JPH08291838A - Hydraulic damping device - Google Patents

Abstract

PURPOSE: To apply a hydraulic damping device to even a rod guide whose opening diameter is small and secure sufficient collision strength of a rebound stopper by constituting a receiving face by a small diameter cylindrical section and the lower end face of a guide bushing. CONSTITUTION: For full-rebound, the rebound rubber 3 provided in a piston rod 4 is received by the rebound stopper receiving face 9 constituted by the small diameter cylindrical section 7h of a rod guide and the lower face of a guide bushing 8, being prevented form expanding. When the rebound rubber 3 collides, an axial load is received by the small diameter cylindrical section 7h of the rod guide, securing sufficient strength even in the case of press-formed plate materials. Since the section inserted into the cylinder tube of the rod guide is constituted by the small diameter cylindrical section 7h, even if the difference between the outer diameter of the piston rod 4 and the inner diameter of the cylinder tube is small, a liquid pressure damping device can be applied to the rod guide leaving a margin.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hydraulic shock absorber used in a vehicle or the like, and more particularly to a rebound stopper receiving surface structure.

[0002]

2. Description of the Related Art Conventionally, as a hydraulic shock absorber, there is, for example, one described in Japanese Utility Model Laid-Open No. 3-81436 filed by the applicant of the present application.

In this conventional hydraulic shock absorber, the rod guide is formed by press-molding a single plate material, and an outer diameter portion is inscribed in the inner diameter surface of the outer tube for centering.
An upper end flat portion that supports the oil seal, a support cylindrical portion that hangs axially from the inside of the upper end flat portion, and an intermediate flat surface that is formed at the lower end of the support cylindrical portion and that locks to the upper end opening end surface of the cylinder tube. Step and an engagement step part formed of a tubular part inscribed in the inner diameter surface, and an inner-outer double tube part formed by folding back inward from the lower end of the tubular part of the engagement step part in a substantially U-shape. And a predetermined gap is formed between the outer diameter surface of the outer cylinder portion and the inner diameter surface of the cylinder tube in the inner and outer double cylinder portions so that the piston rod slides on the inner diameter surface of the inner cylinder portion. The guide bush for guiding is press-fitted, and the rebound stopper receiving surface is constituted by the bottom surface of the inner / outer double tube portion or the receiving plate attached to the bottom surface.

That is, in this conventional hydraulic shock absorber, since the rod guide is formed by press-molding a single plate material, the weight can be reduced and the manufacturing is easy, so that the cost is reduced. It can be reduced and the inside and outside 2
With the structure in which a gap is provided between the outer diameter surface of the outer cylinder portion and the inner diameter surface of the cylinder tube in the heavy cylinder portion, the inner and outer double cylinder portions are deformed following the inclination of the piston rod due to the lateral force. Therefore, it is possible to prevent the local deterioration of the surface pressure on the rod guide and to reduce the friction.

[0005]

However, in such a conventional hydraulic shock absorber, as described above, the structure of the rod guide is doubled inside and outside, which is formed by folding back in a substantially U-shaped cross section. Since the cylindrical portion is housed between the inner surface of the cylinder tube and the outer surface of the piston rod, there are problems as described below.

That is, the inner and outer double cylinders require a predetermined bend R at the lower end bent portion, and the bottom surface constitutes the receiving surface of the rebound stopper, so a predetermined plate thickness is required in terms of strength. Therefore, the thickness between the inner diameter surface of the inner cylinder and the outer diameter surface of the outer cylinder in the inner-outer double cylinder portion becomes large, and therefore,
As is often seen in the strut type, if the difference in bore between the outer shape of the piston rod and the inner diameter of the cylinder tube is small, it may not be possible to apply the rod guide structure as in the conventional example.

The present invention has been made by paying attention to the above-mentioned conventional problems, and can be applied even when the difference in bore between the outer diameter of the piston rod and the inner diameter of the cylinder tube is small, and An object of the present invention is to provide a hydraulic shock absorber capable of ensuring sufficient strength even when the rebound stopper collides.

