentioned disadvantages of ski bindings of this design, another model from the Adidas company has found increasing use today. This model is adapted to a boot that is provided with a projection on the upper surface of the toe section. The binding has the form of a plate with side members arranged at an angle to the longitudinal axis of a shaft carrying a weight arm, which carries another shaft at its other end. The second shaft carries a second weight bar, and the free end of the latter clamps the protrusion on the toe part of the boot sole. To secure the boot, the skier pushes the free end of the second barbell against the protrusion on the boot and presses down on the first barbell which is rotated around the first axle until the line connecting the two axles runs below the line connecting the first axle to the push point. Once this position is created, the boot is locked in place. The ski binding is advantageous, as the boot can be attached and detached without difficulty. A disadvantage of this binding, however, is the low reliability of the attachment for the boot. Cases have been reported where the protrusion on the boot has been deformed and where it comes off unintentionally (as a result of a sudden movement of the boot in the vertical plane). Another disadvantage lies in a complicated construction and rather large weight on the binding.

The rat trap binding type is widely used these days. The binding comprises a plate with side members arranged at an angle to the ski's longitudinal axis. The plate is attached to the ski with screws. The upper surface of the plate carries spikes that fit into corresponding holes in the toe section of the ski boot. Bushings built into the side members hold the ends of a hoop. A plate with grooves is placed on an axle in the front part of the binding. The boot is placed so that the holes in the toe part of the boot sole come over the spikes. The skier then presses the hoop down so that it fits into a groove in the plate in the front part of the binding. The binding is advantageous insofar as the boot is reliably held. A disadvantage of the binding lies in the fact that a significant force exerted by the hoop for locking the boot to the ski affects a significant area, with the result that the plastic sole breaks easily, usually within a year of use. Moreover, this type of binding weakens the effect of the skier's kick-off, because a lot of power is lost to bending the sole in the toe area. Another disadvantage lies in a relatively large weight, large size and complicated construction of the binding.

It thus appears from the above that the known ski bindings do not satisfy today's requirements. During the use of such bindings, significant twisting moments are formed in the horizontal and vertical plane in relation to the fasteners (screws), so that noticeable breaking forces affect the ski. The bindings are virtually impossible to remove from the ski, because they are attached with screws and sealed with glue to resist twisting moments. For this reason, a user cannot easily carry several pairs of skis, although it is common for skiers participating in major competitions to carry several pairs of skis in their luggage.

The locking device exerts a force in the vertical plane which affects a large area in the toe part of the boot sole, with the result that more force ~ st. es b "t for bending the sole during the kick-off, so that the effect of the kick-off is reduced. Twisting moments in the vertical plane cause frequent breaks in the plastic sole.

The bindings are quite heavy (48 g), complicated to produce and they are made from quite expensive alloys (where titanium or aluminum is used as the base metal), so the price is quite high. During the skier's kick-off, strong twisting moments are exerted in the vertical plane against the fasteners (screws)

and twisting moments also act in the horizontal plane during turns, so that the ski is exposed to breaking forces.

It is an aim of the present invention to eliminate the above-mentioned disadvantages and to provide a ski binding where a horizontal force component as a result of the skier's kick-off will essentially be taken up by pressure pins.

According to the present invention, there is thus provided a ski binding with pressure pins and holding device for limiting the vertical movement of the toe part of the boot sole

in relation to a ski, characterized by the fact that a part of each pressure pin intended for direct attachment to the toe part of the boot sole or to the ski is separated by means of a support plate from the other part of the pressure pin intended for reception in corresponding holes in the ski or in the boot sole.

In a preferred embodiment, the support plate is common to all push pins. Furthermore, it is preferred that said part on each pressure pin forms a non-detachable connection with the toe part or the ski, or together with said other part on the pressure pin is designed as part of the toe part or the ski.

Said holding device or holder shall serve to lock the pins in said holes, as the push pins have side holes and the holder is made in the form of splinters which are inserted into

the aforementioned holes.

The ski bin according to the present invention is designed

so that the horizontal component of the force that produ-

seen during the skier's kick-off, the pressure pins are mainly pressed on. This makes the ski binding more reliable, and its service life is extended. In addition, the twisting torque that affects the fasteners and leads to breakage of the ski is reduced. The binding's construction is simpler and the weight lower than with the known bindings, and relatively inexpensive materials can be used in their manufacture.

It is appropriate that the holes in the pressure pins are arranged above the surface of the ski, at a distance above that exceeds the thickness of the toe part of the boot sole.

