JP2004160095A - Snowboard - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a snowboard easily manufactured of a necessary minimum number of components at low cost and changing the direction of binding in a single operation without detaching a dedicated boot in the snowboard. <P>SOLUTION: This snowboard 1 is so formed that, when finishing a descent, a front-side binding 4 is fixed by clamping a first erected part 11a along with a lock means 12 so that, when the right foot is detached from a rear-side binding 3, the lock means 12 is detached from the first erected part 11a and the front-side binding 4 is turned with the left foot fixed thereto, it abuts on a second erected part 11b and stops. The front-side binding 4 is fixed with its facing frontward by clamping second erected part 11b between another unshown lock means 18 and the front-side binding 4. This constitution extremely facilitates a player to walk with the right foot kicking the snow surface and the snowboard 1 sliding thereon. When riding on a lift, if the player turns the left foot straight, the snowboard 1 also turns straight to eliminate the occurrence of a trouble and prevent any possibility of spraining the ankle. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a snowboard that can be fixed by rotating a front binding of two bindings attached to a snowboard until the binding faces the front of the snowboard.
[0002]
[Prior art]
[Patent Document 1] Japanese Patent Application Laid-Open No. 9-168626
[Patent Document 2] JP-A-2000-325527
Conventionally, the two bindings attached to the snowboard are devices for fixing the dedicated boots worn on both feet to the snowboard, and directly to the snowboard with multiple screws etc. so as to face diagonally to the longitudinal direction of the snowboard Installed. And, when you finish the downhill and try to get on the lift again, generally remove the special boot from the rear binding and free the rear foot, put the snowboard on the rear foot facing the direction of travel Walk while kicking the snow surface with boots. However, since the direction of the binding is fixed diagonally, in order to direct the snowboard in the advancing direction, the front foot has to be turned into the inner leg, making it very difficult to walk.
[0003]
Also, when riding on a lift, if you sit with your front foot facing forward, the snowboard will face diagonally, and when multiple people ride like a pair lift or triple lift, the snowboard will be They often touched the skis and felt uncomfortable with each other. In addition, the force to twist the ankle works to support the snowboard with only one foot, and there was a high risk of spraining the ankle when riding a long lift or being swung by the wind during that time.
[0004]
In order to solve such a problem, in the technique described in Patent Document 1, a disc-shaped adjustment body is interposed between the front binding body and the snowboard, and the binding body is slid on the adjustment body. A positioning member which is rotatable and has 72 engagement holes formed at 5 degrees per pitch along the outer periphery of the adjustment body, and has a front end portion which engages with these engagement holes on the left and right sides of the binding body. Have. These positioning members are urged by a spring in a direction (downward) in which the distal ends engage with the engagement holes. In a normal state, the distal ends of the positioning members engage with the engagement holes, so that the binding body is Is fixed so that it cannot slide and rotate, that is, cannot adjust its angle.
[0005]
However, a rocking member is provided at the upper end of the positioning member to lift the positioning member against the urging force of the spring. By moving the rocking member, the tip of the positioning member is separated from the engagement hole. Can be fixed. As a result, the binding body can be slid and rotated so that fine adjustment of the angle suitable for the user can be performed, and the front binding body is directed forward when walking or lifting, and the swinging member is moved forward. Can be fixed back.
[0006]
Further, in the technique described in Patent Document 2, a binding (binding) is rotatably mounted on a snowboard by a rotation shaft, and a fixing pin is provided through a pin hole provided in the binding, among a plurality of holes provided in the snowboard. It is stated that the angle of the binding with respect to the snowboard can be fixed sideways or forward by inserting it into either one.
[0007]
[Problems to be solved by the invention]
However, the technique described in Patent Literature 1 does not aim at simply changing the front binding of the snowboard from a diagonal direction in a downhill state to a forward direction suitable for walking / lift riding. The direction of the foot with respect to the longitudinal direction of the snowboard can be subtly changed depending on the inclination angle and the downhill speed of the downhill slope, or the direction of the foot can be changed finely when sliding down a half pipe when sliding down a slope Like that. Also, for beginners, the structure is such that the direction of the foot with respect to the longitudinal direction of the snowboard can be finely changed so that the angle of the foot that best suits the user can be found.
[0008]
As a result, the "angle adjustment structure of the snowboard binding" described in Patent Document 1 described above has a very complicated structure and a large number of parts, which requires technology and time for manufacturing and assembly, and is expensive. Become.
[0009]
On the other hand, in the “snowboard” described in Patent Document 2, although the structure is simple, it is considered that it is difficult to actually manufacture it because no specific mounting method of each member is described. In both the "range", "example" and "FIG. 1", it is described that the binding (binding) is fixed to the snowboard body sideways when the snowboard is used, and it seems that sliding is difficult. Furthermore, even if this "snowboard" could be manufactured, in order to change the direction of the binding, it would be necessary to remove the dedicated boot from the binding and remove and insert the fixing pin below it, which would be a laborious task. Was needed.
