DE2364001C2 - Heel safety ski binding - Google Patents

Description

The invention relates to a heel safety ski binding with an essentially in the position of use heel supports aligned perpendicular to the ski surface and engaging the heel of the boot, the one on the ski pivotable about a transverse axis bow-shaped, which runs obliquely forward and downward Tension element is articulated, the crosspiece of which is attached to the heel pad! attached tension spring connected and along one in the direction of the heel support part or essentially perpendicular to the ski surface extending guide is performed, the plane of the tension element above the support point of the Heel support part is on the heel of the boot, resulting in an over-center position for the heel support part on Boot heel results

In DT-OS 14 78 105 there are various forms of execution represented by safety bindings of the type described above All of these ski bindings has in common that for their functionality in the position of use an over-center position of the support point of the heel support part on the boot heel in relation to the tension element in the form of tension bars horizontal plane must be set. Determine the ends of the drawbar and the support point a triangle in the over-center position. As long as this over-center position or this triangle exists, will the heel support is pressed against the boot heel and holds it on the ski. If the boot heel is raised, then the support point moves in the direction of the plane of the drawbar, reducing the height this triangle is getting smaller and smaller. At zero altitude, i.e. H. if the support point of the heel support part is in the plane of the tension bracket, the dead center has been reached. Heard shortly before reaching this dead center position if the force applied to the heel of the boot is upwards, the heel support, which is loaded by the spring, presses the heel of the boot back towards the ski. If, however, this dead center position is increased by further lifting the heel of the boot is exceeded, the heel support swivels away from the boot and the heel of the boot is released. The height of the triangle discussed above, i.e. H. the distance of the support point the heel support part on the heel from the level of the tension bow is a measure of the height elasticity of the ski binding, d. H. at a greater distance there is a greater lifting movement of the boot heel until it is triggered required than with a smaller distance.

The height of the triangle explained above or the distance between the support point and the level of the tension bracket can be done by changing the angle that the heel support in relation to the back of the boot by changing the length of the drawbar or can be changed by changing the point of application of the tension bow on the heel support.

In one of the known embodiments, a tension spring is on the one hand at the free upper end of the heel support part and on the other hand on a slide guided displaceably on the heel support by means of a Fastened set screw that allows a change in the spring tension. He grabs the sledge Drawbar on. It can be seen that when the tension of the spring is changed by means of the adjusting screw the point of application of the tension bow on the heel support and thus the distance between the support point of the heel support changed at the heel of the boot to the level of the drawbar. With a change in the release hardness the height elasticity of this bond changes. If you use this binding with unchanged dimensions for a ski boot with a higher or lower heel, the angles of the die change

23 640Oi

Trigger function determining triangle. If you go from a certain setting of the bond to a certain heel height and now uses a boot with a higher heel, the angle of the The drawbar compared to the ski is enlarged and the distance of the support point reduced to the level of the tie rod; the height of the characteristic of the release process Triangle is decreased. The way of the boot heel to reach the dead center position is

according to the invention solved in that the guide for the Cross piece of the tension element except for the part which runs essentially perpendicular to the ski surface a part at the lower end of the vertically extending part, which is directed towards the Stiefeispiize has, to which the cross piece during the triggering process before reaching the level located in the tension element Reached dead center. Due to this design, the heel safety ski binding is largely unaffected.

ringer, so that with lower height elasticity the binio is sensitive to different heel heights and undung triggers with less effort than different angular positions. of the support part opposite the lower paragraph for which this binding is a _. .

was posed. If, on the other hand, you use a thong heel, which is lower than the paragraph

for which the binding was originally set, so 15 extends perpendicular to the surface of the Skj, but only if the distance between the support point then coincides when the cross piece of the tension leather Tie bar level, whereby a greater path of the element is guided through that part of the guide

Paragraph is necessary to reach the Totpunktleje- '~ - .. ·· ..

chen. But since the spring until it reaches the dead

over the boot, as the triangle explained above does not move along the crosspiece that part of the leadership that is essentially

which is directed towards the toe of the boot. Overcoming the dead center takes place from a certain lifting height

o point position proportional to the reduction in the height of the boot heel at which the cross piece of the drawbar

If the triangle is stretched, the release force also decreases

ments reaches the second part of the guide, essentially no longer against the action of the spring, as is the case with the known ski bindings, but the dead center position is

The same conditions also occur in the other embodiment shown in the aforementioned publication, in which the release hardness 15 height of the boot heel is essentially the same due to the change in the angular position of the heel-supporting force acting on the boot heel overriding part compared to the rear part of the boot by means of because an eccentric enlargement of the distance between the support point of the heel disk, which is arranged on the heel support part, can be changed by the second part of the guide. If the heel support part is carried out in the boot heel to the transverse axis in order to be brought up to the boot, the height of the tension element which is arranged pivotably on the ski and which characterizes the triggering process increases. Different heel heights only lead to the fact that triangles, on the other hand, by adjusting the cross piece of the tension element on the different eccentric disk, the heel support part is located from the rear surfaces of the second part of the guide. Part of the boot, if the dead center position is exceeded, that is, measurements are the height of the triangle or the distance 35 different extensions of the above-mentioned support point of the support part on the boot heel to the distance between the support point and the transverse Tie bar level reduces what ^ u a reduction axis of the swiveling tension element is required, the height elasticity and the required release in order to lead to the over-screeching force at different heel heights. A change in the dead center position can also be achieved in this embodiment. In this second one, which is the height elasticity and the required part of the guide, there is no proportional release force with different heel heights if the force increases more, so that the release function is not readjusted accordingly to the binding. no longer affected by different heel heights