[0008]

In order to achieve the above-mentioned object, in a hydraulic shock absorber of the present invention, a cylinder tube in which a piston is slidably accommodated and an outer chamber for forming a reservoir chamber in its outer periphery are formed. A rod guide is provided at both open ends of the tube and has a rod insertion hole in the center for guiding the sliding of the piston rod, and the piston is provided at the upper end opening of the outer tube above the rod guide. The rod guide includes a closing member including an oil seal that slidably seals the rod, and a rebound stopper provided on the piston rod in the cylinder tube, and the rod guide is formed by press-molding a single plate material. An outer diameter portion that is inscribed and centered on the inner diameter surface of the outer tube, an upper end flat portion that supports the closing member, and the upper end flat portion It is formed by a support cylinder portion that hangs in the axial direction from the inside, an intermediate flat surface portion that is formed at the lower end of the support cylinder portion and that engages with the upper end opening end surface of the cylinder tube, and a cylindrical portion that is inscribed in the inner diameter surface. There is a gap between the engaging step portion and the lower end of the tubular portion of the engaging step portion in the axial direction, and the outer surface has a gap between the inner surface of the cylinder tube and the piston rod slides on the inner surface. A guide bush for guiding is configured by a small-diameter tubular portion into which the guide bush is pressed, and a rebound stopper receiving surface is configured by the small-diameter tubular portion of the rod guide and the lower end surface of the guide bush.

Further, in the hydraulic shock absorber according to the present invention, the small diameter cylindrical portion and the guide bush are separated from the gap formed between the outer diameter surface of the small diameter cylindrical portion of the rod guide and the inner diameter surface of the cylinder tube. It is configured such that the total plate thickness of is larger.

[0010]

Since the hydraulic shock absorber of the present invention is configured as described above, at the time of full rebound of the hydraulic shock absorber,
The rebound stopper provided on the piston rod is received by the rebound stopper receiving surface composed of the small diameter cylindrical portion of the rod guide and the lower end surface of the guide bush.
Further extension is blocked.

When the rebound stopper collides, a load is axially applied to the small-diameter cylindrical portion of the rod guide, so that even a press-formed product of a plate material can have sufficient strength.

Further, since the portion of the rod guide to be inserted into the cylinder tube is composed of a small-diameter cylindrical portion,
Even when the difference between the outer diameter of the piston rod and the inner diameter of the cylinder tube is small, it can be sufficiently applied.

Further, since the outer diameter of the small-diameter cylindrical portion is smaller than the inner diameter surface of the cylinder tube and a gap is formed between the outer-diameter surface of the small-diameter cylindrical portion and the inner diameter surface of the cylinder tube, the action of lateral force is exerted. The small-diameter tubular portion follows and deforms in accordance with the inclination of the piston rod due to the above, and this makes it possible to prevent local deterioration of the surface pressure on the rod guide and reduce friction.

[0014]

Embodiments of the present invention will now be described in detail with reference to the drawings. First, the configuration of the embodiment will be described. FIG. 2 is an overall sectional view showing a hydraulic shock absorber according to an embodiment of the present invention. In this figure, 1 is a cylinder tube, 2 is a piston, 3 is a rebound rubber (rebound stopper), 4 is a piston rod, and 5 is a piston rod. An outer tube, 6 is a base, 7 is a rod guide, 11 is an oil seal, 12 is a packing land cover, A is an upper chamber, B is a lower chamber, and C is a reservoir chamber.

Next, FIG. 1 is an enlarged sectional view showing a portion of the rod guide 7. As shown in FIG. 1, the rod guide 7 is formed by press-molding one circular plate material. The outer cylindrical portion (outer diameter portion) 7a inscribed in the inner diameter surface of the outer tube 5 and centered in order from the outer peripheral side, the inclined surface portion 7b inclined inward, and the upper end flat surface supporting the oil seal 11. A portion 7c, and a support cylinder portion 7d that hangs axially from the inside of the upper end flat surface portion 7c,
Engagement stepped portion formed at the lower end of the support cylinder portion 7d and formed by an intermediate flat surface portion 7e which is locked to the upper end opening end surface of the cylinder tube 1 and a cylindrical portion 7f which is inscribed in the inner diameter surface of the cylinder tube 1. 71 and the cylindrical portion 7 of the engagement step 71
An annular locking rib 7g that bulges inward from the lower end of f
And a small-diameter cylindrical portion 7h that is hung from the lower end of the locking rib 7g in the axial direction and has an outer peripheral surface having a smaller diameter than the inner diameter surface of the cylinder tube 1.

