JP3301470B2 - Hydraulic shock absorber - Google Patents

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 sealing structure for sealed gas.

[0002]

2. Description of the Related Art Conventionally, as a hydraulic buffer, for example, there is a hydraulic buffer described in Japanese Utility Model Laid-Open No. 57-70537.

In this conventional hydraulic shock absorber, as shown in FIG. 4, a rod guide 12 is fitted into an outer tube 10 via a seal ring 11, and a plug member 13 is screwed into an upper end portion of the outer tube 10. In the hydraulic shock absorber, a gas escape passage 14 formed of an annular groove is formed at a screw terminal portion below the outer tube 10 so that the plug member 13 for the outer tube 10 can be removed when the hydraulic shock absorber is disassembled.
When the seal ring 11 is pushed up to the gas release passage 14 in the process of loosening the screw, the interference of the seal ring 11 is released and the sealing gas is released from the gap formed on the outer periphery of the seal ring 11. It was configured to be able to.

[0005] As shown in detail in FIGS. 5 and 6, a mounting groove 15 for the seal ring 11 is formed on the outer peripheral upper end surface of the rod guide 12.
Is formed by a horizontal bottom surface 15a and a tapered surface 15b having a smaller diameter toward the upper end. The outer peripheral lower end surface 13a of the horizontal plug member 13 allows the seal ring 11 in the mounting groove 15 to be tightly mounted. The outer peripheral surface of the seal ring 11 is pushed into the inner tube 1
The inner tube of the outer tube 10 is pressed against the inner surface of the outer tube 10 and the outer surfaces of the rod guide 12 and the plug member 13 with a predetermined interference.

[0005]

However, in such a conventional hydraulic shock absorber, when the hydraulic shock absorber is disassembled, the screwing of the plug member 13 into the outer tube 10 is loosened. As shown in FIG. 5, when the seal ring 11 is pushed up to the inside of the gas release passage 14 formed by the annular groove formed in the screw end portion of the outer tube 10, the interference of the seal ring is released. However, the side surface of the escape groove 14 with which the outer peripheral side surface of the seal ring 11 abuts is vertical, and the inner peripheral wall surface (taper surface 1) of the mounting groove 15 with which the inner peripheral side surface of the seal ring 11 abuts.
5b), the line connecting the side surface of the relief groove 14 and the contact point of the seal ring 11 with the tapered surface 15b of the mounting groove 15 is almost horizontal, and thus the sealing from the lower surface is performed. Since the pressure receiving surface of the gas pressure is substantially on the lower surface side of the seal ring 11, a gap is hardly formed between the inner peripheral surface of the outer tube and the outer peripheral surface of the seal ring 11, and therefore, the escape of the sealed gas is deteriorated. There was a problem.

[0006] Further, as shown in FIG.
1 is formed on a tapered surface 15b having a smaller diameter as the inner peripheral wall surface of the mounting groove 15 with which the inner peripheral surface of the mounting groove 1 contacts increases, and the plug member 1 with which the upper surface of the seal ring 11 contacts.
Since the outer peripheral lower end surface 13a of the seal ring 11 is formed horizontally, when the gas pressure received on the lower surface side of the seal ring 11 increases, the seal ring 11 seals in the upper direction, in which the interference in the circumferential direction decreases. Since the ring 11 is pushed up, especially at the time of full bounce in a high temperature state where the gas pressure becomes high, the interference between the inner peripheral surface of the outer tube 10 and the outer peripheral surface of the seal ring 11 is reduced, and the gas sealing is reduced. There was also a problem that the property deteriorated.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned conventional problems, and has as its object to provide a hydraulic shock absorber capable of reliably releasing (depressurizing) a sealed gas during a disassembling operation. It is an additional object of the present invention to ensure the sealing property of the sealed gas even when the sealed gas pressure increases in the assembled state.

