KR101589923B1 - Skate board - Google Patents

Abstract

In the present invention, a front board and a rear board are connected to each other by a connector so that they can be wrenched,
A caster wheel, that is, an inclinable caster (also referred to as a 'directional caster') installed at a wedge angle (inclination angle) in the traveling direction is mounted on the bottom surface of each board,
To a skateboard capable of exerting driving force or facilitating a direction change.

Description

Skateboard {SKATE BOARD}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a skate board for running two feet of a user on a board,

The front board and the rear board are connected to each other by a connector so that they can be wrenched together,

A caster wheel, that is, an inclinable caster (also referred to as a 'directional caster') installed at a wedge angle (inclination angle) in the traveling direction is mounted on the bottom surface of each board,

The present invention relates to a skateboard capable of generating a driving force by an organic action between the twist and the incline descender and capable of performing a direction change, and more particularly to the skateboard.

The background art of the present invention is Korean Patent Registration No. 0394848 (2003.08.04).

In the patent, the skateboard is composed of a front board and a rear board (front board and rear board), and the front and rear boards are coupled by a connecting element (connector), and the connecting element is twistable And an elastic body in the form of a leaf spring so as to be elastically restored after the twist. The directional casters are provided on the bottom surfaces of the front and rear boards.

However, when the elastic body takes the form of a leaf spring, repeated twisting is applied, or excessive torsion exceeding the elastic deformation limit of the leaf spring is applied, the mechanical fatigue increases and elastic deformation is caused to one side. There is a problem that it is difficult to keep the front and rear boards in the same horizontal state at the end.

There is provided an embodiment using an elastic compression force of a spring which is roughly equivalent to a torsional elastic restoring force of the plate spring in relation to the elastic body.

In this regard, conventionally, first, Korean Patent No. 859413 (2008.09.12) is known, wherein a cam and a compression spring are used at a connecting portion between a front board and a rear board, The front board and the rear board are separated from each other by the cam by pressing the compression spring. When the load is released, the front board and the rear board are elastically restored by the elastic compression force of the compression spring, Is released.

Second, 885506 (Mar. 18, 2009) is provided, and a cam and a compression spring are used at the connection portion between the front board and the rear board, and the front board and the rear board are pressed in the opposite direction, When the torsion is twisted, the compression spring is pressed. When the load is released, the torsion is released while restoring the elasticity by the elastic compression force of the compression spring. However, the distance between the front board and the rear board is fixed using a hinge shaft and a bearing.

The distance between the front board and the rear board is increased or decreased. Therefore, there is a problem that the stride is continuously changed while the user is aboard, which causes discomfort and lowers the stability.

Secondly, the hinge shaft is used to fix the distance between the front board and the rear board. At this time, since the compression spring applies a load to the end portion of the hinge shaft, the twisting rotation is not easy. Therefore, a bearing is added to constitute the structure, which increases manufacturing costs and adds a manufacturing process. In addition, it is necessary to prepare one end of the hinge shaft by inserting it with the bearing in advance in either the front board main body or the rear board main body.

SUMMARY OF THE INVENTION The present invention has been made in order to solve all the problems of the prior art,

It is possible to prevent the front board and the rear board from being twisted by escaping the elastic deformation of the leaf spring and to maintain a horizontal level of the front board and the rear board by providing a constant circular restoring force even in repetitive twisting,

By fixing the increase and decrease of the distance generated by twisting of the front board and the rear board by the cam, it is possible to maintain the stability at the time of boarding and at the same time to solve the compression load of the compression spring applied to the hinge shaft, And to provide a connector with an easy configuration.

In order to solve the above-mentioned problems,

A front board having an engraved castor mounted on a bottom surface thereof and formed with a connector engaging hole at a rear end thereof, a rear board having an incline caster mounted on its bottom face and formed with a connector engaging hole at its front end, And a connector inserted into a connector coupling hole of the rear board to connect the front board and the rear board,

The connector includes a connector pipe for taking a pipe shape, a connector rotation shaft for taking a shaft shape,

A fixed cam fixed to the inside of the connector pipe and having a hollow to allow rotation of the connector rotary shaft,

And a hollow cam formed in the center of the connector rotation shaft so as to correspond to the cross section of the connector rotation shaft, and capable of sliding back and forth while rotating along the rotation of the connector rotation shaft.