[0010]
Therefore, the present invention can be manufactured inexpensively and easily with the minimum necessary number of parts, and only for the purpose of changing the front binding of the snowboard from an oblique direction in a sliding state to a forward direction suitable for walking / lift riding, An object of the present invention is to provide a snowboard that can change the direction of binding with one touch without removing boots.
[0011]
[Means for Solving the Problems]
The snowboard according to the first aspect of the present invention is characterized in that at least one of the two bindings attached to the front and rear of the snowboard main body at a predetermined angle with respect to the longitudinal direction of the snowboard main body is unlocked. It is rotatable with respect to the snowboard main body until it is oriented substantially in the front-rear direction, and is locked non-rotatably by being locked in that direction. It is desirable that this rotation angle be at least within the range of 0 to 90 degrees with respect to the length direction of the snowboard body.
[0012]
As described above, the snowboard according to the present invention is different from a normal snowboard in that, for example, a rotation mechanism in a predetermined range of the front binding (a narrow range from a slidable oblique direction to a forward direction) and a lock mechanism for fixing the oblique direction. And only a lock mechanism for fixing forward is added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle. As for the rear side, only a rotation mechanism for a predetermined range of the rear binding (a narrow range from a slidable oblique direction to a forward direction), a lock mechanism for fixing the oblique direction, and a lock mechanism for fixing the front direction are added. Things. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0013]
In this way, the front binding of the snowboard can be changed from a diagonal orientation in a sliding state to a forward orientation suitable for walking / lifting, so that it can be manufactured easily and inexpensively with a minimum number of parts, and a special boot is removed. It becomes a snowboard that can change the direction of the binding with one touch.
[0014]
The snowboard according to the second aspect of the present invention has a rear binding fixed to the snowboard main body at a predetermined angle with respect to a longitudinal direction of the snowboard main body from a center of the snowboard main body to a rear side, and from a center of the snowboard main body. A base plate provided at a mounting position of a front binding from the front, a front binding rotatably provided on the base plate, and attached to one of the base plate and the front binding, and the other A lock mechanism that restrains the rotation of the front binding that can be engaged, so that only a base plate and a lock mechanism are added to a normal snowboard; In addition, the one-touch operation of releasing the lock mechanism, rotating the front binding, and restraining by the lock mechanism Planing state to the walking-lift ride state and can switch freely, there is no need to remove the dedicated boots of both sides from the binding.
[0015]
Therefore, the snowboard can be manufactured easily and inexpensively with the minimum number of components, and can change the direction of the binding with one touch without removing the dedicated boot. Therefore, when they are lined up in a row when riding a lift, they do not hit the snowboards of those who are next to them. In addition, it is possible to avoid hitting or crossing the snowboard of the next person when riding the lift, or applying a turning force to his / her ankle. Then, even during a break, the angle of the snowboard can be arbitrarily set by removing only one foot.
[0016]
A snowboard according to a third aspect of the present invention is mounted on the base plate and the front binding of the second aspect, and lock mechanisms for restraining rotation of the front binding are disposed on both sides of the front binding. Therefore, in addition to the effect of the second aspect, the fixed state can be stably maintained at an arbitrary angle.
[0017]
The snowboard according to claim 4, wherein the front binding of the two bindings attached to the front and rear of the snowboard main body at a predetermined angle with respect to the longitudinal direction of the snowboard main body is unlocked, so that the snowboard is unlocked. It is rotatable until it is oriented substantially forward with respect to the main body, and is locked in that direction so that it cannot rotate.
[0018]
As described above, the snowboard according to the present invention has a rotation mechanism in a predetermined range of the front binding (a narrow range from a slidable oblique direction to a forward direction) with respect to a normal snowboard, a lock mechanism for fixing the oblique direction, Only a lock mechanism for fixing forward is added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0019]
In this way, the sole boot can be manufactured inexpensively and easily with the minimum number of parts, and only for the purpose of changing the front binding of the snowboard from the diagonal direction of the sliding state to the forward direction suitable for walking and lift riding, and special boots. It becomes a snowboard that can change the direction of binding with one touch without removing.
[0020]
The snowboard according to the invention of claim 5 is configured such that, of the two bindings attached at a predetermined angle to the longitudinal direction of the snowboard body before and after the snowboard body, the rear binding releases the lock. It is rotatable until it is oriented substantially forward with respect to the snowboard body, and is locked in that direction so that it cannot rotate.