All previously known versions that are after.

work the basic principle explained at the beginning, in a preferred embodiment of the invention

sen the lack that with unchanged geometrical formation the part directed towards the toe of the boot closes

see dimensions of the binding parts are the height of the guide with the substantially perpendicular to the

elasticity and the force required to trigger the ski surface running part of the guide

change with the height of the boot heel and that at an angle which is greater than 90 °, to an automatic

large distance of the support point to Zugbügelebe- return of the cross piece in the first part of the

ne and thus with great height elasticity d. H. to enable at 5 ° guidance after the release process.

a large tripping path, the force required for tripping is greater than when by corresponding Angular change with constant spring force is the distance between the support point and the level of the tension bracket

In this embodiment occurs after the transition of the cross piece of the tension element from the first part of the Leadership in the second part of the lead that runs in the direction of the toe of the boot because of the inclination

is reduced. This is due to the fact that 55 this guide until reaching the dead center position until the dead center position is reached, the spring force still has a slight increase in force or the dead center

increases proportionally to the shortening of the distance between the support point and the level of the tie rod until the dead center position is achieved.

The object of the present invention is to design a ski binding of the type explained at the outset in such a way that that in a wide range neither changes in the heel height nor changes in the angular position of the Heel support part opposite the boot is an insert with constant force on the Boot heel exceeded, which depends on the slope of this second part of the guide.

A preferred embodiment of the ski binding according to the invention is characterized in that the Spring is designed as a tension spring and that the heel support part as a downwardly expanding housing formed and the spring at the upper end of the

Fluß is hinged on the height elasticity and the release force has 65 housing. In doing so, the task suspension for the spring to change the spring - this task will be displaceable starting from a heel device, i. H. the spring can with Safety ski binding of the type explained above can be connected to an adjusting screw.

It is advisable to use the guide for the crosspiece as a slot guide with two opposite one another To form slots, but the guide for the crosspiece can also be designed as a control cam, on which the crosspiece rests in the position of use due to the spring action, d. H. it's just one Control cam formed on which the crosspiece in the position of use of the binding due to the acting Forces is applied, while it can be released from the control cam after triggering, if none Forces act more. In this case, the crosspiece is not included in the guide, like this is the case with the slot guide, but rests on the guide.

So that the snow that may penetrate during the guide does not compact inside the housing and the ski binding can block, the housing is open at the bottom in a further embodiment of the invention, so that any snow that might penetrate the housing can fall out again.

A particularly simple embodiment is obtained if, according to the invention, the housing is made in one piece is made and preferably consists of an impact-resistant plastic, which is an injection molding of the housing permitted without post-processing.

The invention is shown in the drawing, for example. In this shows

F i g. 1 shows a section through a heel safety ski binding in the position of use and

F i g. 2 one of the F i g. 1 corresponding section through a modified embodiment.

On a ski 1, a tension element 3 is pivotably mounted about a pivot axis 2 transverse to the longitudinal axis of the ski, which is essentially U-shaped and engages with its crosspiece 4 on a tensioning spring 5, the other end of which is fastened inside a heel support part 6 is designed as a column-like housing 7 open at the bottom, which with a pressure piece 8 adapted to the usual heel groove on the boot heel detects the boot heel in the position of use.The interior 9 of the housing expands downwards by the tension spring attached to an adjusting screw 10 at the upper end of the housing 7 5 is a certain possibility of movement to allow, when the cross-piece 4, which is guided in an angular guide 11 ^c when Au 'ösevorgang in the guide is displaced, the Strammerfeder 5 executes a pivoting movement about its upper attachment point

The guide 11, which has two angled slots lying opposite one another in the housing 7, comprises a first or upper part 12 which extends substantially perpendicular to the ski surface. On this first or upper part of the guide 12 is followed by a second, directed obliquely towards the toe of the boot or lower part 13 of the guide. In the position of use, the crosspiece 4 is at the upper end of the first Part 12 of the guide 11 due to the tensile effect of the tension spring 5. The level at which the Tension element 3 is located in FIG. 1 denoted by 14. In the position of use, the pressure piece 8 rests on one with 15 designated support point on the boot heel. The perpendicular distance to the tension element level is with the distance arrow 16 marked The end points of the tension element 3 and the support point 15 form a Triangle, the height of which marks the release process. Below the height of the triangle, the distance is 16 to to understand.

