Binding for cross-country skis binding comprising elastic buffer

This binding comprises an elastic buffer (20) or comparable device, designed to exert a return-motion stress on the boot when the latter is raised off the upper surface of the ski. The deformation of the elastic buffer during its compression by the boot when raised is controlled so as to avoid vertical expansion of the buffer during compression. The binding also comprises a housing (16) in which at least one part of the elastic buffer (20) may be fitted, and which has transverse dimensions greater than those of the elastic buffer.

FIELD OF THE INVENTION 
The present invention relates to a cross-country ski binding of the type 
comprising an elastic buffer, or comparable device, designed to exert 
return-motion stress on the boot when the latter is raised off the upper 
surface of the ski. 
BACKGROUND OF THE INVENTION 
A binding of this type is known, for example, from FR 2 537 010 and FR 2 
582 226. 
In FR 2 537 010 in particular, the elastic buffer is constituted by a 
tubular element whose generatrix is perpendicular to the axis of the ski, 
this configuration being designed to allow progressive resistance to the 
pivoting motion of the boot. 
In FR 2 582 226, the elastic element is constituted by a block of elastic 
material provided on the inside with honeycomb cells intended to 
facilitate its partial compression capacities during pivoting of the boot. 
In FR 2 582 226, the elastic element also comprises, on its upper external 
surface, transverse grooves designed to facilitate its deformation. 
Although these elastic elements constitute a definite improvement over 
elastic elements made of a single block of compact material, as in IT 193 
815, they do not make it possible to solve all problems, in particular 
those linked to the compression of such a block when the boot is raised. 
Indeed, this kind of compression necessarily causes the block to expand in 
directions other than the direction of compression, and this expansion 
may, after the boot has been raised a certain number of times, lead to the 
detachment of the elastic block from the binding, and to the loss of this 
block. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to solve these problems, to 
provide a cross-country ski binding and an elastic buffer securely held in 
position in the binding during cross-country skiing, and to avoid untimely 
loss of this block. 
Another object of the present invention is to assure that the elastic 
buffer returns effectively to its original shape after deformation. 
This object is achieved in the binding according to the invention by 
providing means to control the deformation of the elastic buffer during 
its compression by the boot when the latter is raised. 
Indeed, the control of the deformation of the elastic buffer during 
repeated stresses exerted on it, not only prevents the buffer from 
detaching, but also promotes an effective return to its original shape, 
while avoiding any blocking effect created by its deformation. 
According to a preferred embodiment, the buffer deformation-control means 
prevent vertical expansion of the buffer during compression, thus assuring 
that the buffer will be kept in a proper vertical position. 
The binding advantageously comprises a housing adapted to receive at least 
one part of the elastic buffer. This housing has transverse dimensions 
greater than those of the elastic buffer. This kind of arrangement permits 
transverse expansion of the elastic buffer and consequently limits 
appreciably the tendency of the buffer to "swell" vertically and to leave 
its housing.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
FIGS. 1 and 2 illustrate a hinge-type cross-country ski binding 10 attached 
to a cross-country ski 1 and incorporating an elastic buffer 20 according 
to the invention. The type of cross-country ski binding illustrated is 
already known, and is described, for example, in applicant's French Patent 
Application No. 88.111104. In this type of binding, the boot (not shown) 
is assembled to the ski while being rotatable about a pin unitary with the 
boot, the boot pin being held between a stationary jaw 11 and a movable 
jaw 12 of this binding. In this case, the movable jaw 12 is mounted on a 
carriage which may be moved longitudinally in relation to the ski and 
which can be maneuvered by use of a lever 14. The frame 15 of the binding 
delimits, moreover, a housing 16 for the elastic buffer 20, as will be 
seen below. 
The elastic buffer 20 is illustrated in more detail in FIGS. 3 to 7. 
As shown especially in FIG. 4, elastic buffer 20 comprises two parts, an 
embedded part 21 and a part 22 designed more specifically to be deformed. 
The embedded part 21 of the buffer is designed to be fitted into the 
housing 16 provided for this purpose in the frame 15 of the binding, while 
the deformation part 22 of the buffer is designed to cooperate more 
especially with the boot by means of an associated support surface 24. 
As emerges more especially from FIG. 2, the housing 16 in the frame for the 
elastic buffer 20 has transverse dimensions which are greater than those 
of the elastic buffer 20. In consequence, therefore, there is play between 
the lateral walls of the buffer 20 and the lateral walls of the housing 
16, allowing transverse expansion of the buffer 20 when compressed by the 
boot, but without hindering its penetration into the housing 16. 
It will be noted that, if this play did not exist as soon as longitudinal 
compression was exerted, transverse expansion would immobilize the buffer 
against the walls of the frame 15, thereby preventing any penetration into 
the housing 16 and thus limiting the longitudinal motion of the buffer. 
This type of arrangement thus promotes the transverse expansion of the 
elastic buffer 20 and therefore limits the tendency of the latter to 
expand or dilate vertically when compressed. In this manner, a first 
control of the deformation of the elastic buffer is obtained in a 
direction other than the direction of compression of the buffer by the 
boot (i.e., the direction indicated by arrow F in FIG. 1). 