[0021]
As described above, the snowboard according to the present invention has, with respect to a normal snowboard, a turning mechanism in a predetermined range of the rear binding (a narrow range from a slidable oblique direction to a forward direction) and a lock mechanism for fixing the oblique direction. , Only a lock mechanism for fixing forward is added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0022]
In the snowboard according to the invention of claim 6, the front and rear bindings of the two bindings attached to the front and rear of the snowboard main body at predetermined angles with respect to the longitudinal direction of the snowboard main body are unlocked. Thus, the snowboard can be rotated until it is directed substantially forward with respect to the snowboard main body, and is locked in that direction so that it cannot rotate.
[0023]
As described above, the snowboard according to the present invention is different from a normal snowboard in that the front and rear bindings have a predetermined range of rotation (a narrow range from a slidable oblique direction to a forward direction) and a lock that is fixed obliquely. Only a mechanism and a lock mechanism for fixing forward are added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0024]
In this case, the user rotates and uses only one of the front and rear bindings.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view showing an entire structure of a snowboard according to an embodiment of the present invention, in which each binding is fixed to a normal slidable state. FIG. 2A is a perspective view illustrating a fixed state of the rear binding, and FIG. 2B is a plan view illustrating a fixing member of the rear binding. FIG. 3 is a perspective view showing a fixed state of the front binding. FIG. 4 is an exploded perspective view showing a rotating structure of the front binding. FIG. 5 is an enlarged perspective view showing a method of fixing the front binding. FIG. 6 is a perspective view from the right side of the snowboard showing a state in which the front binding is turned forward and fixed. FIG. 7 is a perspective view from the left side of the snowboard showing a state in which the front binding is turned forward and fixed. FIG. 8 is a perspective view showing the entire structure in which the front binding of the snowboard according to the embodiment of the present invention is rotated forward and fixed in a state suitable for walking / lifting.
[0026]
Actually, a fixing belt for fixing a dedicated boot is attached to each binding at two places of a heel portion and a tip portion, but is not shown in FIGS. 1 to 8 as a state where the fixing belt is removed. .
[0027]
First, the overall configuration of the snowboard according to the present embodiment will be described with reference to FIG. In the snowboard 1 of the present embodiment, a plurality of metal female screws 5 are buried in the wooden body 2, and the two front and rear bindings 3, 4 are screwed to the female screw 5 with four male screws 6, respectively. Fixed by. In this manner, the snowboard 1 can be slid by fixing the dedicated boots worn on both feet to the two front and rear bindings 3 and 4 which are screwed diagonally to the snowboard body 2 with the above-mentioned fixing belt.
[0028]
Next, a detailed method of fixing the rear binding 3 will be described with reference to FIG. As shown in FIG. 2, a large through hole 8 is formed in the bottom surface of the rear binding 3, and around this through hole 8, saw-toothed engaging teeth 8 a are provided over the entire circumference. Have been. Then, a circular fixing member 7 is fitted in which the lower part is fitted into the through hole 8 and the upper part rises up around the through hole 8 to press the bottom surface of the binding 3.
[0029]
The fixing member 7 has a lower portion 7b around which a meshing tooth 7a meshing with the meshing tooth 8a of the through hole 8 is provided, and a lower portion 7b at four connection portions 7c in a plate ring shape slightly larger than the through hole 8. The upper male 7d is connected to the upper male 7d by screwing the four male screws 6 into the female female 5 through the through holes 7e formed at four places of the lower 7b. The side binding 3 is pressed down and fixed.
[0030]
Here, as shown in FIG. 2 (a), eight female screws 5 are embedded in two rows and four places at equal intervals in the mounting portion of the rear binding 3. Therefore, the position of the rear binding 3 in the longitudinal direction of the snowboard body 2 can be changed in three ways depending on which four female screws 5 are screwed with the four male screws 6. FIGS. 1 and 2A show a state in which the rear binding 3 is fixed to the rearmost part of the snowboard body 2 and is farthest from the front binding 4. Further, as shown in FIG. 2 (b), three through holes 7e formed in four places of the lower part 7b are formed by shifting three holes little by little in the longitudinal direction of the snowboard body 2. The longitudinal position of the rear binding 3 can be further finely adjusted depending on which of the three holes the male screw 6 is passed through.
[0031]
Furthermore, since the meshing teeth 8a of the through hole 8 are provided over the entire circumference, the meshing teeth 7a around the fixed member 7 mesh with the rear binding 3 regardless of the direction in which the rear binding 3 is oriented. Therefore, by turning the rear binding 3 in a desired direction, the fixing member 7 is engaged with the through hole 8 and tightened with the four male screws 6, so that the angle of the rear binding 3 with respect to the longitudinal direction of the snowboard body 2 can be freely set. Can be adjusted.
[0032]
Next, a detailed rotating structure of the front binding 4 will be described with reference to FIGS. In FIG. 4, only the bottom plate portion of the front binding 4 from which the heel portion has been removed is shown.
