JPH01185277A - Surfski-board - Google Patents

Abstract

PURPOSE:To improve the sliding, turning and operating properties of a surfski- board by providing such a structure thereof, as positioning a footboard on which sliding person's feet are fitted and a sliding board at an interval and connecting the approximately middle point of the lower face of the footboard to the upper face of the sliding board by means of a pillar member. CONSTITUTION:A footboard 12 on which respective hooks 13 are fitted is attached on the upper face of a sliding board 11. The footboard 12 is attached to a prescribed position near the middle point of the sliding board 11 with hooks 13 arranged in parallel in the longitudinal direction of the sliding board 11. Then, the way of attaching the footboard 12 is not to attach the footboard 12 directly on the sliding board 11 but to attach it thereon by interposing a pillar member 14 between the footboard 12 and the sliding board 11. The upper end of the pillar member 14 is fixed to approximately the center of the lower face of the footboard 12 and its lower end is fixed to the upper face of the sliding board 11. The pillar member 14 is formed as short as possible in the longitudinal direction of the sliding board 11 and not as protruding laterally from the sliding board 11. The width of the pillar member 14 is preferably about one third of that of the sliding board 11.

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Field of Application> The present invention relates to the structure of a surf skiboard.

<Problems to be Solved by the Present Invention> In skis, only one foot of the skier is attached to the center of one of the skis.

Therefore, the load is mainly applied to one point in the center of the two skis, and the front and rear ends of the skis can flex vertically relatively freely.

Therefore, during rotational skiing, the front and rear ends of the skis bend upward, so the skis come into contact with the snow surface at one point, and the contact area with the snow surface is extremely small, reducing frictional resistance.

Therefore, the rotational performance of the ski is improved.

Furthermore, since the front and rear ends of the ski do not receive much load, they can flexibly move up and down in accordance with the unevenness of the snow surface, and can effectively absorb the vertical movement of the entire ski due to the unevenness of the snow surface.

Furthermore, by shifting your weight forward, the rear end of the ski rises, concentrating the load and reducing frictional resistance, increasing your skiing speed; conversely, by shifting your weight backward, you , the sliding speed can be controlled.

Based on the above, if we consider the case of a conventional surf ski board, we will find that in a conventional surf ski board, the rider places both feet at intervals in the longitudinal direction of the upper surface of the two sliding boards. It is something to do.

Therefore, a load is applied to the sliding board at two points spaced apart, and the load is distributed over the entire sliding board.

Therefore, the sliding board becomes like a single hard plate, the contact area between the sliding board and the snow surface becomes large, and the frictional resistance increases significantly.

Therefore, various effects such as those of the above-mentioned skis cannot be obtained, and there is a risk that sliding performance, rotation performance, and operability may be deteriorated.

OBJECT OF THE INVENTION The present invention was made in order to improve the above-mentioned problems, and an object of the present invention is to provide a surf skiboard that can improve glide performance, rotation performance, and maneuverability. .

Configuration of the Present Invention> An embodiment of the present invention will be described below with reference to the drawings.

〉Sliding plate (Fig. 1.2) The gliding plate 11 of the surf skiboard 1 protects the outer periphery of the core with a reinforcing material, similar to conventional ones, and the bottom gliding surface is made of high-density polyethylene or the like. It is.

Depending on the purpose, groups may or may not be engraved on the bottom.

<Open> Treadboard (Fig. 1.2) The treadboard 12 is a board shorter than the length of the sliding board 11, and may be approximately H-shaped, square, oval, or other shapes as shown in Fig. 1. It will be done.

In short, it is sufficient to provide a space on both ends of the footboard 12 where the runner can place his or her feet, and to firmly connect the two ends.

Therefore, it is desirable that the length of the footboard 12 in the longitudinal direction is slightly longer than the predetermined distance between the feet of the runner.