With the holes arranged as discussed above, it is possible

to use holders in a simple design and allow visual observation when the bindings are put on.

It is very appropriate that the holes in the push pin

are axially in line and perpendicular to the ski's longitudinal axis. Thus, it will be possible to use a single splint that is inserted into the holes in the push pin, so that attaching the boot to the ski is noticeably simplified, and the time this takes is reduced. In addition, the area of the toe part of the boot sole that is locked by the binding can be reduced to a minimum.

The cotter pins can be attached to a plate mounted on the ski, in front of the push pin and are movable back and forth along the ski's longitudinal axis to thread into or out of the holes in the push pin when the boot is to be fastened or unfastened.

The use of the holder as discussed above allows easy attachment of the boot to the ski.

The parts of the pressure pin which project outside the toe part of the boot opening can be provided with circular grooves, whereby the holder comprises a sliding fork which is introduced into the said grooves.

This feature greatly simplifies the holder's construction and thereby reduces the price of the ski bins.

In another embodiment, a groove is arranged at an acute angle to the vertical axis and facing the ski in one side of each thrust pin, and the holder comprises at least one segment-shaped eccentric, mounted on a shaft which is mounted in the above-mentioned groove for the respective thrust pin and equipped with a stop pin, where the distance from the track to the surface of the ski exceeds

the thickness from the toe part of the boot sole.

The binding in this design allows significantly increased reliability of the boot's attachment to the ski.

In a preferred embodiment, each pressure pin consists of two parts, one which is arranged directly in the spacer body,

while the other is provided with a transverse hole and must fit into respective holes in the toe part of the boot sole.

As the pressure pin is driven directly into the spacer body,

can the push pin e.g. are produced from a material of a similar type to that of the ski, particularly with regard to the current extent of plastic ski production. This feature allows for improved reliability of the boot attachment, significantly reduces the net cost of the binding, and allows the push pin to be positioned correctly during factory production.

The above-mentioned design of the pressure pin reduces the torque caused by the skier's kick-off to a minimum and thus reduces the breaking forces affecting the ski.

The bottom part of the pressure pin, which is embedded in the skid body, can be equipped with threads. This feature allows easy disassembly of the binding from the ski and thus facilitates the transport of the skis.

The support plate that separates the upper and lower parts of the pin helps to increase the area where the binding interacts with the ski, with the result that the unit breaking force per ski unit area is reduced. The support plate can also be used for mounting several upper parts of the pressure pins for more reliable fastening of the boot.

The invention shall be described and illustrated through the following detailed description of some examples of embodiment with reference to the drawing, where

fig. 1 shows a pressure pin for a ski binding according to the invention, fig. 2 shows an exemplary embodiment of the pressure pin,

fig. 3 shows an upper part of the pressure pin,

fig. 4 shows cooperating holes in the toe part of the boot sole,

fig. 5 shows cooperating bushings mounted in the toe part of the boot sole,

fig. 6 shows an example of the design of the cooperating bushings, mounted in the toe part of the boot sole,

fig. 7 shows a possible attachment method for the pressure pins for the ski binding according to the invention,

fig. 8 shows another possible attachment method for the pressure pins

of the ski binding according to the invention,

fig. 9 further shows a possible attachment method for the pressure pins of the ski binding according to the invention,

fig. 10 shows the pressure pin inserted into a hole arranged in the boot sole,

fig. 11 shows an embodiment of a holder,

fig. 12 shows fastening of the boot with the holder shown in fig. 11,

fig. 13 is a cross-section of an exemplary embodiment of the push pin provided with a groove,

fig. 14 is a cross-section of an embodiment of the holder,

fig. 15 is a cross-section showing fastening of the boot with the pressure pins,

fig. 16 shows an embodiment of the holder, fig. 17 shows the same holder placed on the pressure pin, fig. 18 shows yet another design example of a holder, fig. 19 is a section along the line XIX-XIX in fig. 18,

fig. 20 shows a shaped pressure pin mounted on the lower surface of the toe part of the boot sole,

fig. 21 is a cross-section of the toe part of the boot sole with the pressure pin,

fig. 22 shows the pressure pin made in one with the boot sole,

fig. 23 shows another design example of the pressure pin,

fig. 24 shows a further embodiment of the pressure pin,

fig. 25 shows the toe part of the boot sole, equipped with sleeves to hold the pressure pins,

fig. 26 shows the toe part of the boot sole, where two pressure pins with attachment holes are inserted,