A spring that has one end abutting the moving cam and the other end abutting the end of the connector engaging hole to provide an elastic pressure when the moving cam performs sliding,

.

According to the skateboard of the present invention,

Provides continuous circular restoring force even for repetitive torsional loads on the front and rear boards, keeping the front and rear boards level,

While the cam is used, the distance between the front board and the rear board is kept constant to maintain the stability of the boarding,

The structure in which the compression load of the spring does not interfere with the twisting rotation is adopted and the structure of the bearing is omitted, thereby simplifying the overall structure and reducing the weight.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a simplified diagram illustrating the working principle of the present invention, wherein Figure IA is a side view of a portion; 1B is a front view or a front sectional view; 1C is a plan view;
FIG. 2 is an operation diagram illustrating an operation in front or in a plane.
3 is a perspective view and a bottom perspective view respectively from top to bottom.
4 is a bottom perspective view showing the disassembled state.
5 is a simplified side view for convenience of explanation, and is a side view and a bottom view respectively from top to bottom.
Figure 6 shows a side view of one part, Figure 6A is an external view; 6B is a perspective view; 6C is an exploded view showing the decomposed state of the perspective view. However, the inside of the connector was not observed.
FIG. 7 is a front view showing a part (connector) seen through; FIG. Floor plan; And a side view.
FIG. 8 is a front view, a plan view, and a side view of a portion (stationary cam) shown in FIG. 8A; FIG. 8B is a perspective view showing an outer shape in any direction and a perspective view in another direction;
FIG. 9 is a perspective view showing a state in which a fixing cam is inserted and fixed to the hollow d of the connector pipe. FIG. 9A is an exploded view of the broken state. FIG. Figure 9B is an illustration of an assembled one; 9C is a perspective view.
FIG. 10 illustrates a connector rotary shaft. FIG. 10A is a front view, a plan view, and a side view; FIG. 10B is a perspective view and a bottom perspective view;
FIG. 11 is a plan view and a side view of the assembled assembly of the fixed cam inserted through the connector rotation shaft. FIG. 11A is an exploded view of the assembled state before assembly. FIG. 11B is an illustration of an assembled state.
FIG. 12 is a front view, a plan view, and a side view of FIG. 12A. 12B is a perspective view and a bottom perspective view; to be. In particular, a spin operation is illustrated and shown in the plan view of FIG. 12A.
FIG. 13 is a perspective view showing a perspective view and an appearance of the moving cam; FIG. 13B is a perspective view showing a state in which a moving cam is inserted into a connector rotary shaft;
FIG. 14 is a view showing a coupling operation and a sliding operation of the moving cam and the connector rotary shaft of FIG. 13, wherein FIG. 13A is a side view; 13B is a plan view.
Fig. 15 illustrates the state of the moving cam that slides along with the rotation of the connector pipe and the rotary shaft of the connector. Fig. 1/4 rotation state diagram; 1/2 rotation state diagram.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a skateboard according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 3 to 5, the skateboard according to the present invention,

A front board 100 to which a front wheel incline caster 120 is attached to a bottom surface of a board 110 disposed in front; A rear board 200 having a rear wheel inclinable caster 220 attached to a bottom surface of the board 210 disposed at the rear side; And a connector 300 connecting the front board 100 and the rear board 200 in a twistable manner.

With respect to the operating principle relating to the row, as shown in FIGS. 1 and 2,

In the example of FIG. 1A, the above-mentioned incline descender 120/220 is provided with a caster equipped with rollers capable of rolling motion by tilting the bottom surface of the board 110/210 with respect to the horizontal plane . As shown in FIGS. 1B and 1C, the inclinable casters 120/220 perform a directional change in exactly the same direction as the tilt in the tilting direction of the board. For example, when the user presses the left side of the board with his foot and the board tilts leftward, the inclinable casters 120/220 proceed in the left direction.

2, the connector 300 can be tilted by operating the front board 100 and the rear board 200 so that they can be twisted in opposite directions to each other.

A more detailed overall structure and operation principle of the skateboard according to the present invention will be described with reference to the background of the present invention and will be focused on the connector 300 which is the essential body of the present invention.

