The present invention relates to a plate for attaching a snowboard binding to a snowboard.
A binding is used to mount a boot onto a snowboard. In other words, a boot is mounted onto a snowboard via a binding. For the attachment of such a binding to a snowboard, a plate disclosed in Patent Document 1 may be used, for example.
The plate described above is disk-like and is made to be hard and have a predetermined thickness so as to allow for the attachment of a binding, and on a circumferential edge of a bottom face of the plate, teeth are formed in a circumferential direction. The plate also has a plurality of insertion through holes, through which screws are inserted to secure the plate to the snowboard. A bottom of the binding to be attached to the snowboard by means of the plate has a circular opening. On a circumferential edge of the opening, teeth that engage or mesh with the corresponding teeth of the plate are formed in the circumferential direction. The opening is formed to have a diameter that corresponds to the diameter of the plate and is also formed to have a depth that corresponds to the predetermined thickness of the plate.
In order to attach the binding to the snowboard by means of this plate, first, the plate is placed on the opening of the bottom of the binding at a desired angle such with both teeth meshing with each other. Then, the screw is inserted through the insertion through hole of the plate and screwed into a threaded hole formed in the snowboard. As a result, the plate presses the bottom of the binding from above and the binding is attached to the snowboard.
Patent Document 1: Japanese Patent Application Laid-open No. 2007-143727 (JP2007-143727A)
The above plate disclosed in Patent Document 1 is disk-like and hard and has a predetermined thickness. The screws that are formed from hard members and are relatively long so as to conform to the predetermined thickness of the disk-like plate are used to secure the plate to the snowboard. The flexibility of the plate is therefore impaired when the snowboard is used to glide.
Due to the impaired flexibility of the plate, the binding and the snowboard are deprived of the flexibility that the binding and the snowboard are expected to provide, and there lies a hidden problem in that the binding and the snowboard cannot demonstrate the adequate flexibility that the binding and the snowboard were originally designed to demonstrate.
The present invention has been contrived in view of the circumstances described above and an object of the present invention is to provide a plate for a snowboard binding with which flexibility of a binding and a snowboard can sufficiently be demonstrated.
A plate for a snowboard binding to achieve the object described above according to the present invention is accommodated in an opening that is formed in a bottom of the binding and has teeth on a circumferential edge of the opening, the plate serving to press the binding against the snowboard and attaching the binding to the snowboard by being secured to the snowboard by means of a screw, the plate being characterized by comprising:
a bottom having a circular shape, an insertion through hole through which the screw is inserted being formed in the bottom; a side face provided on a circumferential edge of the bottom; a flange provided on an upper edge of the side face and protruding outward in a radial direction; and teeth provided on a lower side of the flange and configured to mesh with the teeth of the binding.
The plate may include a ring, an upper surface of the ring being configured to be attached to a lower surface of the flange, the teeth of the plate for a snowboard binding being formed on a lower surface of the ring, and
an outer circumferential edge of the flange may be formed in the shape of a curved surface protruding toward an outer side in the radial direction and obliquely upward.
The plate may include a ring attached to the lower side of the flange, the teeth of the plate for a snowboard binding being formed on a lower surface of the ring, and
the flange may be inclined downward toward an outer side in the radial direction.
The teeth of the plate for a snowboard binding may be formed on a lower surface of the flange.
The side face may be inclined upward toward an outer side in the radial direction, and
an inner circumferential surface of the opening of the binding may be perpendicular to the snowboard.
The side face may be inclined upward toward an outer side in the radial direction, and
an inner circumferential surface of the opening of the binding may be inclined upward toward the outer side in the radial direction of the opening, and an inclination angle of the inner circumferential surface may be smaller than an inclination angle of the side face.
Each mountain part of the teeth of the plate for a snowboard binding may include an inclined surface inclined upward toward an inner side from a lower vertex of a radially outermost surface of the teeth to an uppermost end of the teeth on a base side, and
each valley part of the teeth of the binding may include an inclined surface configured to abut against the inclined surface of the mountain part of the teeth of the plate for a snowboard binding and being inclined downward toward an outer side from an uppermost end of an innermost surface of the teeth in the radial direction of the opening to a lowermost portion of the teeth on an outermost side in the radial direction of the opening.
The plate may include slits formed in at least one from among the bottom, the side face, and the flange.
The plate may include slits formed in the ring.
The slits may be provided in radial fashion.
A longitudinal direction of the slits may coincide with a longitudinal direction of the snowboard.
A longitudinal direction of the slits may coincide with a width direction of the snowboard.
The plate may include a hole formed in a center of the bottom.