[0033]
As shown in FIG. 3, the front binding 4 is placed on a first disk 11 made of a steel plate having substantially the same thickness as the bottom plate of the binding 4, and rotates on the first disk 11. . Both the front binding 4 and the rear binding 3 are bilaterally symmetric when the fixed belt is removed, and both have the same structure. That is, the front binding 4 is the same member as the rear binding 3.
[0034]
Therefore, as shown in the exploded perspective view of FIG. 4, a large through hole 8 is also formed in the bottom plate of the binding 4, and around this through hole 8, a saw-toothed engaging tooth 8 a is formed all around. Are provided. In this through hole 8, a second disk 14 that has a diameter from the tip of the meshing tooth 8 a to the tip of the meshing tooth 8 a opposite by 180 degrees and that can be barely rotated in the through hole 8 is inserted. The second disk 14 is also made of a steel plate having substantially the same thickness as the bottom plate of the binding 4. Above and below the second circular plate 14, thin spacers 15, 16 having substantially the same size as the second circular plate 14 are sandwiched one by one.
[0035]
Then, the third disk 13 that is slightly larger than the second disk 14 (that is, from the through hole 8 of the binding 4) is placed on the spacer 15. The first disk 11, the spacer 16, the second disk 14, the spacer 15, and the third disk 13 are each provided with four through holes 17 through which the male screw 6 can pass at the same position. ing. On the other hand, the mounting portion of the front binding 4 of the snowboard body 2 shown in FIG. 3 is hidden by the first disk 11 and is not shown in the drawing, but like the mounting portion of the rear binding 3 described above, a metal female screw is used. Are buried at four locations in two rows at equal intervals. Therefore, the position of the front binding 4 in the longitudinal direction of the snowboard body 2 can be changed in three ways depending on which of the four internal threads is screwed with the four external threads 6.
[0036]
In this way, the first disk 11 and the spacer 16 are formed by penetrating the four through holes 17 provided in each member, screwing the four male screws 6 into any of the four female screws, and tightening. , Second disk 14, spacer 15, and third disk 13 are fixed to snowboard body 2. However, since the second disc 14 is sandwiched between the two spacers 15 and 16, the front binding 4 is fixed with a gap between the first disc 11 and the third disc 13. Instead, the state becomes free to rotate around the second disk 14.
[0037]
Here, as shown in FIG. 3, two places of the first disk 11 are cut and bent, and two standing portions 11 a and 11 b which are substantially perpendicular to the snowboard body 2 are formed. I have. Therefore, when the front binding 4 is to be rotated clockwise when viewed from above, the right side surface is stopped by contacting the first upright portion 11a, and when the front binding 4 is to be rotated counterclockwise when viewed from above, the left side is left. The surface comes into contact with the second upright portion 11b and is stopped. Therefore, the front binding 4 is rotatable only within a range from the first standing portion 11a to the second standing portion 11b. This rotation angle is in the range of 0 to 90 degrees with respect to the length direction of the snowboard body.
[0038]
FIG. 3 shows a thin plate-shaped locking means 12 made of a steel plate rotatably attached to the bottom plate side surface 4a of the front binding 4 at that position where the front binding 4 abuts on the first standing portion 11a. Indicates a locked state in which rotation is impossible. As a result, the front binding 4 is fixed in an oblique direction with respect to the snowboard main body 2 and becomes slidable.
[0039]
The fixed state of the front binding 4 will be described in more detail with reference to FIG. As shown in FIG. 5, a short plate-like member 12b is fixed to the lock means 12 with an interval therebetween, and the first upright portion 11a is sandwiched between the lock means 12 and the short plate-like member 12b. However, the short plate-like member 12b is provided for fixing the contact member 12a therebetween, and the contact member 12a locks the lock means 12 in a vertical plane in a counterclockwise direction in the drawing. When the lock means 12 is rotated, the lock means 12 comes into contact with the surface of the first disk to stop the lock means 12 in a substantially horizontal state.
[0040]
What actually sandwiches the first standing portion 11a between the locking means 12 and the locking means 12 is a tip end portion of a fixing belt attaching bolt (not shown) hidden behind the first standing portion 11a. That is, before the bottom right side 4a of the front binding 4 actually contacts, the tip of the fixing belt mounting bolt mounted in the square hole of the bottom right side 4a comes into contact with the first upright portion 11a. And no longer rotate. Therefore, the first standing portion 11a is protruded from the bottom right portion 4a by an interval generated between the bottom right portion 4a and the first standing portion 11a, and is rotatable in a vertical plane. The front binding 4 can be firmly fixed in a non-rotatable manner without rattling.