fig. 27 shows the toe part of the boot sole, where the pressure pin with the groove is inserted,

fig. 28 is a cross-section of a ski with grooves taken out on the outside for receiving the push pins mounted on the boot sole,

fig. 29 shows a longitudinal groove in the ski,

fig. 30 shows the same with a bush fitted in the groove,

fig. 31 shows yet another embodiment of the holder,

fig. 32 shows a further embodiment of the holder,

fig. 33 shows yet another design example of the holder, fig. a t.n. '"t following the line XXXIV-XXXIV in Fig. 33, Fig. 35 shows the push pin provided with a groove,

fig. 36 shows the same pressure pin in side view,

fig. 37 shows an embodiment of the holder,

fig. 38 shows the same holder in side view,

fig-39 shows fastening of the boot which is provided with the holder according to fig. 37-

In fig. 1, the ski binding according to the invention is designed as at least one pressure pin 1, which comprises two parts 2 and 3" which are separated by a support plate 4. The bottom part 2 is used to screw the pressure pin down into the ski body, and the upper part 3 helps to hold the toe part of a boot sole 5 (fig. 10). The upper part 3 of the push pin 1 is provided with a transverse hole 6 (fig. 1). The bottom part 2 of the push pin 1 is provided with threads, e.g. wooden screw thread, for screwing the pin into the spacer body (fig. 1 and 2). For a more precise fastening of the binding to the ski, the bottom part 2 of the pressure pin 1 can in turn comprise at least two parts 7 and 8, where the upper part 7 is used as a guide spindle, e.g. with a cylindrical shape, and where the bottom part 8 is provided with the threads (fig. 2). Otherwise, the spacer body can accommodate a cooperating bushing (not shown), which also comprises an upper guide part and a lower threaded part. The ski binding can comprise the upper part 3 of the pressure pin 1 and the support plate 4 (fig. 3), which e.g. is attached to the ski using screws. In order for the boot to be attached, the toe part of the sole 5 has shaped holes 9 (fig. 4). Metal bushings 10 (fig. 5) can be fitted into the holes 9 to give the ski binding a longer life.

The bushings 10 can be connected by a plate 11, which is attached to the toe part of the boot sole (fig. 6). Support plate 4

can carry two or three upper parts 3 for a better fit for the boot.

Fig. 7 shows two additional upper parts 3 for the pressure pin 1. The parts 3 can be placed on the support plate 4 in such a way that their longitudinal axes do not extend in line with the longitudinal axis of the pin 1 bottom part 2. A support plate 4 can carry only the upper parts 3 of the pressure pin 1 (fig. 9).

In order to attach the boot to the ski, the upper part 3 of each pressure pin 1 has a hole 6 (fig. 1), perpendicular to the longitudinal axis of the ski. The holes 6 extend in line with each other. It is appropriate that the distance between the support plate 4 and the axis of the hole 6 exceeds the thickness of the toe part of the boot sole 5 (fig. 10).

A locking member for the binding can be in the form of a splinter

12 (Fig. 11), or several cotter pins, depending on the number of holes 6 (Fig. 12), where one end of each cotter pin carries a spring-biased half-ring 13 (Fig. 11) with a web 14. Fig. 14 shows the boot attached to the ski, with the cotter pin 12 inserted into the holes 6

in the push pins 1. The spring-loaded half ring 13 grips over the upper parts 3 of the pins 1 and thus prevents lateral displacement of the pin 12.

The holes 6 can be placed at a distance above the surface of the ski that is smaller than the thickness of the toe part of the boot sole 5, so that the torque that affects the fastening device during the skier's kick-off is reduced. In this case, the locking device can be introduced or built into the sole of the ski boot 5" It is possible that a circular groove as shown in fig. 13 is taken out on the upper part 3 of the pressure pin instead of the hole 6. In order for the boot to be held firmly, the toe part of the boot sole 5 can include a locking device in the form of an elastic device such as a pressure fork 16, which is either permanently built into the boot sole 5 toe section or attached to this during the fastening operation (fig. 14 and 15). The locking device can also be designed as two stoppers 17 and

18 with a spring 19 inserted between them (fig. 16).