[0008]

In order to achieve the above object, in the hydraulic shock absorber according to the first aspect of the present invention, a rod guide mounted in an outer tube and an upper portion of the rod guide are provided. A plug member screwed into a screw portion formed in an upper end opening of the outer tube, and a plug member interposed between the outer peripheral lower end portion of the plug member and the outer peripheral upper end portion of the rod guide so as to sandwich the outer tube. In a hydraulic shock absorber provided with a seal ring for sealing between an inner periphery and an outer periphery of a rod guide and a plug member, a chamfered portion is formed on an outer peripheral edge of an upper end of a rod guide serving as one holding surface of the seal ring. A clearance groove having a diameter larger than that of the seal ring abutment surface and opening the seal ring is formed at an inner peripheral surface of the outer tube at an end portion of the screw portion, and an upper end opening inner peripheral portion of the clearance groove is formed. The rod guy And a means which is formed on the inclined surface of the chamfered portion in the same direction.

Further, in the hydraulic shock absorber according to the second aspect, the inclined angle of the chamfered portion of the rod guide from the axial direction is formed larger than the inclined surface of the inner peripheral portion of the upper end opening of the relief groove. Configuration.

Further, in order to achieve the above-mentioned additional object, in the hydraulic shock absorber according to the third aspect, a chamfered portion is formed on an outer peripheral edge of a lower end of a plug member serving as another holding surface of the seal ring. Is formed.

[0011]

In the hydraulic shock absorber according to the present invention, since the hydraulic shock absorber is constructed as described above, the screw end of the outer tube is reduced during the disassembly of the hydraulic shock absorber by loosening the screwing of the plug member into the outer tube. When the seal ring is pushed up to the inside of the escape groove formed in the part, the interference of the seal ring is released, and the inner periphery of the upper end opening of the escape groove is in the same direction as the chamfered part of the rod guide. Is formed on the inclined surface, the line connecting the inclined surface on the clearance groove side and the contact point of the seal ring with the chamfered portion of the rod guide is inclined from the horizontal state to the direction in which the inclined surface side is higher and the chamfered portion side is lower. As a result, the pressure receiving surface of the sealed gas pressure from the lower surface moves outward from the lower surface side of the seal ring, and the component force of the sealed gas pressure pressing the seal ring inward is reduced. It will be use.

Therefore, a gap is easily formed between the inner peripheral surface of the outer tube and the outer peripheral surface of the seal ring, so that the sealed gas can be reliably released.

Further, in the hydraulic shock absorber according to the second aspect, the inclined angle of the chamfered portion of the rod guide from the axial direction is larger than the inclined surface of the inner peripheral portion of the upper end opening of the relief groove. Since the distance between the two contact points of the seal ring with respect to the inclined surface and the chamfered portion increases inward, the deformation and movement of the seal ring inward due to the sealing gas pressure are performed smoothly. Is performed more reliably.

According to a third aspect of the present invention, a chamfered portion is formed at the outer peripheral edge of the lower end of the plug member, which is the other holding surface of the seal ring, so as to be inwardly directed by the sealed gas pressure. Since the space for deforming and moving the seal ring is widened, the sealed gas can be more reliably released.

Further, in the assembled state of the hydraulic shock absorber, the sealing gas pressure rises, and when this gas pressure is received on the lower surface side of the seal ring, the seal ring is pushed upward and the upper surface side of the sealing member is closed. Although it is pressed against the outer peripheral lower end surface, since the lower end outer peripheral edge portion of the plug member is formed with a chamfered portion, it acts in a direction in which the interference with the inner peripheral surface of the outer tube increases along the inclination thereof. For,
The sealing property of the sealed gas is improved.

[0016]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. First, the configuration of the embodiment will be described. FIG. 1 is an enlarged sectional view showing a seal portion which is a main part of a hydraulic shock absorber according to an embodiment of the present invention. In this figure, reference numeral 1 denotes an outer tube, which is not shown in the outer tube 1. A rod guide 2 for guiding the sliding of the piston rod is fitted.