The plate may include a plurality of ribs formed on the bottom from a circumferential edge side toward a center of the bottom.
The ribs may be provided in radial fashion.
The plate may include ribs formed on the bottom in a form of intersecting each other in an X-shape.
A hole may be formed at a portion where the ribs intersect each other in an X-shape.
The plate may include a rib formed on the bottom, a longitudinal direction of the rib coinciding with a longitudinal direction of the snowboard.
The plate may include a rib formed on the bottom, a longitudinal direction of the rib coinciding with a width direction of the snowboard.
The bottom, the side face, and the flange may be formed from a thin plate.
A material of the bottom, the side face, and the flange may be pure titanium, a titanium alloy, stainless steel, or maraging steel.
A material of the teeth of the plate for a snowboard binding may be pure titanium, a titanium alloy, stainless steel, or maraging steel.
According to the present invention, there can be provided a plate for a snowboard binding with which flexibility of a binding and a snowboard can sufficiently be demonstrated.
A plate for a snowboard binding according to embodiments of the present invention will be described below with reference to the drawings.
A plate for a snowboard binding according to a first embodiment will be described with reference to
As illustrated in
In the circular bottom 11a, there are formed a plurality of screw insertion through holes 111a through which screws 4 for securing the plate 1 to the snowboard 3 are inserted, and ribs 112a. Four such screw insertion through holes 111a are disposed in the bottom 11a at equal intervals in the circumferential direction. The screw insertion through holes 111a are each formed into the shape of a circular arc on the same circumference; accordingly, an angle at which the plate 1 is attached to the snowboard 3 using the screws 4 can be adjusted.
The ribs 112a serve to efficiently transmit force from a snowboarder (a person who glides) to the binding 2 and the snowboard 3 via the plate 1. While flexibility of the plate 1 is maintained, the plate 1 is hardened only along the longitudinal direction of the ribs 112a, and in this direction, the snowboarder can efficiently transmit force to the binding 2 and the snowboard 3 via the plate 1.
Each rib 112a is formed from the circumferential edge of the bottom 11a toward the center thereof. The rib 112a is shaped such that the rib 112a is mildly sloped and widened toward the circumferential edge side of the bottom 11a. A total of eight such ribs 112a are provided in pairs that are disposed in four locations by being separated from one another at equal intervals in the circumferential direction.
As illustrated in
Fitting holes 112c to which small protrusions 12b (described later) of the ring 12 are fit are formed in the flange 11c along the circumferential direction. The side face 11b is inclined upward toward the outer side in the radial direction of the plate 1.
As illustrated in
Now, with reference to
First, as illustrated in
Next, the plate 1 is accommodated in the opening 2a of the bottom of the binding 2 in such a manner that the teeth 12a of the plate 1 and the teeth 21a on the circumferential edge of the opening 2a of the binding 2 mesh with each other. By accommodating the plate 1 in the opening 2a of the binding 2 while adjusting the accommodation angle of the same, the binding 2 can be attached to the snowboard 3 at a desired angle.
Then, as illustrated in
Note that when it is intended to adjust the angle at which the plate 1 is attached to the snowboard 3, the screws 4 may be removed while the position of the binding 2 remains fixed and the angle of attachment of the plate 1 may be adjusted within ranges in which the positions of the circular arc-shaped screw insertion through holes 111a and the threaded holes 3a of the snowboard 3 overlap one another, after which the screws 4 may be inserted through the washers 4a and the screw insertion through holes 111a and screwed anew into the threaded holes 3a. This adjustment is carried out when, for example, it is intended to slightly adjust the disposition, angle, and so on, of the ribs 112a or the slits 111c in relation to the snowboard 3.
As described above, for the plate of the present embodiment, the plate body 11 is formed from the bottom 11a, the side face 11b, and the flange 11c such that the plate body 11 has a recessed shape, and thus the thickness of the bottom 11a of the plate body 11 can be reduced compared to conventional disk-like plates having a predetermined thickness; as a result, flexibility of the plate 1 is increased. Moreover, as a result of the bottom 11a of the plate body 11 being formed from a thin plate, the length of the screws 4 can be reduced, so flexibility of the plate 1 can be prevented from being impaired by the screws 4. Due to such an increase in the flexibility of the plate 1, the flexibility of the binding 2 and the snowboard 3 also increases, so that the flexibility according to the original design can be demonstrated and the gliding properties of the snowboard 3 can be improved.