Organs 20 used to adjust the stoppers 17 and 18 allow the skier to move the stoppers 17 and 18 in a horizontal direction within the area limited by a groove 21 taken out either in the pressure pin 1 (Fig. 17) or in the upper part of the boot - the sole 5 (fig. 16). In addition, a shaped locking device can be mounted on the surface of the ski 22 (fig. 18), where the locking device is designed as an elastic hoop 23, which is pressed down so that the half-rings 24 will enter the grooves 15 in the upper parts 3 of the pressure pin 1 (fig. 19)•

It is also possible to mount the pressure pin in the lower surface of the boot sole 5" with cooperating grooves placed on the outer surface of the ski. The locking device can be removable or it can be attached to the ski body or to the boot sole, and it can be arranged at an angle to the ski's longitudinal and lateral axes (fig. 20, 21, 22). The pressure pin 1 can be made of different materials, such as metal, which is suitably designed and mounted in the toe part of the boot sole 5. The pressure pin 1 can in particular be sealed in the toe part of the boot sole 5 during the manufacture of the latter (fig.

21). To facilitate production, the pressure pin 1 can be made of the same material as the boot sole 5 (fig. 22). The pressure pin 1 can be removable with a device that secures it in the toe part of the boot sole 5, e.g. with a thread. In this case, the push pin 1 may comprise the threaded part 8, the guide part 7, the support plate 4, a groove 15 and the part 3 which is inserted into the spacer body (fig. 23). The hole 6 (fig. 24) can be arranged instead of the groove 15 for attaching the boot. It is possible that for mounting the pressure pin 1, a cooperating hole is taken out in the toe part of the sole 5, where the metal bushing 10 is mounted (fig. 25) to provide increased strength. There may be one or two pressure pins 1 (fig. 26) mounted in the toe section of the sole 5. Fig. 27 shows the pressure pin 1 provided with a groove 15. The pressure pins 1 can be arranged on the boot sole 5 in such a way that they enclose the spacer body 22 on the outside (Fig. 28). In order for the boot to be attached, a groove 25 (fig. 29) has been taken out in the ski body. This groove 25 accommodates a bushing 26 (fig. 30) which is intended to provide increased strength and for exchange of the binding.

For securing the boot, a locking device is arranged in the form of a pin 28, which is biased by a spring 27 and is mounted in a housing 29 (fig. 31). When the boot is to be fixed, the push pin 1 is inserted into the groove 25 and the spring biased pin 28, which is acted upon by the spring 27, enters the hole 6 in the push pin 1. When the boot is to be released again, the pin 28 must be moved into a suitable position where it moves out of the hole 6 in the push pin 1. The locking device shown in fig. 31 can also be mounted in the toe part of the boot sole 5, as shown in fig. 32.

The locking device can be designed as a splinter 30 (fig. 33, 34), mounted on a plate 32 which is biased by a spring 31. The plate 32 is enclosed in a housing 33, which is placed in front of the pressure pins 1, with the holes in the pins running along the longitudinal axis of the ski 22, in line with the pins or pins 30. To secure the boot in place, the skier first uses a weight arm 34 to press the plate 32 against the tip of the ski 22, places the boots on the binding's pressure pins 1 and then releases the arm 34, whereupon the spring 31 moves the plate 32 back to its original position and the pins 30 enter the holes 6 in the push pins 1.

There is another way to fasten the ski boot. The upper part 3 of each pressure pin 1 is then provided with a groove 35 (fig. 35 and 36) which faces the ski 22 and is inclined at an acute angle to the longitudinal axis of the pressure pin 1. The distance between the groove 35 and the surface of the ski 22 exceeds the thickness of the toe part of the boot sole 5. The locking device can consist of one or two segment-shaped eccentrics 36 (fig. 37 and 38) which are articulated with a shaft 37 which enters the slot 35, and a lock 38 which locks the segment-shaped eccentrics 36. A flexible joint 39 connects the locks 38 with each other to establish control with the eccentrics.

Claims (3)

1. Ski binding with pressure pins (1) and holding device for limiting the vertical movement of the toe part of the boot sole (5) in relation to a ski (22), characterized in that a part (2) on each pressure f l.^1-- (1 ) 'suitable for direct attachment to the toe part of the boot sole \^) or to the ski (22), is separated by means of a support plate (4) from the other part (3) of the pressure pin (1) intended for reception in corresponding holes ( 9) in the ski (22) or in the boot sole (5). 2. Ski binding according to claim 1, characterized in that the support plate (4) is common to all pressure pins (1). 3. Ski binding according to claim 1, characterized in that the part (2) on each pressure pin (1) forms a non-detachable connection with the toe part or the ski, or together with the other part (3) on the pressure pin is designed as part of the toe part or the ski.