On the inner peripheral surface of the upper end opening of the outer tube 1, a screw portion 1a for screwing the plug member 3 into the upper end opening of the outer tube 1 is formed.
A relief groove 4 is formed on the inner peripheral surface of the outer tube 1 which is the lower end of the outer tube 1. Further, the screw portion 1a
, A vertical groove 1b for exhaust gas is formed so as to communicate with the escape groove 4. The sectional shape of the escape groove 4 is
The lower side of the inner surface is formed in a substantially arcuate surface, and the upper side of the inner surface has a linear inclined surface 4a whose diameter decreases upward.
Is formed.

At the outer peripheral edge of the lower end of the plug member 3, a chamfered portion 3a having a larger diameter as it goes upward is formed, while the outer peripheral edge of the upper end of the rod guide 2 axially opposed to the chamfered portion 3a. A chamfered portion 2a having a larger diameter as it goes downward is formed in the portion.
By interposing the seal ring 5 between the 2a in a sandwiched state, a gas seal is formed between the inner circumference of the outer tube 1 and the outer circumferences of the rod guide 2 and the plug member 3.

[0019] Then, the inclination angle from the relief to the inclination angle alpha ₁ from the axial direction of the inner surface the upper inclined surface 4a of the groove 4, the axial direction of the chamfered portions 2a formed at the lower outer periphery of the rod guide 2 α ₂ is configured to be larger.

Next, the operation of the embodiment will be described. (A) Gas sealing property in assembled state In the assembled state of the hydraulic shock absorber, especially in the case of full bound in a high temperature state where the filled gas pressure is high, as shown in FIG. When the seal ring 5 is received on the lower surface side of the ring 5, the seal ring 5 is pushed upward and the upper surface side is pressed against the outer peripheral lower end surface of the plug member 3. Is formed in the chamfered portion 3a, which acts on the inner tube of the outer tube 1 in a direction in which the interference is increased, so that the sealing property of the sealed gas is ensured.

(B) Degassing property during disassembly During disassembly of the hydraulic shock absorber, in the process of loosening the screwing of the plug member 3 into the outer tube 1, as shown in FIG. When the seal ring 5 is pushed up to the inside of the clearance groove 4 formed at the terminal end, the interference of the seal ring 5 is released, and the inner peripheral portion of the upper end opening of the clearance groove 4 is formed by the rod guide 2. Is formed on the inclined surface 4a in the same direction as the chamfered portion 2a, so that a line g connecting the inclined surface 4a on the clearance groove 4 side and the contact point PP of the seal ring 5 to the chamfered portion 2a of the rod guide 2 is formed. ₂ is inclined from the horizontal state in a direction in which the inclined surface 4a side is higher and the chamfered portion 2a side is lower, so that the pressure receiving surface of the sealing gas pressure from the lower surface moves outward from the lower surface side of the seal ring 5. I Charged gas pressure will act the component force that presses the seal ring 5 inward.

Further, with respect to the inclination angle alpha ₁ from the axial direction of the inclined surfaces 4a, so that the direction of the inclination angle alpha ₂ from the axial direction of the chamfered portions 2a formed at the lower outer periphery of the rod guide 2 increases The inclined surface 4a
Contacts P of the seal ring 5 with respect to the chamfered portion 2a
Since the interval between the -Ps increases toward the inside, the deformation and movement of the seal ring 5 in the inward direction due to the sealed gas pressure can be smoothly performed, and further, the plug member 3
Due to the chamfered portion 3a formed in the outer peripheral edge of the lower end of the seal ring, the space for deforming and moving the seal ring inward due to the pressure of the sealed gas is expanded.

Accordingly, a gap is easily formed between the inner peripheral surface of the outer tube 1 and the outer peripheral surface of the seal ring 5, and thus, the sealed gas is released (pressurized) reliably.

As described above, in the hydraulic shock absorber of this embodiment, in the assembled state, the sealing property of the sealed gas can be ensured even when the sealed gas pressure increases, and the disassembling operation can be performed. The effect is obtained that the sealed gas can be released (pressurized) in the process without fail.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and even if there is a design change or the like without departing from the gist of the present invention. Included in the present invention.