Further, a guide bush 8 for guiding the sliding of the piston rod 4 is press-fitted and fixed to the inner diameter surface of the small-diameter cylindrical portion 7h forming a lot insertion hole through which the piston rod 4 is inserted. The guide bush 8 is set such that the outer peripheral edge portion of the upper end thereof is abutted and locked by the locking rib 7g, and the lower end surface thereof is flush with the lower end surface of the small diameter cylindrical portion 7h of the rod guide 7. In addition, the lower end surface of the guide bush 8 and the lower end surface of the small diameter cylindrical portion 7h constitute a rebound stopper receiving surface 9 that receives the rebound rubber 3 at the time of full rebound.

The gap E ₁ between the cylinder tube 1 and the small-diameter cylindrical portion 7h is at least the small-diameter cylindrical portion 7h and the guide bush in order to prevent the rebound rubber from being caught or cracked at the time of full rebound. 8 and the total thickness E ₂ are set to be smaller.

By forming the rod guide 7 by press-forming a plate material as described above, an annular space 10 for accumulating the working fluid is formed on the upper surface side of the rod guide 7. It is in a state of being communicated with the reservoir chamber C through a small hole 72 formed in the support cylinder portion 7d.

The oil seal 11 is provided on the upper side of the rod guide 7. This oil seal 11
Has a reinforcing ring (closing member) 11a fitted to the inner circumference of the outer tube 5, and the reinforcing ring 11a is attached to the outer circumference of the piston rod 4 on the inner circumference side thereof. A strip 11b and a sealing lip 11c are provided. Further, the lower surface of the reinforcing ring 11a is abutted and supported on the upper end flat surface portion 7c of the rod guide 7, and the upper end of the outer tube 5 is bent inward and crimped on the upper side of the reinforcing ring 11a. The oil seal 11 and the rod guide 7 are fixed while being subjected to the internal residual axial force.

Further, the seal ring 13 sandwiched between the reinforcing ring 11a and the inclined surface portion 7b of the rod guide 4.
Thus, the inner diameter surface of the outer tube 1 and the outer diameter surface of the reinforcing ring 11a are hydraulically sealed.

Next, the operation of the embodiment will be described. Since the hydraulic shock absorber of the present embodiment is configured as described above, at the time of full rebound of the hydraulic shock absorber, the rebound rubber 3 provided on the piston rod 4 causes the rod guide 7 to move.
The rebound stopper receiving surface 9 composed of the small-diameter cylindrical portion 7h and the lower end surface of the guide bush 8 receives the rebound stopper, and further extension is prevented.

When the rebound rubber 3 collides, a load is axially applied to the small-diameter cylindrical portion 7h of the rod guide 7, so that even a press-molded product of a plate material has sufficient strength. be able to.

Further, since the portion of the rod guide 7 to be inserted into the cylinder tube 1 is composed of the small-diameter cylindrical portion 7h, the outer diameter of the piston rod 4 and the cylinder tube 1 are
Even if the difference in bore from the inner diameter of is small, it can be sufficiently applied.

Further, the piston rod 4 by the action of lateral force
With respect to the inclination of the rod guide 7, since the small-diameter cylindrical portion 7h deforms following the gap E ₁ formed between the outer diameter surface of the small-diameter cylindrical portion 7h and the inner diameter surface of the cylinder tube 1, Local deterioration of surface pressure is prevented, and thus friction can be reduced.

As described above, the hydraulic shock absorber according to this embodiment has the following effects.

The present invention can be applied even when the diameter difference between the outer diameter of the piston rod and the inner diameter of the cylinder tube is small, and sufficient strength can be ensured against the collision of the rebound stopper.

Since the rod guide 7 is formed by press-molding a single plate material, the weight can be reduced, and the assembling property is excellent, and the manufacturing is easy, so that the cost can be reduced. Will be able to.

