WO2002081292A1

WO2002081292A1 - Suspension type saddle supporting structure

Info

Publication number: WO2002081292A1
Application number: PCT/JP2002/002925
Authority: WO
Inventors: Shinji Takase
Original assignee: Sakae Engineering Inc.
Priority date: 2001-03-30
Filing date: 2002-03-26
Publication date: 2002-10-17
Also published as: JP4846116B2; JP2002293280A; CN1460081A; CN1217821C; DE10296620T5; DE10296620B4

Abstract

A suspension type saddle supporting structure, wherein the deformations of a pair of arm members (11) and (12) are started by an impact force on a saddle (1) to impart a pressing force to a slide rod (17) while rolling a rolling roller (23) on the end face (17a) of the slide rod (17) to press the rod (17) into a pillar (15).

Description

Specification

Suspension type saddle support structure

Technical field

The present invention relates to a suspension-type saddle support structure that displaces a saddle and absorbs impact when a large impact force is applied to the saddle. Background art

Conventionally, as this kind of saddle support structure, there is a structure in which a deformable arm is connected to a coil sparing via a rod to absorb an impulse added to the saddle by deformation of the coil spring. Are known.

Also, as another saddle support structure, an elastic body such as a resin having an elastic function is directly disposed between a pair of deformable arms, and the impact force applied to the saddle by the deformation of the elastic body is reduced. Absorbing structures are also known.

However, in a structure in which the arm and the coil spring are connected by a mouth, the direction in which the arm is deformed and the direction in which the rod moves are different, and therefore, precision is required in the design.

In the structure in which the elastic body is directly arranged between the arms, the elastic body deteriorates, and thus there is a problem in durability.

An object of the present invention is to provide a suspension-type saddle support structure that is easy to design and can absorb an impact force smoothly, and has durability. Disclosure of the invention

The present invention has the following configuration in order to solve such a problem.

That is, according to the present invention, one end of each of the opposing arm members facing each other is deformably connected to a support frame to which a saddle of a bicycle is attached, The other end of each of the pair of arm members is deformably connected to a mounting frame fixed to the pillar, and a slide rod projects between the pair of arm members via an elastic member disposed in the pillar. At the same time, the end surface of the slide rod presses a rolling roller rotatably mounted on one of the arm members, and when an impact force is applied to the saddle, the end surface of the slide rod is pressed. The rolling roller is pushed into the pillar by this rolling roller while the rolling roller is rolling above, and the pair of arm members are deformed. I do.

If no impact is applied to the saddle, the slide rod projects from the pillar due to the elastic force of the elastic member in the pillar, and the end face of the slide rod presses the rolling roller. Therefore, the pair of arm members is held without deformation. On the other hand, when an impact force is applied to the saddle, the impact force is transmitted to the rolling roller via one arm member, and the rolling roller rolls on the end face of the sliding rod while sliding. Push the head into the pillar. This deforms the pair of arm members and absorbs the impact.

As described above, when the slide rod is pushed in while being rolled by the rolling roller, the pair of arm members can be smoothly deformed. That is, the impact can be absorbed smoothly. BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a cross-sectional view of the suspension-type saddle support structure according to the present invention when it is not deformed, and FIG. 2 is a cross-sectional view of the same when the structure is deformed. BEST MODE FOR CARRYING OUT THE INVENTION

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

FIG. 1 is a sectional view of a suspension-type saddle support structure according to the present invention. In FIG. 1, 1 indicates a bicycle saddle. The saddle 1 has a mounting bar 2 on the lower surface side, and the mounting bar 2 is sandwiched by clampers 3.

The saddle support structure of the present invention includes a support frame 10. A clamper 3 is disposed in a recess on the upper surface of the support frame 10, and the clamper 3 is fixed to the support frame 10 by a fixed bolt 4.

Upper ends of the pair of arm members 11 and 12 are connected to upper and lower portions of the support frame 10 via pivot pins 13 and 13 so as to be deformable. The lower ends of the pair of arm members 11 and 12 are deformably connected to the bulging portion 14A of the mounting frame 14 via pivot pins 13 and 13.