[0041]
Next, a procedure for locking the front binding 4 by turning it counterclockwise will be described with reference to FIGS. First, the lock unit 12 is turned clockwise from the state of FIG. 5 to be raised, removed from the first standing portion 11a, and the lock is released. Subsequently, the front binding 4 is rotated counterclockwise when viewed from above, and is brought into contact with the second standing portion 11b. At this time, the abutting portion is not the bottom left portion 4b of the front binding 4 but the tip portion of the fixing belt attaching bolt attached to the square hole of the bottom left portion 4b. The raised locking means 12 is again laid down so as not to be in the way.
[0042]
Therefore, the lock means 18 protrudes from the bottom left part 4b by an interval generated between the bottom left part 4b and the second standing part 11b and is rotatable in a vertical plane. Can be firmly pinched, and the front binding 4 can be firmly fixed so as not to rotate without rattling. By such a simple operation, as shown in FIGS. 6 and 7, the front binding 4 is fixed facing the front of the snowboard body 2 and is in a state suitable for walking / lifting.
[0043]
A more specific use procedure will be described with reference to the overall view of FIG. When the runner finishes the descent, the front binding 4 is still fixed in an oblique direction. That is, the first upright portion 11 a is locked by being sandwiched between the locking means 12 and the front binding 4. Therefore, the two fixed belts (not shown) of the rear binding 3 are removed, and the dedicated boot worn on the rear foot (the right foot in the present embodiment) is removed from the rear binding 3. Then, while placing the right foot on the snow surface to support the weight, the locking means 12 is rotated in a vertical plane to release the locking means 12 from the first upright portion 11a, thereby releasing the lock.
[0044]
Subsequently, when the front binding 4 is rotated counterclockwise as viewed from above while the dedicated boot for the left foot is fixed, the front binding 4 comes into contact with the second standing portion 11b (not shown) and stops. The second standing portion 11 b is locked by being locked between the locking means 18 and the front binding 4 by rotating the 18 in a vertical plane. As a result, as shown in FIG. 8, the front binding 4 is fixed in a state facing the front of the snowboard body 2, so that the user can kick the snow surface with his free right foot and walk while sliding the snowboard 1 straight. It will also be very easy. Also, when riding the lift, if the left foot is directed straight, the snowboard 1 is also directed straight, so that there is no trouble and there is no risk of spraining the ankle.
[0045]
In this manner, the snowboard 1 of the present embodiment has the minimum necessary number of parts only for the purpose of changing the front binding 4 of the snowboard 1 from the oblique direction in the sliding state to the forward direction suitable for walking / lift riding. It can be manufactured easily at low cost, and the direction of the binding 4 can be changed with one touch without removing the dedicated boot.
[0046]
In the snowboard 1 according to the present embodiment, the spacers 15 and 16 are interposed between the upper and lower sides of the second disk 14 so that a gap is formed between the front binding 4 and the first and third disks 11 and 11. The front binding 4 is made rotatable around the second disk 14, but instead of using the spacers 15 and 16, only the second disk 14 is made slightly thicker so that the second disk 14 becomes thicker. The front binding 4 may be rotatable around the periphery of the front binding. This further reduces the number of parts and makes assembly easier.
[0047]
The configuration, shape, quantity, material, size, connection relationship, and the like of other portions of the snowboard 1 are not limited to the present embodiment.
[0048]
In the above-described embodiment, of the two bindings 3 and 4, the front binding 4 is unlocked so that the front binding 4 can be turned to the substantially forward direction with respect to the snowboard body 2 and locked in that direction. It is fixed so that it cannot rotate. However, when the present invention is implemented, the rear binding 3 is unlocked so that it can be turned until it is directed substantially forward with respect to the snowboard body 2, and locked in that direction, so that it cannot be turned. Can be fixed to Depending on the preference, the function of unlocking the binding on the rear side depending on the dominant foot or the health condition of the foot may be provided depending on the conditions of the lift.
[0049]
Further, in the above embodiment, the front binding 4 of the two bindings 3 and 4 is unlocked so that the front binding 4 can be turned to the substantially forward direction with respect to the snowboard body 2 and locked in that direction. By doing so, it is fixed so as not to rotate. However, when the present invention is implemented, the front and rear sides are both unlocked by the bindings 3 and 4 so that the snowboard body 2 can be turned until it is substantially in the front-rear direction. By doing so, it is fixed so as not to rotate. The other foot can be rested as a function of unlocking the front binding 4 or the rear binding 3 depending on the preference during use or the condition of the lift depending on the dominant foot or the health condition of the foot.