When the snowboarder makes a turn with the snowboard 3 while gliding, the snowboard 3 is bent according to the action of leverage, where the plate 1 serves as a fulcrum joining the snowboard 3 and the binding 2. The plate of the present embodiment is highly flexible and thus, as a fulcrum, provides a loose joint between the snowboard 3 and the binding 2; therefore, restrictions on a movable range for the leg can be made relatively relaxed, and a load placed on the knee during a glide can be alleviated while the action of leverage being moderated. Furthermore, there have been situations where, for example, when having only one leg secured to the binding 2 while riding on a lift in a ski resort, fastening of the binding 2 was loosened so as to provide enough movable range for the leg and thereby alleviate the load placed on the knee; with the plate of the present embodiment, however, since the plate is highly flexible so that the load placed on the knee can be alleviated, it is possible to ride on a lift without loosening the fastening of the binding 2.
In addition, since the plate of the present embodiment has enhanced flexibility as described above, it is possible to prevent deterioration in the meshing of the teeth 12a of the plate 1 and the teeth 21a of the binding 2. In the related art, a binding is relatively flexible with respect to a poorly flexible disk-like plate, so when force acts on the plate during a glide, the binding undergoes relatively large deformation, leading to deterioration in the meshing between the teeth of the plate and the teeth of the binding. This plate 1 having enhanced flexibility can prevent such deterioration in the meshing between the teeth of the plate and the binding.
Moreover, in the plate of the present embodiment, the outer circumferential edge of the flange 11c is formed in the shape of a curved surface that protrudes toward the outer side in the radial direction of the plate 1 and obliquely upward, so also from this perspective, favorable meshing between the teeth 12a of the plate 1 and the teeth 21a of the binding 2 during a glide with the snowboard 3 can be maintained During a glide with the snowboard 3, the snowboard 3 bends from the central part toward both ends, and the plate 1 and the binding 2 also bend in conformity with the bending of the snowboard 3. Accordingly, the site at which the teeth 12a of the plate 1 and the teeth 21a of the binding 2 mesh is often inclined in such a manner that the outer side of this site in the radial direction of the plate 1 and the radial direction of the opening 2a of the binding 2 rises. As described above, the outer circumferential edge of the flange 11c of the plate 1 is formed in the shape of a curved surface that protrudes toward the outer side in the radial direction and obliquely upward, so by virtue of this flange 11c, force that presses the site, at which the teeth 12a of the plate 1 and the teeth 21a of the binding 2 mesh (which are inclined during the glide), obliquely downward from above toward the inner side in the radial direction of the plate 1 acts more readily. As a result, the meshing of the teeth 12a of the plate 1 and the teeth 21a of the binding 2 is prevented from diverging during a glide with the snowboard 3.
Moreover, since the plate of the present embodiment includes the slits 111c, flexibility of the plate can be further enhanced and, accordingly, flexibility of the binding 2 and the snowboard 3 can also be enhanced further, in addition to which deterioration in the meshing of the teeth 12a of the plate 1 and the teeth 21a of the binding 2 can be prevented to an even greater extent.
The plate of the present embodiment is provided with the ribs 112a that are disposed in four locations in the circumferential direction by being separated at equal intervals, and as illustrated in
During a glide, a snowboard may absorb dips and bumps as obstruction on the snow surface so that the snowboard undergoes unwanted bending, resulting in a deceleration in the gliding speed. According to the present embodiment, however, force is transmitted efficiently to the snowboard 3 in the longitudinal direction (X direction) by virtue of the ribs 112a, and thus absorption of the dips and bumps on the snow surface is mitigated and occurrence of unwanted bending can be limited; therefore, gliding speed can be maintained.
When a snowboard shakes, force that occurs during a turn may dissipate in different directions, resulting in the turn becoming unstable. According to the present embodiment, however, force is transmitted efficiently to the snowboard 3 in the longitudinal direction (X direction) by virtue of the ribs 112a, and thus shaking of the snowboard 3 is limited and force that occurs during a turn dissipates less readily; therefore, the turn is stabilized.
According to the present embodiment, force is transmitted efficiently to the snowboard 3 in the width direction (Y direction) by virtue of the ribs 112a, so when making a turn, the direction in which the force from the leg is transmitted deviates less readily and a shift of body weight can be controlled more easily; thus, accuracy of a turn is improved. Moreover, a superfluous shift of body weight is reduced, and thus a beneficial effect of the gliding speed being increased is achieved.
In other words, according to the present embodiment, it is possible to ensure both of the following at the same time, namely: operability that is based on the inherent flexibility of the binding 2 and the snowboard 3 as expected by a purchaser as well as on the transmission of force from the leg to the snowboard 3; and user comfort obtained as a result of a load on the knee being alleviated.