First, a description will be made with respect to the connection of the connector 300 and the board together with the example of Figs. 3 to 6. If necessary, the rear end of the front board 100 and the front end of the rear board 200 may be spaced apart as shown in Figs. 5 and 6, or may be disposed as close as shown in Fig. 3 or even in contact with each other . The connector 300 connects the rear end of the front board 100 and the front end of the rear board 200 to each other.

At the rear end of the front board 100, holes are formed along the longitudinal direction of the skateboard to form a hollow e, which is referred to as a connector coupling hole 130 of the front board. Similarly, a hollow is formed along the length of the skateboard at the front end of the rear board 200, and this is referred to as a connector coupling hole 230 of the rear board.

The connector 300 includes a connector pipe 310 and a connector rotation shaft 320. The connector pipe 310 has a pipe shape with an inner hollow cavity d, And is fitted in the pipe 310 in the longitudinal direction. The connector pipe 310 and the connector rotation shaft 320 are preferably made of metal, carbon fiber, or synthetic resin having sufficient rigidity.

The rear end of the connector pipe 310 is connected to the connector coupling hole 230 of the rear board 200 by inserting the front end of the connector pipe 310 into the connector coupling hole 130 of the front board 100, Insert and tighten.

The connector fitting hole 130/230 is formed with an engaging hole f2. The connector pipe 310 and the protruding portion 321 of the connector rotation shaft are formed with a notched hole f2 so as to coincide with the fastening hole f2 of the connector hole 130/230 (F) by using a fastening screw (f1) or the like.

Next, the configuration of the connector 300 will be described with reference to FIGS. 6 and 7. FIG. The connector (300)

A connector pipe 310 for taking a pipe shape and drilling a fastening hole into the pipe-shaped body and fastening the fastening hole of the connector fastening hole 130/230 with a fastening screw;

An end portion of the shaft hole f2 is formed in the protruding portion 321 exposed to the outside of the connector pipe 310 with the fastening hole f2 of the connector fitting hole 130/230 A connector rotating shaft 320 to be fastened with a fastening screw;

A fixing cam 330 which rotates through the connector rotation shaft 320 by making a hole in the center thereof and fixes the connector pipe 310 to one end of the connector pipe 310;

A moving cam 340 configured to be in contact with an inclined surface of the fixed cam 330 to be slidable in the longitudinal direction of the connector pipe 310 and to rotate along the rotation of the connector rotating shaft 320;

A compression spring 350 which has one end in contact with the moving cam 340 and whose other end is in contact with a clogged end ee of the connector coupling hole 130/230 to apply an elastic restoring force to the moving cam 340; .

Next, the connector 300 will be described in more detail.

8A is a front view, a plan view and a side view of the fixed cam 330, and an example of Fig. 8B is a perspective view and a perspective view of the fixed cam 330 in the other direction. The fixed cam 330 takes a ring shape with an inclined surface 331 for performing a role of a cam. The hollow portion c is formed by hollowing the inside of the connector rotation shaft 320 so as to be rotatable about the vertical axis. The hollow c may be formed in a circular shape so as to serve as a rotation bearing of the connector rotary shaft 320.

A ring-shaped latching protrusion 332 is formed around the hollow to prevent a specific portion of the connector rotation axis 320 from being caught.

In the example of FIG. 9, the fixed cam 330 is inserted into the interior of one end of the connector pipe 310, and is fixed. The fixed cam 330 is fixed so as not to be detached or rotated. The fixing method may use friction between the outer periphery of the fixed cam 330 and the inner periphery of the connector pipe 310, and may be bonded, welded, or fastened with a fastening screw or the like. When the fastening is used, the fastening holes may be aligned to fasten the connector pipe 310 with the fastening screws when fastening the connector pipe 310 to the connector fastening holes 130/230.

