KR20120093465A - Shock-absorber with anti-torsion function and shoes pad with the same - Google Patents

Abstract

PURPOSE: A twist prevention shock absorbing device, and a shoe pad including thereof are provided to prevent the twisting of ankles of a user by preventing the compressive force of one spring tilting from the shock applied to the other spring. CONSTITUTION: A twist prevention shock absorbing device includes a shared rotary shaft frame, a third compressive spring(101) located on the upper side of the shared rotary shaft frame, a first lever arm(102a) rotating along to a rotary shaft located on one side of the shared rotary shaft frame, a first upper moving slider(103a) including another rotary shaft on the first lever arm; a first upper suspension including a moving guide; a first lower moving slider(104a) including a central rotary shaft of the first lever arm; a second lever arm(102b) rotating along to the rotary shaft on the shared rotary shaft frame; a second upper moving slider(103b) including another rotary shaft of a second lever arm; a second upper suspension; a second lower moving slider(104b) having a central shaft of the second lever arm; and a pair of springs(105a, 105b).

Description

SHOCK-ABSORBER WITH ANTI-TORSION FUNCTION AND SHOES PAD WITH THE SAME}

The present invention relates to a shock absorbing device that prevents the torsional phenomenon to the foot by adjusting the compression force according to the torsional pressure transmitted to the shoe during walking by using the vertical movement of the double-armed lever arm, and when the pressure is applied to the center When biased on the left and right sides, even when the foot is twisted by applying the same pressure, the lower side of the shoe is compressed flat to protect the ankle joint and to prevent an anti-twist shoe shock absorber for forming a parallel leg shape.

The shock absorbing device applied to the conventional shoes has a function of alleviating the shock caused by the weight while walking by using a spring and an air tube under the shoe pad. The shock absorber located in the place where the impact shock absorber of the above shock absorber is applied to perform the function of dispersing the shock by compressing and relaxing.

In addition, there is a shock absorbing device having an electric device that adjusts the shock absorbing force by detecting the pressure applied to a specific portion of the shoe according to the walking situation.

However, in the case of a shock absorber using a separate spring and air tube, as in the prior art, if excessive pressure is applied to one side, the shock absorber loses its shock absorbing capacity and the relaxed shock absorber increases this pressure imbalance. In the case of a device that adjusts the compressive force differently depending on the losing position, an additional device such as an electric device and a battery is required, thereby increasing the production cost and consequently decreasing the competitiveness.

Therefore, there is a demand for a torsional pressure sensitive shock absorber in which the compressive force is adjusted according to the magnitude of the pressure unevenly applied to only one side of the shoe.

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is not a conventional independent shock absorbing device, the compression force of the spring of the opposite side does not incline to one side when a strong impact is applied to one side By compressing the shoe pad horizontally, to prevent the ankle torsion, and to provide a structure of the shock absorber having a torsion preventing function to create a parallel walking environment.

In order to achieve the problem to be solved by the present invention,

Torsional shock absorption device according to an embodiment of the present invention,

It is formed on the upper side of the lower fixed frame,

In the center shared shaft frame,

A central spring provided above the shared rotary shaft frame;

A pair of lever arms provided on both sides rotating along the rotation axis of the shared rotation shaft frame;

A pair of lower moving sliders including the middle axis of rotation of the lever arm,

Three separate suspensions on the upper and middle sides,

A pair of upper moving sliders including one axis of rotation of the lever arm provided inside the suspensions on both sides,

It is configured to include a pair of springs on the lower side of the suspension on both sides to implement a torsion-resistant shock absorbing device.

The pair of springs, which are provided on both sides around the center suspension, have a structure in which the opposite spring is compressed together when one side receives a stronger pressure than the other side, so that the torsion of the shoe due to the pressure concentrated only on one side Prevents and provides parallel walking conditions by forming horizontal shoe pads.

According to the present invention including the above-described configuration, the following effects can be obtained.

First, according to the present invention, the torsion-resistant shock absorbing device is simple in structure, and thus easy to manufacture, it can be applied in various fields.

Second, according to the present invention, the torsion-resistant shock absorbing device is effective to protect the ankle and knee by reducing the impact on the ankle due to the torsional pressure transmitted to the shoe in accordance with the walking environment of the pedestrian.

Third, according to the present invention, the anti-twist shock absorbing device provides a parallel walking condition by leveling the bottom of the shoe.

Fourthly, according to the present invention, the torsion-resistant shock absorbing device is effective for the beauty of the legs and the pelvis by bending to one side of the ankle.