[0050]
The snowboard 1 according to the present embodiment includes a snowboard body 2 and a plurality of male screws 6 embedded in the snowboard body 2 at a predetermined angle with respect to the longitudinal direction of the snowboard body 2 from the center of the snowboard body 2 to the rear. The rear binding 3 screwed and fixed to the female screws 5, a plurality of female screws 5 (not shown) embedded in the mounting position of the front binding 4 from the center of the snowboard body 2 to the front, and a plurality of mounting screws at the mounting position The first disk 11, which is a metal plate provided with a plurality of through holes 17, which are placed so as to coincide with the positions of the female screws 6, and the through hole 8 surrounding all of the plurality of female screws 5, are centered. A front binding 4 that is formed, and a thin metal plate 1 that is rotatably mounted in a vertical plane at an interval from the front binding 4 on both outer sides of the front binding 4. Metal means provided with a plurality of through holes 17 which are capable of penetrating the through holes 17 and which are substantially the same size and are slightly thick, and which are positioned so as to be aligned with the plurality of female screws 5. And a third metal circle having a plurality of through-holes 17 which are larger than the through-holes 17 and are positioned so as to coincide with the plurality of female screws 5. The plate 13 and the through hole 17 of the third disk 13 pass through the through hole 17 of the second disk 14 and the through hole 17 of the first disk 11 and are screwed into the female screw 5 of the snowboard body 2. And a plurality of male screws 6 fixed together by tightening.
[0051]
Two portions of the first disk 11 are cut and each of the first disk 11 is erected substantially vertically on the snowboard body 2, and the first erected portion 11 a is a front binding 4 that rotates around the second disk 14. Abuts when it faces obliquely with respect to the longitudinal direction of the snowboard body 2 and rotates one of the pair of locking means 12 and 18 until it comes into contact with the first disk 11. Then, the first binding portion 4a is fixed diagonally by sandwiching the first standing portion 11a with the front binding portion 4, and the second standing portion 11b rotates around the second disk 14. When the moving front binding 4 faces forward with respect to the snowboard body 2, the other binding means 18 of the pair of locking means 12, 18 abuts on the first disk 11. Rotate to the front binding By sandwiching the second standing portion 11b between 4 it is intended to secure the front of the binding 4 forward.
[0052]
As described above, among the components of the snowboard 1, the components that are added to the normal snowboard 1 are the first disk 11 made of metal, the through-hole 8 formed in the front binding 4, and A substantially large through-hole is also provided in the binding, so it may be used.) A second disk 14 made of a metal, which is almost the same size as the through-hole 8 and is slightly thicker, is larger than the through-hole 8. Only a third disk 13 made of metal and a pair of thin plate-shaped locking means 12 and 18 made of metal are provided.
[0053]
Then, two portions of the first disk 11 are erected and serve as a stopper for the front binding 4 rotating on the first disk 11, and the first erected portion 11a is in a slidable state. The front binding 4 is stopped obliquely, and the first standing portion 11a is sandwiched by one locking means 12, thereby fixing the front binding 4 in a slidable state. The second standing portion 11b stops the front binding 4 in a forward direction for walking / lifting, and fixes the front binding 4 forward by sandwiching the second standing portion 11b with the other locking means 18.
[0054]
Therefore, the one-touch operation of raising the one locking means 12 and rotating the front binding 4 and lowering the other locking means 18 with the minimum necessary members allows the sliding state and the walking / lift riding state to be freely changed. It is possible to switch, and it is not necessary to remove the dedicated boot from the front binding 4 one by one.
[0055]
In this way, only the front binding 4 of the snowboard 1 can be changed from the oblique direction in the sliding state to the forward direction suitable for walking and lift riding, and can be manufactured inexpensively and easily with the minimum necessary number of components, and the dedicated boot , The snowboard 1 can change the direction of the binding 4 with one touch.
[0056]
Here, instead of making the second disk 14 slightly thicker than the binding 4 on the front side, the second disk 14 is set to have substantially the same thickness, and is provided between the second disk 14 and the first disk 11 and the third disk 13 respectively. The spacers 15 and 16 provided with through holes 17 through which the plurality of male screws 6 pass are sandwiched.
[0057]
This eliminates the need to manufacture only the second disk 14 from steel plates having different thicknesses, and all the steel plate members can be manufactured from a metal plate such as a steel plate having the same thickness as the bottom plate of the front binding 4. Cost can be further reduced. Since the spacers 15 and 16 are sandwiched between the second disk 14 and the first and third disks 11 and 13, the first, second and third disks 11 and Even if the screws 14 and 13 are firmly fixed to the female screws embedded in the snowboard body 2 by the plurality of male screws 6, there is a gap between the bottom plate of the front binding 4 and the first and third disks 11 and 13. As a result, the front binding 4 is rotatable between the two stoppers.
[0058]
Here, the spacers 15 and 16, the second and third disks 14 and 13, and the plurality of male screws 6 make the front binding 4 of the present embodiment impossible to be disengaged, and can be rotated only. A driving shaft means is formed.