With the plate of the present embodiment, weight reduction can also be achieved due to the plate body 11 being formed into a thin plate. Moreover, with the plate of the present embodiment, if pure titanium or a titanium alloy is used for the material of the plate body 11, flexibility can be further enhanced and weight can be further reduced.
Next, a first modification of the first embodiment will be described with reference to
A second modification of the first embodiment will be described with reference to
A third modification of the first embodiment will be described with reference to
A fourth modification of the first embodiment will be described with reference to
The slits 114c are formed in the plate 1 in radial fashion, so flexibility can be enhanced in any direction of the plate 1, and accordingly, flexibility can be enhanced for the binding 2 and the snowboard 3 in any direction, in addition to which meshing between the teeth 12a of the plate 1 and the teeth 21a of the binding 2 can be maintained to be even more favorable.
A fifth modification of the first embodiment will be described with reference to
A sixth modification of the first embodiment will be described with reference to
A seventh modification of the first embodiment will be described with reference to
A plate for a snowboard binding according to a second embodiment will be described with reference to
A plate 1A of the second embodiment includes a flat flange 11d which is formed so as to be inclined downward toward the outer side in the radial direction of the plate 1A. The plate 1A is provided with the slits 116c formed in the side face 11b of the plate body 11 and the protrusions 12e that are formed on the inner surface of the ring 12 and fit to the slits 116c, as in the sixth modification. The upper surface of the ring 12 is formed in inclined fashion, and an inclination angle thereof is smaller than an inclination angle of the flange 11d.
In the present embodiment, the flange 11d is formed so as to be inclined downward at a larger inclination angle than the inclination angle of the upper surface of the ring 12, so when the binding 2 is attached to the snowboard 3 by using the plate 1A and fastening the screws 4, then as illustrated in
A plate for a snowboard binding according to a third embodiment will be described with reference to
In the third embodiment, a plate 1B does not include the ring 12, and a serrated teeth 11e is formed on the lower surface of the flange 11d integrally therewith, the teeth 11e being continuous in the circumferential direction. The teeth 21a are formed above the opening 2a of the binding 2.
When the plate 1B having the side face 11b inclined upward toward the outer side in the radial direction is secured to the snowboard 3 by being fastened using the screws 4, then as illustrated in
Note that even when the inner circumferential surface of the opening 2a of the binding 2 is inclined upward toward the outer side in the radial direction of the opening 2a, if the inclination angle thereof is smaller than the inclination angle of the side face 11b of the plate 1B, then accommodation of the plate 1B in the opening 2a of the binding 2 results in restoration force for restoring the original shape acting on the side face 11b and the flange 11d. Thus, a beneficial effect is achieved in that meshing between the teeth 11e of the plate 1B and the teeth 21a of the binding 2 is maintained to be favorable.
A plate for a snowboard binding according to a fourth embodiment will be described with reference to
Inclined surfaces 221a, which abut against the inclined surfaces 111f of the teeth 11f of the plate 1C, are formed in valley parts of the serrated teeth 22a of the binding 2. The inclined surfaces 221a are inclined downward toward the outer side in the radial direction of the opening 2a from an uppermost end of an innermost surface of the teeth 22a to a lowermost portion of the teeth 22a on the outermost side thereof. A side face 11g of the plate 1C is formed so as to be roughly perpendicular to the bottom 11a.
When the binding 2 is attached to the snowboard 3 by using the plate 1C and fastening the screws 4, then as illustrated in
Hereabove, the present invention has been described through exemplification of embodiments, but the present invention is not limited to the embodiments above, and various modifications other than the modifications described above are possible. For example, the description of the embodiments above illustrates various types of ribs 112a, 113a, 114a, and 115a, silts 111c, 114c, 115c, 116c, and 12f, a rhombic hole 113c, a circular hole 117c, and so forth, but the disposition, direction, shape, number, combination, etc. of the ribs, slits, holes, and so on can be changed, as appropriate, in accordance with, for example, basic turns and tricks as well as, for example, the purpose of gliding with the snowboard 3, e.g. a speed competition. In particular, balance in disposition, combination, and so on, of slits and holes, which enhance the flexibility of the plate, and ribs, which harden the plate only in desired directions, is to be taken into consideration.
Disposition of a slit or a hole on an inner side from the screw insertion through holes 111a in the radial direction of the plate results mainly in an enhancement of the flexibility of the snowboard 3 directly thereunder and disposition of a slit on an outer side from the screw insertion through hole 111a in the radial direction of the plate results mainly in an enhancement of the flexibility of the binding 2 near the slit; in view of this, the flexibility of each of the snowboard 3 and the binding 2 can be adjusted, as appropriate.