1 is a perspective view showing a shoe pad having a torsion-resistant shock absorbing device according to an embodiment of the present invention.
Figure 2 is a perspective view of the top of the anti-torsion shock absorbing device according to an embodiment of the present invention.
Figure 3 is a perspective view showing a part coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing the structure of each component of the anti-twist shock absorber according to an embodiment of the present invention.
Figure 5 is a perspective view showing a part coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.
Figure 6 is a lower perspective view showing a torsion-resistant shock absorbing device according to an embodiment of the present invention.
7 is a cross-sectional view showing a component coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.
Figure 8 is a perspective view showing a torsional shock absorbing device according to another embodiment of the present invention.
Figure 9 is an exploded perspective view showing the structure of each component of the torsional shock absorber according to another embodiment of the present invention.
10 is a cross-sectional view showing a component coupling structure of the torsion-resistant shock absorbing device according to another embodiment of the present invention.

Torsional shock absorption device of the present invention for achieving the above object,

Is formed on the upper side of the fixed frame 106 including the moving guide of the first lower moving slider (104a) and the second lower moving slider (104b),

Springs 105a and 105b symmetrically formed on both sides,

Shared rotating shaft frame 100,

A third compression spring 101 provided above the shared rotary shaft frame,

A first lever arm 102a which rotates along a rotation axis of one side of the shared rotation shaft frame 100,

A first upper moving slider 103a including another axis of rotation of the first lever arm,

A first upper suspension 107a including a moving guide to which the first upper moving slider is moved;

A first lower moving slider 104a including a central axis of rotation of the first lever arm,

A second lever arm 102b that rotates along a rotation axis on one side of the shared rotation shaft frame 100,

A second upper moving slider 103b including another rotation axis of the second lever arm,

A second upper suspension 107b including a moving guide to which the second upper moving slider is moved;

A second lower moving slider 104b including a central axis of rotation of the second lever arm,

And it comprises a pair of springs (105a, 105b) provided below the first upper suspension (107a) and the second upper suspension (107b) to solve the problem of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention a torsional shock absorber.

Figure 2 is a top perspective view showing a torsion-resistant shock absorbing device according to an embodiment of the present invention.

2, the torsion-resistant shock absorbing device is composed of three separate suspensions on the upper side and a fixed frame and a spring on the lower side.

Figure 3 is a perspective view showing a part coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.

Figure 4 is an exploded perspective view showing the structure of each component of the anti-twist shock absorber according to an embodiment of the present invention.

5 is a perspective view showing a component coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.

3 to 5, the torsion-resistant shock absorbing device includes a first lever arm 102a and a second lower moving slider (rotating along a rotation axis of the first lower moving slider 104a above the lower fixed frame). A second lever arm 102b which rotates along the axis of rotation 104b is provided, and a shared axis of rotation frame 100 including a shared axis of rotation of the first lever arm 102a and the second lever arm 102b is connected,

The third compression spring is coupled to the upper side of the shared rotary shaft frame,

A first upper moving slider 103a including another axis of rotation of the first lever arm on one side of the other end of the first lever arm 102a,

A second upper moving slider 103b including another axis of rotation of the second lever arm on one side of the other end of the second lever arm 102b,

The lower fixed frame 106 is configured to include a pair of first compression spring (105a) and the second compression spring (105b) coupled to both sides.

7 is a cross-sectional view showing a component coupling structure of the torsion-resistant shock absorbing device according to an embodiment of the present invention.

Referring to FIG. 7, a first lever arm 102a and a first upper moving slider 103a, and a first lower moving slider 104a and a first side are formed on both sides of a central compression spring 101 and a shared rotary frame. A first upper suspension 107a and a first compression spring 105a, a second lever arm 102b and a second upper moving slider 103b, and a second lower moving slider 104b and a second upper suspension 107b. And the second compression spring 105b are symmetrically coupled.

When the first compression spring is compressed, the shared shaft frame 100 is raised as the first lever arm 102a connected to the rotation axis of the first upper slider 103a rotates along the rotation axis of the first lower moving slider 104a. and,

As the shared rotary shaft frame 100 rises, the second lever arm 102b rotates along the rotation axis of the second lower moving slider 104b,

The pressure pushing the first upper suspension 107a equally extends to the second upper suspension 107b.

Accordingly, even if either one of the first and second upper suspensions is subjected to a stronger pressure, the first, second and third upper suspensions equally mitigate the impact, thereby preventing the torsional phenomenon from being distorted to either side.

In another embodiment of the anti-twist shock absorbing device includes a first upper suspension 107p including a first lever rotation axis and a moving guide of the rotation axis of the first upper suspension, the first suspension rotation axis A first lever arm 102p that rotates along the

And a second lever arm 102q including a second upper suspension 107q including a second lever rotation axis and a moving guide of the rotation axis of the second upper suspension, and rotating along the second suspension rotation axis. It is configured by.

8 is a perspective view showing a torsion-resistant shock absorbing device according to another embodiment of the present invention.

9 is an exploded perspective view showing the structure of each component of the anti-twist shock absorbing apparatus according to another embodiment of the present invention.