Friction can be reduced by preventing local deterioration of surface pressure on the rod guide 7 due to lateral force.

Although the embodiment of the present invention has been described in detail above with reference to the drawings, the specific structure is not limited to this embodiment, and even if there is a design change or the like within the scope not departing from the gist of the present invention. Included in the present invention.

[0030]

As described above, in the hydraulic shock absorber of the present invention, the rod guide is formed by press molding of one plate material, and the rod guide is inscribed in the inner surface of the outer tube and centered. A diameter portion, an upper end flat portion that supports the closing member, a support cylindrical portion that hangs axially from the inside of the upper end flat portion, and an upper end opening end surface of the cylinder tube that is formed at the lower end of the support cylindrical portion. An engaging step formed by an intermediate flat surface part that stops and a tubular part that is inscribed in the inner diameter surface, and an outer surface that hangs axially from the lower end of the tubular part of the engaging step and the outer surface is the cylinder tube inner diameter. The outer diameter of the piston rod and the cylinder tube are made up of a small-diameter cylinder part that has a gap between the inner surface and a guide bush that press-fits the inner surface to guide the sliding of the piston rod. Has a small difference from the inner diameter of It can be applied even if already there and effect that it is possible also to ensure a sufficient strength against collision rebound stopper.

Further, since the outer diameter of the small-diameter cylindrical portion is smaller than the inner diameter surface of the cylinder tube and a gap is formed between the outer-diameter surface of the small-diameter cylindrical portion and the inner diameter surface of the cylinder tube, the inclination of the piston rod The small-diameter tubular portion follows and deforms in accordance with the above, and this makes it possible to prevent local deterioration of surface pressure on the rod guide and reduce friction.

[Brief description of drawings]

FIG. 1 is an enlarged half sectional view showing a rod guide portion which is a main part of a hydraulic shock absorber according to an embodiment of the present invention.

FIG. 2 is an overall sectional view showing a hydraulic shock absorber according to an embodiment of the present invention.

[Explanation of symbols]

1 Cylinder Tube 2 Piston 3 Rebound Rubber (Rebound Stopper) 4 Piston Rod 5 Outer Tube 7 Rod Guide 7a Outer Cylindrical Part (Outer Diameter Part) 7c Upper End Flat Part 7d Supporting Cylindrical Part 7e Intermediate Flat Part 7f Cylindrical Part 7h Small Diameter Part 8 Guide bush 9 Rebound stopper receiving surface 11a Reinforcing ring (closure member) 71 Engaging step C Reservoir chamber E ₁ Gap E ₂ Total plate thickness

Claims (2)

[Claims] 1. A rod which is provided at both open end portions of a cylinder tube in which a piston is slidably accommodated and an outer tube which forms a reservoir chamber on the outer periphery thereof, and which guides sliding of a piston rod in a central portion. A rod guide having an insertion hole, a closing member provided at an upper end opening of the outer tube above the rod guide and including an oil seal for slidably sealing the piston rod, and a piston rod in the cylinder tube. The rod guide is formed by press-molding a single plate material, an outer diameter portion that is inscribed in the inner diameter surface of the outer tube and is centered, and an upper end flat portion that supports the closing member. A supporting cylinder portion that hangs in the axial direction from the inside of the upper end flat surface portion, and a seal formed at the lower end of the supporting cylinder portion. An engaging step portion formed of an intermediate flat surface portion that engages with the upper end opening end surface of the inner tube and a tubular portion that is inscribed in the inner diameter surface, and hangs axially from the lower end of the tubular portion of the engaging step portion. And a small-diameter cylindrical portion in which the outer surface has a gap with the inner diameter surface of the cylinder tube, and a guide bush for guiding the sliding of the piston rod is press-fitted into the inner diameter surface. And a lower end surface of the guide bush constitutes a rebound stopper receiving surface. 2. The total plate thickness of the small diameter cylinder and the guide bush is larger than the gap formed between the outer diameter surface of the small diameter cylinder and the inner diameter surface of the cylinder tube in the rod guide. The hydraulic shock absorber according to claim 1, wherein the hydraulic shock absorber is configured.