The embodiments above describe examples in which the plate includes slits, but even without such slits being provided, flexibility can be adequately enhanced by forming the plate into a thin plate. Further, the embodiments above describe examples in which the plate includes ribs, but in cases where, for example, it is not particularly intended to efficiently transmit force to the binding 2 and the snowboard 3 via the plate in a desired direction, there is no need to provide any ribs.
The embodiments above describe examples in which washers 4a are employed, but if, for example, the diameters of the heads of the screws 4 are made larger than the width of the screw insertion through holes 111a, it is possible not to employ any washers 4a. If no washers 4a are employed, flexibility of the plate can be further enhanced.
The embodiments above describe examples in which screw insertion through holes 111a having a circular arc shape are formed in the plate, but the screw insertion through hole 111a may be formed to be linear. If the screw insertion through holes 111a are linear, it is possible to, for example, adjust the position of the binding 2 in the longitudinal direction (X direction) or the width direction (Y direction) of the snowboard 3 when attaching the binding 2 to the snowboard 3. Further, although examples have been described in which four screw insertion through holes 111a are formed in the plate, the number of screw insertion through holes 111a is not limited to four and, for example, three or two screw insertion through holes 111a may be formed. A reduction in the number of screw insertion through holes 111a results in a reduction in the number of screws 4 so that flexibility of the plate can be enhanced.
The third embodiment above describes an example in which the side face 11b of the plate 1B is inclined upward toward the outer side in the radial direction, but the side face 11b may be formed to be perpendicular to the bottom 11a, rather than being inclined. Even if the side face 11b is not inclined, flexibility of the plate 1B is enhanced as a result of the plate 1B being formed from a thin plate, so deterioration in the meshing of the teeth 11e of the plate 1B and the teeth 21a of the binding 2 can be adequately prevented.
The teeth 12a and 11e of the plate in the first to third embodiments may be replaced with the teeth 11f of the fourth embodiment where the mountain parts include the inclined surfaces 111f and the teeth 21a of the binding 2 in the first to third embodiments may be replaced with the teeth 22a of the fourth embodiment where the valley parts include the inclined surfaces 221a, so that meshing between the teeth of the plate and the teeth of the binding are maintained to be even more favorable.
Moreover, even when the teeth of the plate is inclined upward toward the outer side in the radial direction and the teeth of the binding 2 is inclined upward toward the outer side in the radial direction of the opening 2a in the first to third embodiments, the present invention is applicable.
The first embodiment above describes an example in which, for example, a total of eight ribs 112a are provided in pairs that are disposed in four locations by being separated from one another at equal intervals in the circumferential direction of the bottom 11a of the plate 1, but the ribs 112a may be formed on the bottom 11a of the plate 1 in radial fashion. If the ribs 112a are formed in radial fashion, it is easier for the snowboarder to transmit force equally in all directions of the snowboard 3 and, for example, beneficial effects are achieved in terms of a response to turns, or the like, being improved and the gliding speed being increased.
The seventh modification of the first embodiment above describes an example in which the slits 12f are provided in four locations in the circumferential direction of the ring 12 by being separated at equal intervals, but, for example, the slits 12f may be formed in radial fashion in the ring 12 at locations where the small protrusions 12b are formed. Moreover, as described above, the disposition, direction, shape, number, combination, etc. of the slits 12f can be changed, as appropriate.
The first modification of the first embodiment above describes an example in which a rhombic hole 113c is formed at the site where the ribs 113a intersect each other in an X-shape, but it is also possible to enhance the effect demonstrated by the ribs 113a by not forming the rhombic hole 113c.
The second embodiment above describes an example in which the upper surface of the ring 12 is formed so as to be inclined, but the upper surface of the ring 12 may also not be inclined.
The embodiments above describe examples in which hexagon socket set screws 4 are employed, but, for example, cross-recess head screws, slotted head screws, square head screws, or other such screws may be employed instead.
1, 1A, 1B, 1C: plate for snowboard binding (plate)
11: plate body
11a: bottom
111a: screw insertion through hole
112a, 113a, 114a, 115a: rib
113c: rhombic hole
11b, 11g: side face
11c, 11d: flange
111c, 114c, 115c, 116c, 12f: slit
117c: circular hole
12: ring
12a, 11e, 11f: teeth
111f: inclined surface
12c, 12d, 12e: protrusion
2: binding
2a: opening
21a, 22: teeth
221a: inclined surface
3: snowboard
4: screw
Number | Date | Country | Kind |
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2017-077947 | Apr 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/003555 | 2/2/2018 | WO | 00 |