When the stem shoulder is raised, the crosspiece 4 is counter to the action of the tensioning spring 5 along the first part 12 of the guide 11 relative to Housing 6 moved downwards, since the heel support part 6 is also raised when the boot heel is raised will. Here, the distance 16 of the support point 15 from the tension element plane 14 is reduced the support point 15 reaches the tension element plane 14 and thus the dead center position when it is exceeded ίο the heel support part 6 tilts backwards, arrives the cross piece 4 on the second part 13 of the guide 11, whereby the heel support part 6 can move away from the boot, resulting in the heel support part 6 exceeds the dead center position in that the AbiS support point 5 passes over the tension element plane 14. With Reaching the dead center is determined by the end points of the tension element 3 and the support point 15 Triangle collapsed. When the dead center position is exceeded, the heel support part 6 tips over back away.

During the movement of the cross piece 4 along the first part 12 of the guide 11, the tensioning spring 5 is constantly tensioned and thus exercises an increasing one in accordance with the lifting of the boot heel Force on the boot heel that tries to push the boot heel in the direction of ski 1 As soon as that Crosspiece 4 of the tension element 3 reaches the part 13 of the guide 11, the Kraftein takes effect on the The heel of the boot only closes slightly because of the inclined course of the part 13 of the guide 11 until the dead center position is reached. For practical use, the actual increase in force is when the part is reached 13 of the guide 11 ended. The transverse piece 4 is displaced along part 13 of the guide essentially without an increase in force until dead center is reached. At what point of part 13 of the Guide 11 the dead center is reached depends on the height of the heel and the inclination of the heel support part 7. The actual triggering process, i.e. the height elasticity and the release force are in any case not affected, provided the difference is at the sales heights does not significantly exceed the values that usually occur.

In the one shown in FIG. 1 illustrated embodiment includes part 13 of the guide with part 12 of this guide at an angle which is greater than 90 ° Return of the cross piece 4 due to the action of the tension spring 5 in the starting position in the upper Ensure part of the leadership. In this training, as already described, when the Part 13 of the leadership to the force only imperceptibly. At an angle of 90 ° between the Both parts of the leadership would immediately stop the increase in force when part i3 is reached, whereby the Boot heel with suddenly decreasing force acting on the enlargement of the distance between the The support point and the pivot axis of the tension element are released from the binding.

In the case of the FIG. 2 embodiment shown isi for guiding the cross piece 4 of the tension element I at the lower end of the housing 7, which forms the heel support part 6, a control curve 12 ', 13' formed which essentially corresponds to the course of the contour of the slot guide 11 facing the boots . Di ⁽⁶ S formation of a closed slot for de ever-present tension of Strammerfede 5, pulling the crosspiece against the control cam, nich necessary. This is against the AusführungslForm

those according to FIG. I easier as the slot guide not applicable, and in addition any possibility of a change in the release function due to ice accumulation is excluded, since an accumulation of snow is even less possible than in the embodiment according to FIG. 1.

1 sheet of drawings

Claims (9)

Patent claims: 1. Heel safety ski binding with one in the position of use essentially perpendicular to the Heel support that is aligned with the ski surface and engages the heel of the boot and that is attached to an on the Ski around a transverse axis pivotable bow-shaped, obliquely forward and downward traction element The cross piece is articulated with a tension spring attached to the heel support part connected and along one in the direction of the heel support part or substantially perpendicular to the The guide running across the ski surface is guided, the plane of the tension element being above the The support point of the heel support part on the boot heel is from which an over-center position for the heel support on the heel of the boot results in d a characterized in that the guide (11) for the cross piece (4) of the tension element (3) except that it is essentially perpendicular to the ski surface running part (12,12 *) one at the lower End of the vertically extending part (12, 12 ') adjoining part directed towards the toe of the boot (13, 13 ') to which the cross piece (4) during the triggering process before reaching the in the tension element plane located dead center 2. Heel safety ski binding according to claim 1, characterized in that the toe of the boot directed towards part (13, 13 ') of the guide with the substantially perpendicular to the ski surface Part (12, 12 ') of the guide encloses an angle which is greater than 90 ° 3. Heel safety ski binding according to claim 1 or 2, characterized in that the spring (5) is designed as a tension spring 4. heel safety ski binding uach claim 3, characterized in that the heel support (6) designed as a downwardly expanding housing (7) and the spring (5) at the upper end of the Housing is hinged 5. heel safety ski binding according to claim 4, characterized in that the suspension for the spring (5) can be moved to change the spring preload. 6. Heel safety ski binding according to one of claims 1 to 5, characterized in that the Guide for the crosspiece (4) as a slot guide (11) with two opposing slots is trained 7. Heel safety ski binding according to one of claims 1 to 5, characterized in that the Guide for the cross piece (4) is designed as a control cam (12 ', 13') on which the cross piece (4) in the position of use due to the spring action. 8. heel safety ski binding according to one of claims 4 to 7, characterized in that the Housing (7) is open at the bottom. 9. heel safety ski binding according to one of claims 4 to 8, characterized in that the Housing (7) made in one piece and preferably made of impact-resistant plastic.