[0059]
Therefore, it is possible to manufacture the front binding 4 of the snowboard 1 inexpensively and easily with a minimum number of components only for the purpose of changing the front binding 4 from the oblique direction in the sliding state to the forward direction suitable for walking and lift riding, and to use the special boot. The snowboard 1 can change the direction of the binding with one touch without removing the snowboard.
[0060]
By the way, the first disk 11 provided at the mounting position of the binding 4 on the front side from the center of the snowboard body 2 of the above embodiment is a smooth surface and the first upright portion 11a and the second The shape is not limited to a substantially circular plate, as long as it forms the upright portion 11b. The base plate may be a metal plate. Of course, it can be molded as a synthetic resin plate having a predetermined strength. Therefore, when implementing the present invention, the present invention can be implemented as a base plate provided at the mounting position of the binding 4 on the front side from the center of the snowboard body 1 to the front.
[0061]
Further, the first upright portion 11a and the lock means 12 and the second upright portion 11b and the lock means 18 of the above embodiment constitute a lock mechanism of the embodiment of the present invention. The lock mechanism is not limited to the present embodiment, but may be any mechanism that can maintain a firmly fixed state and can be easily released as needed. Further, the lock mechanism is attached to the binding 4 on the front side, but can be arranged on the first disk 11 side when the present invention is implemented. In any case, the lock mechanism for implementing the present invention is attached to one of the base plate made of the first disk 11 and the front binding 4, and the rotation of the front binding 4 engageable with the other. Any constraint may be used.
[0062]
The front binding 4 rotatably provided on the base plate made of the first disk 11 is a one on which a commercially available product can be attached, but a dedicated one can also be used. In this case, the base plate provided at the mounting position of the front binding 4 from the center of the snowboard body 2 to the front, the front binding 4 rotatably provided on the base plate, the base plate and the front binding 4 and a lock mechanism that restricts the rotation of the front binding 4 that can be engaged with the other.
[0063]
Furthermore, in the embodiment of the present invention, a configuration in which the front binding 4 is rotatable is adopted, but the same configuration can be applied to the rear binding 3.
[0064]
【The invention's effect】
As described above, the snowboard according to the first aspect of the present invention has at least one of two bindings attached at a predetermined angle to the longitudinal direction of the snowboard body before and after the snowboard body. Is unlocked so that the snowboard body can be turned substantially in the front-rear direction with respect to the snowboard body, and locked in that direction so that it cannot be turned.
[0065]
As described above, the snowboard according to the present invention has a rotation mechanism in a predetermined range of the front binding (a narrow range from a slidable oblique direction to a forward direction) with respect to a normal snowboard, a lock mechanism for fixing the oblique direction, Only a lock mechanism for fixing forward is added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0066]
Therefore, the snowboard can be manufactured easily and inexpensively with the minimum number of components, and can change the direction of the binding with one touch without removing the dedicated boot. When you're in a row when you're on the lift, you won't hit the snowboards of people next to you. In addition, it is possible to avoid hitting or crossing the snowboard of the next person when riding the lift, or applying a turning force to his / her ankle. Then, even during a break, the angle of the snowboard can be arbitrarily set by removing only one foot.
[0067]
The snowboard according to the invention of claim 2, a snowboard body, and a rear binding fixed to the snowboard body at a predetermined angle with respect to a longitudinal direction of the snowboard body from the center of the snowboard body to the rear, A base plate provided at a mounting position of the front binding from the center of the snowboard body to the front, a front binding rotatably provided on the base plate, and a base plate and the front binding mounted on the base plate. And a lock mechanism for restraining the rotation of the front binding.
[0068]
As described above, among the components of the snowboard of the present invention, only the base plate and the lock mechanism are added to the normal snowboard. By a one-touch operation of rotating and constraining by a lock mechanism, it is possible to freely switch between a slidable state and a walking / lift riding state, and it is not necessary to remove the dedicated boots on both sides from the binding.
[0069]
Therefore, the snowboard can be manufactured easily and inexpensively with the minimum number of components, and can change the direction of the binding with one touch without removing the dedicated boot. Therefore, when they are lined up in a row when riding a lift, they do not hit the snowboards of those who are next to them. In addition, it is possible to avoid hitting or crossing the snowboard of the next person when riding the lift, or applying a turning force to his / her ankle. Then, even during a break, the angle of the snowboard can be arbitrarily set by removing only one foot.
[0070]
A snowboard according to a third aspect of the present invention is mounted on the base plate and the front binding of the second aspect, and lock mechanisms for restraining rotation of the front binding are disposed on both sides of the front binding. Therefore, in addition to the effect of the second aspect, the fixed state can be stably maintained at an arbitrary angle.
