KR200294891Y1 - stepper - Google Patents

Abstract

The present invention relates to a stepper having a structure capable of preventing uneven wear of a piston (oring) reciprocating in a cylinder and preventing leakage of fluid due to uneven wear of the piston. The stepper according to the present invention is a step-integrated lever hinged on the frame, connected to the fluid tank through the line is filled with a fluid of a predetermined pressure, a cylinder hinged to the frame, a piston rod hinged to the lever, and And a piston connected to the piston rod through spherical coupling to compress the fluid in the cylinder by the vertical movement of the lever.

Description

Stepper

The present invention relates to a stepper, and more particularly to a stepper having a structure that can prevent the failure of the stepper due to the leakage of gas in the fluid compression mechanism such as shock absorber.

A stepper that is commonly used is capable of simultaneously performing lower body aerobic exercise and strength exercise as is well known, and as shown in FIG. It is provided in the same fluid compression mechanism 102, and it is possible for a user to carry out the movement which climbs a staircase continuously by stepping on the left-right footrest 103 alternately at a predetermined position.

The fluid compression mechanism 102 used in the conventional stepper as described above is connected to a fluid tank (not shown) via a line 104 as shown in FIG. ), A piston rod 106 hinged to the lever 101, and a foot plate 103, ie, connected to the piston rod 106 to compress the fluid in the cylinder 105 by the up and down movement of the lever 101. The piston 107 is provided. The cylinder 105 of the fluid compression mechanism 102 is hinged to the frame 100 at point 108 such that the stepping force acting on the scaffold 103 is via the cylinder 101 via the lever 101 and the piston rod 106. Cylinder 105 is pivoted about point 108. O-ring grooves are formed on the outer circumferential surface of the piston 107, and the O-ring grooves are provided with an O-ring 109 to maintain airtightness with the inner surface of the cylinder 105.

When the user presses on the footrest 103, the foot force is transmitted to the piston 107 through the piston rod 106 connected to the footrest 103, and the fluid filled in the cylinder 105 is compressed by the piston 107 and , As the user continues to step on the footrest 103, an exercise effect occurs.

However, in the conventional stepper as described above, since the piston and the piston rod used in the fluid compression mechanism are fixedly connected to each other, when the turning force of the lever moving as the user steps on the foot plate is transmitted to the piston rod, the piston is connected to the piston rod. Only a part of the cylinder contacts the inner surface of the cylinder due to the acting turning force, and partial wear occurs at the portion of the cylinder, and the fluid in the cylinder leaks due to the uneven wear of the piston (O-ring), and the fluid compression mechanism cannot function properly. There was this.

Accordingly, an object of the present invention is to provide a stepper having a structure capable of preventing uneven wear of a piston (oring) reciprocating in a cylinder and preventing leakage of fluid due to uneven wear of the piston.

1 shows a typical stepper.

Fig. 2 is a sectional view showing a contact state between a piston and a cylinder of a fluid compression mechanism used in a conventional stepper.

3 is a cross-sectional view of a fluid compression mechanism using spherical coupling according to the present invention.

4 is an exploded perspective view of the fluid compression mechanism shown in FIG. 3.

(Explanation of symbols for the main parts of the drawing)

1 fluid compression mechanism 2 cylinder 3 piston rod

4: piston 5: spherical body accommodating portion 6: spherical groove

7: snap ring 8: spherical body 9: line

The purpose as described above, the one-piece lever integrally hinged on the frame, connected to the fluid tank through the line is filled with a fluid of a predetermined pressure, the cylinder hinged to the frame, the piston rod hinged to the lever, And a piston connected to the piston rod to compress the fluid in the cylinder by the vertical movement of the lever, wherein the piston and the piston rod are spherically coupled by the stepper according to the present invention. Can be achieved.

In the above, the piston rod is provided with a spherical body at the end, the piston is formed with a spherical body formed with a spherical groove spherically coupled with the spherical body, the spherical body is received when the spherical body is received in the spherical body receiving portion The coupling state is maintained by the snap ring fastened to the inner diameter of the sieve receiving portion.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

3 is a cross-sectional view of a fluid compression mechanism using spherical coupling according to the present invention, Figure 4 is an exploded perspective view of the fluid compression mechanism shown in FIG.

As shown in Figs. 3 and 4, the fluid compression mechanism 1 of the stepper according to the present invention is conventionally provided with a fluid tank (not shown) through the line 9 such that the cylinder 2 is filled with a fluid of a predetermined pressure. And hinged to the frame. The piston rod 3, which is connected to the piston 4 reciprocating in the cylinder 2, is hinged to the scaffold lever, and the piston 4 is fluidized in the cylinder by the vertical motion of the scaffold lever as described above. Compress it.

According to the invention, the piston 4 and the piston rod 3 are spherically coupled. For this spherical engagement, the piston rod 3 is provided with a spherical body 8 at the end, and the piston 4 is formed with a spherical groove 6 which spherically engages with the spherical body 8 of the piston rod 3. A spherical body accommodating part 5 is formed. The spherical body receiving part 5 is formed in the cylindrical groove as can be seen from a figure, and the spherical groove 6 is formed in the bottom of the groove. When the spherical body 8 is accommodated in the spherical body accommodating part 5, the spherical body 8 is hold | maintained by the snap ring 7 which is fastened to the inner diameter part of the spherical body accommodating part 5.

As described above, by the piston rod 3 and the piston 4 being spherically coupled, the piston rod 3 is pivoted as shown by the dashed-dotted line in FIG. 3 by the pivoting force of the lever and centered on the spherical spherical engagement portion. The piston 4 is prevented from being biased in one direction by the turning force of the lever.

That is, since the piston rod 3 and the piston 4 are connected in spherical engagement, the piston rod 3 is pivoted about the spherical engaging portion when the pivoting force of the lever acts, so that the piston 4 is always in the cylinder 2. It can be kept in close contact with the inner surface of the.

As described above, according to the stepper according to the present invention, it is possible to prevent uneven wear of the piston (O-ring) reciprocating in the cylinder, it is possible to prevent the leakage of fluid due to uneven wear of the piston.

Claims (2)

A scaffold integrated lever hinged on the frame, connected to the fluid tank via a line to fill a fluid of a predetermined pressure, a cylinder hinged to the frame, a piston rod hinged to the lever, and a vertical movement of the lever. A stepper having a piston connected to a piston rod to compress fluid in the cylinder by And the piston and the piston rod are spherically coupled. The spherical body of claim 1, wherein the piston rod has a spherical body at an end thereof, and the piston has a spherical body receiving part having a spherical groove spherically engaging the spherical body, and the spherical body has been received in the spherical body receiving part. Stepper, characterized in that the coupling state is maintained by the snap ring is fastened to the inner diameter portion of the spherical body receiving portion.