[0026]

As described above, in the hydraulic shock absorber of the present invention, the rod guide mounted in the outer tube and the upper end of the rod guide are formed in the upper end opening of the outer tube. A plug member screwed into the screw portion, and interposed between the lower end of the outer periphery of the plug member and the upper end of the outer periphery of the rod guide so as to be sandwiched between the inner periphery of the outer tube and the outer periphery of the rod guide and the stopper member And a seal ring that seals between the outer ring and the outer peripheral portion of the outer tube. At the end of the threaded portion, a clearance groove having a diameter larger than that of the seal ring contact surface and opening the interference of the seal ring is formed, and the inner peripheral portion of the upper end opening of the clearance groove is formed in the same direction as the chamfered portion of the rod guide. Shape on slope Because the pressure receiving surface of the sealed gas pressure from the lower surface moves outward from the lower surface side of the seal ring, the component force of the sealed gas pressure pressing the seal ring inwardly acts. In this state, a gap is easily formed between the inner peripheral surface of the outer tube and the outer peripheral surface of the seal ring, whereby the effect of reliably releasing the sealed gas (pressurizing) can be obtained.

Further, in the hydraulic shock absorber according to the second aspect, the inclination angle of the chamfered portion of the rod guide from the axial direction is larger than that of the inclined surface of the inner peripheral portion of the upper end opening of the relief groove. With this configuration, the distance between the two contact points of the seal ring with respect to the inclined surface and the chamfered portion becomes wider toward the inside, so that the deformation and movement of the seal ring in the inward direction due to the sealed gas pressure are performed smoothly. Thus, the effect that the filling gas can be more reliably released is obtained.

According to a third aspect of the present invention, in the hydraulic shock absorber according to the third aspect of the present invention, a chamfered portion is formed on an outer peripheral edge of a lower end of a plug member serving as another holding surface of the seal ring. Is formed, the space for deforming and moving the seal ring inward due to the pressure of the sealing gas expands, whereby the sealing gas can be more reliably vented, and in the assembled state, Due to the tapered surface on the plug member side, an effect is obtained that the sealing property of the sealed gas can be ensured even when the sealed gas pressure increases.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a main part of a hydraulic buffer according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a main part for describing a gas sealing operation in an assembled state of the hydraulic shock absorber according to the embodiment of the present invention.

FIG. 3 is a cross-sectional view of a main part showing a degassing state during disassembly of the hydraulic buffer according to the embodiment of the present invention.

FIG. 4 is a sectional view showing a main part of a conventional hydraulic shock absorber.

FIG. 5 is an enlarged cross-sectional view of a main part for describing a gas releasing operation when disassembling a conventional hydraulic shock absorber.

FIG. 6 is an enlarged cross-sectional view of a main part for explaining a gas sealing operation in an assembled state of a conventional hydraulic shock absorber.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Outer tube 1a Screw part 2 Rod guide 2a Chamfer part 3 Plug member 3a Chamfer part 4 Escape groove 4a Inclined surface 5 Seal ring

Claims (3)

(57) [Claims] 1. A rod guide mounted in an outer tube, a plug member screwed into a thread formed in an upper end opening of the outer tube above the rod guide, and a lower peripheral lower end of the plug member And a seal ring interposed between the outer tube and the upper end of the rod guide in a sandwiched state, and provided with a seal ring that seals between the inner periphery of the outer tube and the outer periphery of the rod guide and the plug member. A chamfered portion is formed on the outer peripheral edge of the upper end of the rod guide, which serves as one holding surface of the seal ring, and at the end portion of the screw portion on the inner peripheral surface of the outer tube,
A relief groove having a diameter larger than that of the seal ring contact surface is formed to release the interference of the seal ring, and an inner peripheral portion of an upper end opening of the relief groove is formed on an inclined surface in the same direction as the chamfered portion of the rod guide. And a hydraulic buffer. 2. The inclination angle of the chamfered portion of the rod guide from the axial direction is larger than that of the inclined surface of the inner peripheral portion of the upper end opening of the clearance groove. Hydraulic shock absorber. 3. The hydraulic shock absorber according to claim 1, wherein a chamfered portion is formed at an outer peripheral edge of a lower end of a plug member serving as another holding surface of the seal ring.