[0071]
The snowboard according to the fourth aspect of the present invention is configured such that, of the two bindings of the first aspect, the front binding is unlocked so that it can be turned until it is substantially directed forward with respect to the snowboard main body. It is fixed so that it cannot rotate by being locked. As described above, the snowboard according to the present invention has a rotation mechanism in a predetermined range of the front binding (a narrow range from a slidable oblique direction to a forward direction) with respect to a normal snowboard, a lock mechanism for fixing the oblique direction, Only a lock mechanism for fixing forward is added. Therefore, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard that is low-cost, easy to walk, does not cause trouble when riding a lift, and has no fear of damaging the ankle.
[0072]
In this way, in addition to the effect of claim 1, the front binding of the snowboard can be changed from the oblique direction in the sliding state to the forward direction suitable for walking / lift riding with the minimum number of necessary parts and inexpensive. In addition, the snowboard can be easily manufactured and can change the direction of the binding with a single touch without removing the special boot.
[0073]
According to a fifth aspect of the present invention, the rear binding of the two bindings of the first aspect of the present invention is unlocked so that the rear binding is rotatable until it is directed substantially forward with respect to the snowboard body. Is locked so as not to rotate. As described above, the snowboard according to the present invention has, with respect to a normal snowboard, a turning mechanism in a predetermined range of the rear binding (a narrow range from a slidable oblique direction to a forward direction) and a lock mechanism for fixing the oblique direction. , Only a lock mechanism for fixing forward is added. Therefore, in addition to the effect of the first aspect, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard which is low-cost, easy to walk, does not cause trouble when riding a lift, and does not have to worry about damaging the ankle.
[0074]
The snowboard according to the invention of claim 6 is capable of rotating until the front and rear bindings of the two bindings of claim 1 are unlocked so that they face substantially forward with respect to the snowboard body, By being locked in that direction, it is fixed non-rotatably. As described above, the snowboard according to the present invention is different from a normal snowboard in that the front and rear bindings have a predetermined range of rotation (a narrow range from a slidable oblique direction to a forward direction) and a lock that is fixed obliquely. Only a mechanism and a lock mechanism for fixing forward are added. Therefore, in addition to the effect of the first aspect, since the number of parts is small and the structure is simple, it is possible to manufacture a snowboard which is low in cost, easy to walk, does not cause trouble when riding a lift, and does not have to worry about damaging the ankle. In this case, the user rotates and uses only one of the front and rear bindings.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an entire structure in which each binding of a snowboard according to an embodiment of the present invention is fixed to a normal slidable state.
FIG. 2A is a perspective view showing a fixed state of a rear binding, and FIG. 2B is a plan view showing a fixing member of the rear binding.
FIG. 3 is a perspective view showing a fixed state of a front binding.
FIG. 4 is an exploded perspective view showing a rotating structure of a front binding.
FIG. 5 is an enlarged perspective view showing a method of fixing the front binding.
FIG. 6 is a perspective view of the snowboard as viewed from the right side, showing a state in which the front binding is turned forward and fixed.
FIG. 7 is a perspective view from the left side of the snowboard, showing a state in which the front binding is turned forward and fixed.
FIG. 8 is a perspective view showing the entire structure in which the front binding of the snowboard according to the embodiment of the present invention is rotated forward and fixed in a state suitable for walking / lift riding.
[Explanation of symbols]
1 Snowboard
2 Snowboard body
3 Back binding
4 Front binding
5 Female thread
6 Male thread
8 Through hole
11 First disk
11a First standing part
11b Second standing part
12 Locking means
13 Third disk
14 Second disk
15, 16 spacer
17 Through hole
18 Locking means

Claims (6)

Of the two bindings attached at predetermined angles to the longitudinal direction of the snowboard body before and after the snowboard body, respectively, one or more bindings are unlocked so that the front and rear directions of the snowboard body are substantially changed. A snowboard characterized by being rotatable until it turns, and being locked in a non-rotatable manner by being locked in that direction. With the snowboard body,
A rear binding fixed to the snowboard main body at a predetermined angle with respect to the longitudinal direction of the snowboard main body from the center of the snowboard main body to the rear,
A base plate provided at a mounting position of the front binding from the center of the snowboard body to the front,
A front binding provided rotatably on the base plate;
A snowboard comprising: a lock mechanism attached to one of the base plate and the front binding and capable of engaging with the other to restrain rotation of the front binding. The snowboard according to claim 2, wherein a lock mechanism attached to the base plate and the front binding and restraining rotation of the front binding is disposed on both sides of the front binding. 2. The snowboard according to claim 1, wherein, of the two bindings, a binding that can be unlocked is provided only on a front side. 3. 2. The snowboard according to claim 1, wherein, of the two bindings, only a binding that can be unlocked is provided on a rear side. 3. 2. The snowboard according to claim 1, wherein one of the two bindings that can be unlocked is provided on both a front side and a rear side. 3.

Images