As shown particularly in FIGS. 3 and 4, the elastic buffer comprises, in 
the zone where the embedded part 21 meets deformation part 22, a 
peripheral sealing lip 23 protruding beyond these two parts. This sealing 
lip 23 extends transversely along a dimension corresponding to the inner 
transverse dimension of housing 16, and thus ensures the sealing of this 
housing 16 with respect to the exterior. 
As illustrated more especially in FIG. 3, sealing lip 23 extends solely 
over the lateral surfaces 40 of buffer 20. 
Part 21 of the buffer, designed to be embedded into housing 16 of frame 15, 
has two lateral shoulders 26, which are designed to cooperate with the 
associated parts of the housing 16 (not shown for reasons of clarity) in 
order to support the elastic buffer in housing 16. 
As FIG. 3 illustrates in greater detail, these two support shoulders 26 of 
the buffer are as remote as possible from the support face 24 of the boot, 
so as not to hinder the compression of the elastic buffer and its 
penetration into the frame. Thus, support shoulders 26 are provided in the 
front end of the embedding part 21 of the buffer. It will be noted that 
these lateral supports could be replaced by a central support, for 
example, one installed at the extreme front end of the embedding part; 
however, the lateral arrangement of the supports is preferable, so as to 
allow an available deformation volume for the buffer in its median area. 
It will also be noted that the role of the lateral support shoulders 26 is 
to assist the elastic buffer 20 to return to its original position after 
the compression phase. Finally, it will be seen that the embedding part 21 
of the buffer has a hole 27 intended for an assembly screw which fastens 
the binding 10 to the ski. The provision of this hole 27 allows the 
binding to be delivered with the elastic buffer 20 premounted. 
The elastic buffer 20 has, on the outside of its deformation part 22, a 
series of parallel grooves 30 extending perpendicularly to the 
longitudinal direction 2 of the ski. 
As illustrated in FIGS. 3 and 4, these grooves 30 extend over both the 
lateral walls 40 and the upper wall 41 of the deformation part 22 of the 
elastic buffer. Each of these grooves 30 has, in transverse section, a 
substantially triangular shape and is inclined at an angle of about 
60.degree. with the horizontal. 
On the inside of its deformation part, the elastic buffer also has a series 
of ribs 32 extending parallel to each other (see FIGS. 5 and 7). 
As illustrated more especially in FIG. 5, these ribs 32 extend, as do 
grooves 30, perpendicular to the longitudinal direction 2 of the ski, and 
each of these ribs 32 extends in the extension of one of grooves 30. 
Furthermore, each of these ribs 32 is inclined at the same angle .alpha. 
to the horizontal as grooves 30. 
As a result and as illustrated more especially in FIG. 5, the connected 
ribs and grooves will have a single median plane 31. 
It will be noted that the inner ribs 32 are designed to exert a certain 
retention force holding the lateral walls of the elastic buffer. On the 
other hand, the outer grooves 30 are designed to allow better compression 
of the elastic buffer by arranging the different successive layers created 
between each of these grooves 30. Moreover, the triangular section of 
these grooves facilitates their closing when the elastic buffer undergoes 
compression. 
As illustrated in FIG. 6, deformation zone 22 of the upper wall 41 of the 
elastic buffer has a slight upward, transverse concavity 41a, designed to 
prevent the upward swelling of the elastic buffer during compression and 
to facilitate the penetration of the buffer into its housing when 
compressed. Furthermore, the elastic buffer has, in its deformation part, 
a substantially pyramidal shape which thins progressively toward the 
support surface 24 of the boot. Accordingly, the width 1 of the elastic 
buffer at the level of its support surface 24 is less than its width L at 
the level of its embedding zone 21. In practice, the optimal ratio 1/L was 
determined to be 75%. 
FIG. 4 illustrates that the support surface 24 of the boot is inclined to 
the horizontal at an angle .beta. of approximately 10.degree.. This 
inclination is provided to improve the contact of the elastic buffer with 
the associated support surface of the boot when the latter is put in 
position. It is also designed to allow prestressing of the elastic buffer 
on the boot. 
Finally, the elastic buffer has, fitted on the extension of its support 
surface 24 for the boot, a connecting tongue 50 extending downward and 
designed to be anchored in an associated part of the binding. 
As illustrated more specifically in FIGS. 7 and 8, this tongue 50 extends 
transversely and is recessed in relation to the lateral walls 40 of the 
buffer, and is thus completely independent of the functional part of the 
elastic buffer. Accordingly, the elastic tongue does not hinder the 
compression of the edges or lateral walls 40 of the elastic buffer. This 
connecting tongue 50 is designed to be secured in the housing using a pin 
60 (illustrated in FIG. 1 and indicated in the other Figures by its axis). 
It will be noted that, because it is anchored in the binding 50, this 
tongue 50 prevents any upward detachment of the elastic buffer when the 
boot is raised, and, therefore, when the buffer is compressed. Moreover, 
it allows the buffer 20 to be attached to the binding before the binding 
is mounted on the ski, thereby ensuring that the buffer will not be lost 
in transit. 
Finally, comparison of FIGS. 7 and 8 shows a possible modification of the 
interior structure of the elastic buffer 20 making it possible to increase 
or reduce its stiffness, as required. Such modification of stiffness may 
be effected very simply by varying the transverse thickness of the lateral 
walls 40 of this type of spring, and potentially the thickness of its 
inner ribs 32, this modification of thickness being obtainable very simply 
during molding by a simple change of the mold core.