In addition, the width of the tread plate 12 is as shown in FIG.
It is desirable that the sliding plate 11 protrudes slightly more than the width of the sliding plate 11.
It may be the same width as or shorter.

The material for the footboard 12 may be the same as that for the sliding board 11 described above.

<C> Hook (FIG. 1.2) The hook 13 is a device for attaching the runner's feet, similar to the conventional one, and is attached to both ends of the footboard 12 in the longitudinal direction.

These hooks 13 are attached to holes formed in the longitudinal direction of the footboard 12 so as to be slidable and rotatable in the longitudinal direction using bolts or the like, and are used to adjust the width of the runner's feet and the direction in which the feet are worn (i.e., Allows adjustment of leg opening (leg opening).

<2> Pillar member (Fig. 1.2) The footboard 12 with the hook 13 attached as described above is attached to the upper surface of the sliding board 11.

The footboard 12 is attached at a predetermined position near the center of the sliding board 11 with both hooks 13 arranged in parallel in the longitudinal direction of the sliding board 11.

At this time, the method of attaching the footboard 12 is not to attach the footboard 12 directly to the sliding board 11, but to attach the footboard 12 to the sliding board 11.
and the sliding plate 11 via a column member 14.

The upper end of the column member 14 is fixed approximately at the center of the lower surface of the footboard 12, and the lower end is fixed to the upper surface of the sliding board 11.

The material and cross-sectional area of this column member 14 are selected so that it can sufficiently withstand the load, and the cross-sectional area is
The area is extremely small compared to the area of 2.

Specifically, the column member 14 is formed as short as possible in the longitudinal direction of the sliding plate 11, and is formed so as not to protrude from the sliding plate 11 in the width direction.

The width of the column member 14 is preferably about one third of the width of the sliding plate 11.

For example, the same material as the sliding plate 11 can be used for the material of the column member 14.

The cross-sectional shape of the pillar member 14 does not necessarily have to be square or circular, and even a rectangular shape having a certain length parallel to the central axis of the sliding plate 11 can be used.

Further, it is desirable that the footboard 12 is installed with a slight upward bend in advance, taking into consideration the downward deflection due to the weight of the runner.

To this end, it may be possible to manufacture the footboard 12 by warping it in advance.

Furthermore, by forming the peripheral edge of the footboard 12 to be slightly bent downward, downward deflection due to the weight of the runner can be reduced.

<Action of the present invention> Since the present invention is configured as shown in the daytime, the following effects occur.

(1) As shown in Figure 3, the runners should use one leg 15
are attached to the hooks 13, respectively.

Then, the load M is transmitted from the footboard 12 to the column member 14, and is mainly applied to one point in the center of the sliding board 11, so that the front and rear ends 16 and 17 of the sliding board 11 are relatively free. It is possible to bend up and down.

Therefore, during rotational sliding, the front and rear ends 16 of the sliding plate 11
．． Since the sliding plate 17 is bent upward, the sliding plate 11 comes into contact with the snow surface at one point, and the contact area with the snow surface is extremely small, reducing frictional resistance.

(2) Also, since not much load is applied to the front and rear ends 16 and 17 of the sliding board 11, they can move up and down flexibly in accordance with the unevenness of the snow surface.

Therefore, vertical movement of the entire sliding board 11 due to unevenness of the snow surface can be absorbed.

(3) Furthermore, by shifting the weight forward, the rear end 17 of the sliding plate 11 rises, the load portion is concentrated, and the frictional resistance is reduced, so the sliding speed can be increased.
Conversely, by shifting your weight backwards, you can control your glide speed.

4) If the width of the tread plate 12 is longer than the width of the sliding plate 11, as shown in FIG. It is longer than the distance L2 to the end.

Therefore, since distance and force are inversely proportional, when the moment M2 acting on the end of the footboard 12 is transmitted to the edge 18, it acts as an increased moment M3.

(5) When a load is applied, the footboard 12 and the column member 14 bend to some extent, so that the effect of absorbing the vertical movement of the entire sliding board 11 due to the unevenness of the snow surface occurs.