The lower cylindrical portion 14 B of the mounting frame 14 is fixedly fitted to the upper end of the pillar 15 via a packing member 16. Above the pillar 15, there is a cylindrical slider 17. The slide rod 17 is coaxially arranged in the pillar 15 via sliding members 18 and 18 fixed to the peripheral surface, whereby the slide rod 17 projects and retracts with respect to the pillar 15. Is possible

Further, a coil spring 19 is arranged in the pillar 15. The lower end of the coil spring 19 is in contact with the cylindrical receiving member 20, and the upper end is in contact with the other receiving member 21. The upper receiving member 21 is fitted into the lower part of the slide rod 17. Since the coil spring 19 is compressed and arranged in the pillar 15, the slide rod 17 protrudes from above the pillar 15, and the upper part thereof is a pair of arm members 1. It is located between 1 and 12.

An obstruction plug 22 is fitted into the upper part of the slide rod 17, and the upper surface of the flange of the obstruction plug 22 forms an end face 17 a of the slide rod 17. Rolling rollers 23 are in contact with this end face 17a. Rolling rollers 23 Is rotatably mounted on the inside of the arm member 11 via a shaft 11a.

The rolling roller 23 is pressed obliquely upward at the end face 17 a by the projection of the slide rod 17. Therefore, the pair of arm members 11 and 12 are held in the non-deformed state shown in FIG.

A rubber ring 24 is rotatably mounted inside the other arm member 12 via a shaft 12a. On the other hand, a receiving recess 10a is formed on the surface of the support frame 10 facing the rubber ring 24.

Next, the operation of the saddle support structure of the present invention will be described with reference to FIG. When an impact force F is applied to the saddle 1 downward while the bicycle is running, the impact force F is transmitted to the support frame 10 and the pair of arm members 11 and 12. As a result, the pair of arm members 11 and 12 begin to fall forward in the traveling direction and start deforming, so that the rolling roller 23 moves on the end face 17 a of the slide rod 17. The end face is pressed while rolling and moving. Accordingly, since the slide rod 17 is piled on the elastic force of the coil spring 19 and is gradually pushed into the pillar 15, the pair of arm members 11 and 12 are shown in FIG. Thus, the saddle 1 is displaced obliquely downward as indicated by the arrow A.

On the other hand, when the deformation of the pair of arm members 11 and 12 progresses, the rubber ring 24 rotates while being crushed by the recess 10 a on the lower surface of the support frame 10. That is, the rubber ring 24 functions as a damper that further absorbs the impact force during deformation.

In this way, the rolling roller 23 rolls on the end face 17a of the slider 17 to gradually change the direction in which the impact force F is applied in the direction of arrow A. Thus, the pair of arm members 11 and 12 can be smoothly deformed, and the impact force can be gradually absorbed. Industrial applicability

As described above, according to the present invention, a pushing force is applied to the slide rod while rolling the rolling roller on the end face of the slide rod. In addition to being able to absorb the impact force smoothly, even if the deformation direction of the arm member is different from the pushing direction of the slide rod, the slide rod must be pushed in without requiring design accuracy. It has excellent durability because of its simple structure.

Claims

The scope of the claims

1. A suspension-type saddle support mechanism for supporting a bicycle saddle, wherein one end of each of the support frames to which the saddle is attached is deformable so as to face each other. A pair of arm members connected to each other, an attachment frame fixedly connected to one end of a pillar, the other end of each of the pair of arm members being deformably connected, and an elastic member disposed in the pillar. A slide rod protruding between the pair of arm members through the first and second arm members, the slide rod being rotatably attached to the one arm member and holding the pair of arm members in a non-deformed state. The slide rod is pressed by the end face of the pad and deforms the pair of arm members in order to absorb the impact added to the saddle. And a rolling roller that pushes the slide rod into the pillar by pushing the slide rod to the elastic force of the elastic member, and a suspension-type saddle support structure.

2. The suspension type saddle support structure further comprising an elastic deformation member attached to the other arm member and elastically supporting the support frame by deformation of the pair of arm members.