8 to 9, the other anti-twist shock absorbing device may include a moving guide of a rotating shaft of the first upper suspension 107p that rotates along the rotating shaft of the first lower moving slider 104a above the lower fixed frame. A second lever arm 102q including a moving guide of a second upper suspension 107q that rotates along the axis of rotation of the first lever arm 102p and the second lower moving slider 104b includes a moving guide.

The shared rotary shaft frame 100 including the shared rotary shaft of the first lever arm 102p and the second lever arm 102q is connected,

The third compression spring 101 is coupled to the upper side of the shared rotary shaft frame,

A first upper suspension 107p including another axis of rotation of the first lever arm at one end of the first lever arm 102p,

A second upper suspension 107q including another axis of rotation of the second lever arm on one side of the other end of the second lever arm 102q,

The lower fixed frame 106 is configured to include a pair of first compression spring (105a) and the second compression spring (105b) coupled to both sides.

10 is a cross-sectional view showing a component coupling structure of the torsion-resistant shock absorbing device according to another embodiment of the present invention.

Referring to FIG. 10, the first upper suspension 107p includes a rotation axis of the first lever arm 102p, and the second upper suspension 107q includes a rotation axis of the second lever arm 102q,

When the first compression spring 105a is compressed by the pressure, the rotating shaft provided in the first suspension 107p moves along the moving guide provided in the first lever arm 102p,

When the second compression spring 105b is compressed, the rotating shaft provided in the second suspension 107q moves along the moving guide provided in the second lever arm 102q,

Move the axis of rotation.

It will be appreciated by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: shared rotating shaft frame
101: third compression spring
102a: first lever arm
102b: Second Crowbar Arm
102p: First Crowbar Arm
102q: 2nd lever arm
103a: first upper moving slider
103b: second upper moving slider
104a: first lower moving slider
104b: second lower moving slider
105a: first compression spring
105b: second compression spring
106: lower fixed frame
107a: first upper suspension
107b: second upper suspension
107p: first upper suspension
107q: second upper suspension
108: third upper suspension
110: shoe heel
111: Shoe Pad

Claims (6)

Is formed on the upper side of the fixed frame,
Shared rotating shaft connected to the center of the fixed frame,
Torsion-resistant shock absorption device characterized in that it comprises a pair of lever arm and suspension to share by sharing the shared rotary shaft formed on both sides of the shared rotary shaft. Is formed on the upper side of the fixed frame 106,
A first lever arm 102a rotating along an axis of rotation of the first lower moving slider 104a above the lower fixed frame 106, and
A second lever arm 102b rotating along the rotation axis of the second lower moving slider 104b,
A shared rotating shaft frame 100 including a shared rotating shaft of the first and second lever arms connected to the first lever arm 102a and the second lever arm 102b;
A third compression spring 101 coupled to an upper side of the shared rotating shaft frame,
A first upper moving slider 103a including another axis of rotation of the first lever arm on one side of the other end of the first lever arm 102a,
A second upper moving slider 103b including another axis of rotation of the second lever arm on one side of the other end of the second lever arm 102b,
Torsion-resistant shock absorbing device characterized in that it further comprises a pair of first compression spring (105a) and the second compression spring (105b) coupled to both sides of the lower fixed frame (106). The method of claim 2,
When the first compression spring is compressed, the shared shaft frame 100 is raised as the first lever arm 102a connected to the rotation axis of the first upper slider 103a rotates along the rotation axis of the first lower moving slider 104a. and,
As the shared rotary shaft frame 100 rises, the second lever arm 102b rotates along the rotation axis of the second lower moving slider 104b,
The first, second, and third upper suspensions equally mitigate the impact, thereby preventing the balance from being distorted to either side. The method of claim 2,
A first lever arm 102p including a moving guide of a first upper suspension 107p rotating shaft that rotates along a rotating shaft of the first lower moving slider 104a above the lower fixed frame 106;
A second lever arm 102q including a moving guide of a rotation axis of the second upper suspension 107q which rotates along the rotation axis of the second lower moving slider 104b;
The shared rotary shaft frame 100 including the shared rotary shaft of the first lever arm 102p and the second lever arm 102q is connected,
The third compression spring 101 is coupled to the upper side of the shared rotary shaft frame,
A first upper suspension 107p including another axis of rotation of the first lever arm at one end of the first lever arm 102p,
A second upper suspension 107q including another axis of rotation of the second lever arm on one side of the other end of the second lever arm 102q,
Torsion-resistant shock absorption device characterized in that it comprises a pair of first compression spring (105a) and the second compression spring (105b) coupled to both sides of the lower fixed frame (106). The method according to claim 1, wherein
A shoe shock absorbing pad having a pair of lever arms and a pair of suspension pads provided on both sides of the central shared rotary shaft. The method according to claim 1, wherein
Shoes provided with a shoe pad including a heel to the internal torsional shock absorption device.

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