Other Examples> In the above example, the sliding board 11, the footboard 12, and the column member 14 are manufactured independently, and each is connected to assemble the surf ski board 1. However, other examples are possible. As, the sliding board 11 and the tread plate 12, the tread board 12 and the column member 14
It is also conceivable to form these three into one.

Effects of the Present Invention> Since the present invention is configured as described above, the following effects are produced.

Kui〉In a conventional surf ski board, the rider attaches both feet at intervals in the longitudinal direction of the upper surface of two sliding boards. A load will be applied and the load will be distributed over the entire sliding board.

Therefore, the sliding board becomes like a single hard plate, the contact area between the sliding board and the snow surface becomes large, and the frictional resistance increases significantly.

Therefore, there is a risk that sliding performance, rotation performance, and operability may be deteriorated.

In contrast, the present invention has a structure in which the tread plate on which the runner wears his/her feet and the gliding plate are positioned at a distance from each other, and the substantially midpoint of the lower surface of the tread plate and the upper surface of the gliding plate are connected by a column member.

Therefore, the load is mainly applied to one point in the center of the sliding plate, and the front and rear ends of the sliding plate can be bent up and down relatively freely.

Therefore, during rotational sliding, the front and rear ends of the sliding board bend upward, so that the sliding board comes into contact with the snow surface at one point, and the contact area with the snow surface is extremely small, reducing frictional resistance.

As a result, the rotational performance of the surf skiboard is improved.

In addition, since not much load is applied to the front and rear ends of the sliding board, the front and rear ends of the sliding board can flexibly move up and down in accordance with the unevenness of the snow surface.

Therefore, vertical movement of the entire sliding board due to unevenness of the snow surface can be absorbed, and the sliding performance of the surf skiboard is improved.

Furthermore, by shifting your weight forward, the rear end of the sliding board rises, concentrating the load and reducing frictional resistance, increasing your sliding speed, while conversely shifting your weight backwards. By moving, the sliding speed can be controlled.

Therefore, the operability of the surf skiboard is improved.

(2) When the footboard is formed to protrude in the width direction of the sliding board, the distance from the center of the column member to the end of the footboard is longer than the distance to the end of the sliding board.

Therefore, since distance and force are inversely proportional, the moment acting on the end of the tread will act as an increased moment when transferred to the edge of the runner.

The moment acting on the edge of the sliding board in this manner serves to ensure that the edge of the sliding board digs into the snow.

Therefore, the rotationability, operability, etc. of the surf skiboard are improved.

<E> For example, when the snow surface slopes to the left, a force acts on the sliding board to cause it to slide from the right side to the left side, that is, from the mountain side to the valley side.

However, as described above, in the present invention, the edges of the sliding board can effectively penetrate into the snow surface, so the edges of the sliding board act as a large resistance to the sliding of the sliding board toward the valley side.

Therefore, especially for beginners, falling due to skidding can be prevented.

Furthermore, since the mountain side of the sliding board bites into hard surfaces such as ice slopes, it is possible to run stably and improve operability.

When a load is applied, the footboard and pillar members will flex to some extent.

Therefore, vertical movement of the entire sliding board due to unevenness of the snow surface can be absorbed, and the sliding performance and operability of the surf skiboard are improved.

[Brief explanation of the drawing]

1st N: Explanatory diagram of one embodiment of the present invention Figure 2: Cross section Figure 3.4: Illustration of the action

Claims (1)

[Scope of Claims] A long sliding board having a sliding surface on the bottom surface, a short tread plate located near the center of the top surface of the sliding board at a distance from the top surface of the sliding board, and On the top,
Attachment parts for the runner's feet provided at two locations spaced apart in the longitudinal direction of the tread plate, and approximately the midpoint between the two attachment parts of the tread board;
A surf skiboard consisting of a pillar member connected to the top surface of a sliding board.