10, the connector rotation axis 320 may take the form of a sword, and in its configuration and configuration, the connector rotation shaft 320 may have a protrusion 321 exposed out of the connector pipe 310 and having a fastening hole, ; A cross section is formed in a rectangular shape as shown in the figure so as to prevent any rotation of the movement cam 340 so that the movement cam 340 can move only in the connector 340. [ A moving cam movable slide 322 which turns only along the rotation of the rotating shaft 320 and at the same time guides the moving cam 340 to slide back and forth; And a locking protrusion 323 protruding from the connector rotation shaft 320 so as to be caught by the locking protrusion 332 of the fixing cam 330 to prevent release of the assembly after assembly. Here, the latching jaw 332 and the latching protrusion 323 can be replaced with other types of configurations having similar purposes. 11 and 12 show that the connector rotation shaft 320 is fitted into the fixed cam 330. In particular, the example of FIG. 12A represents the connector rotation axis 320 which is spinning independently while being held by the fixed cam 330. Conversely, when the connector rotation shaft 320 is positioned, the fixed cam 330 rotates independently.

13 and 14 show sliding cam 340 and cam 340 in sliding contact with connector rotation axis 320. The moving cam 340 has an inclined surface 341 corresponding to the inclined surface 331 of the fixed cam 330. And a plate hollow b is formed in the center thereof so as to correspond to the shape of the connector rotary shaft 320. The movable cam 340 is slid from the opposite side of the protrusion 321 of the connector rotation shaft 320 during assembly.

After assembling, when the front board 100 and the rear board 200 are tilted and tilted in opposite directions, the fixed cam 330 and the moving cam 340 rotate in opposite directions to each other, and at the same time, the inclined surfaces 331/341 So that the moving cam 340 can slide along the moving cam moving slide 322 of the connector rotating shaft. 7, the spring 350, which is in contact with the moving cam 340 at one end, is pushed, so that elastic energy is accumulated in the spring 350 and can be elastically restored later. The other end of the spring 350 abuts and contacts the end ee of the connector fitting hole 130/230 in the example of Figs. 6C and 6D.

15 shows a state in which the connector pipe 310 and the connector rotating shaft 320 generated when the front board 100 and the rear board 200 are tilted by reversely tilting in opposite directions, And shows a state of a normal state, a 1/4 spin state, and a 1/2 spin state before rotation from top to bottom, respectively.

According to the connector 300 of the present invention as described above, the moving cam 340 rotates along the rotation of the movable cam moving slide 322 of the connector rotating shaft 320, and the fixed cam The elastic force of the spring 350 in the forward and backward direction is applied to the connector rotation shaft 320 and the moving cam 331. In this case, Since the movable slide 322 is not pressed, the friction can be reduced as compared with the conventional structure, and the structure of the separate bearing device can be omitted.

In addition, since the connector can be separately manufactured and applied without using any special design modification to the existing skateboard structure while utilizing the elastic restoring force of the cam and the compression spring, there is an advantage that the existing equipment investment can be saved.

A front board 100;
A rear board 200;
An incline descender 120/220;
A connector 300;
Connector mating holes (130/230);
A connector pipe 310;
A connector rotation shaft 320;
A fixed cam 330;
A moving cam 340;
A spring 350;

Claims (3)

In skateboarding,
A front board on which an incline descender is mounted on a bottom surface and a connector coupling hole is formed on a rear end thereof;
A rear board on which an incline descender is mounted on the bottom surface and a connector coupling hole is formed on the front end;
And a connector having a front end inserted into a connector coupling hole of the front board and a rear end inserted into a connector coupling hole of the rear board to connect the front board and the rear board,
Wherein the connector comprises:
A connector pipe for taking a pipe shape;
A connector rotating shaft for taking a shaft shape;
A fixed cam having an inclined surface for performing a role of a cam, a hollow formed in the center thereof so that the rotary shaft of the connector can rotate, and a fixed cam fixed inside the connector pipe;
A movable cam having an inclined surface which abuts against an inclined surface of the fixed cam so as to be pushed when rotated, and a hollow corresponding to the cross-section of the connector rotary shaft is formed at the center thereof so as to be slidable back and forth while rotating along the rotation of the connector rotary shaft;
A spring having one end contacting the moving cam and the other end contacting the end of the connector engagement hole to provide an elastic pressure when the moving cam performs sliding;
Wherein the skateboard comprises: The method according to claim 1,
Wherein the connector rotary shaft has a rectangular cross-sectional shape. The method according to claim 1,
Wherein the connector coupling hole includes a fastening hole.

Images