JPH0140355Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a hydraulic shock absorber used for suspension of a vehicle such as a motorcycle.

[Prior art]

Generally, in the body suspension of a motorcycle, a piston is slidably fitted into a cylinder filled with hydraulic oil.
A hydraulic shock absorber is used which generates a damping force as the piston strokes. In recent years, in order to improve the riding comfort of a vehicle, a system has been proposed in which the damping force during the normal stroke of the piston is weakened. However, if the damping force of the normal stroke remains weakened, bottoming will occur at the most compression end of the piston, so in order to prevent this bottoming out phenomenon, the hydraulic oil passage is closed at the most compression end of the stroke and a large A structure that generates damping force has been proposed.

However, in all conventional systems, since the oil passage is simply closed, the damping force is rapid, and it cannot necessarily be said that they provide a good ride comfort when used for suspension of a vehicle.

[Purpose of invention]

The purpose of this invention is to create a hydraulic shock absorber for vehicle suspension that can smoothly change the damping force when generating a large damping force at the most compression end of the stroke and provide a comfortable ride without any discomfort. Our goal is to provide the following.

[Structure of the idea]

The present invention, which achieves the above object, is a vehicle suspension hydraulic system in which a piston is slidably fitted into a main cylinder filled with hydraulic oil, and a sub cylinder filled with gas is connected to the main cylinder via a communication passage. In the shock absorber, a connection port to the main cylinder side of the communication passage is opened near the most compression end within the sliding stroke range of the piston, and a notch extending in the axial direction of the main cylinder is connected to this connection port, or opening a connection port of a sub passage in communication with the communication passage at a position apart in the axial direction of the main cylinder;
and the length L of the notch in the main cylinder axial direction or the maximum length L in the main cylinder axial direction between the two connection ports is larger than the axial length l of the piston. It is something to do.

[Example of idea]

The present invention will be explained below with reference to embodiments shown in the drawings.

In Fig. 1, 1 is a main cylinder filled with hydraulic oil, and its end has a connecting hole 3, commonly called the eyeball.
It is usually connected to a frame that supports the wheels. A piston 2 fits into the main cylinder 1, and is designed to slide with a sliding stroke from a most extended position shown by a solid line to a most compressed position shown by a chain line. The piston 2 is fixed to the tip of a rod 4, and a support member 5 is attached to the other end of the rod 4.
is fixed. The other connecting hole 6, commonly called an eyepiece, is provided at the end of the support member 5, and the support member 5 is connected to the frame through this connecting hole 6. Spring receivers 7 and 8 are provided on the outer periphery of the support member 5 and the outer periphery of the cylinder 1, respectively.
A spring 9 is stretched between them.

The piston 2 has an orifice 10 in its center.
is provided. This orifice 10 includes front and rear cylinder chambers 1a and 1b separated by the piston 2.
The opening area of the needle valve 11 can be adjusted by adjusting the position of the needle valve 11 in the axial direction. Further, the piston 2 is provided with a valve 12 made of an elastic material, and the valve 12 is designed to balance the hydraulic pressure in the front and rear cylinder chambers 1a, 1b and allow the flow of hydraulic oil.

13 is a sub cylinder. This sub-cylinder 13
A free piston 14 is fitted inside the chamber, and the free piston 14 partitions the chamber into a gas chamber 15 and an oil chamber 16. The free piston 14 slides in the axial direction due to the balance between the pressure of the gas filled in the gas chamber 15 and the oil pressure applied to the oil chamber 16.

The sub-cylinder 13 is connected to the main cylinder 1 via a communication passage 17. The connection port 18 of the communication passage 17 that opens toward the main cylinder 1 is located within the sliding stroke range of the piston 2, and opens near the most compression end of the sliding stroke. Further, the connection port 18 is provided with a notch 18a extending in the axial direction of the main cylinder 1, and the notch 18a has a shape that gradually narrows as it moves away from the connection port 18, as shown in FIG. be. The length L of this notch 18a in the main cylinder axial direction is set to be larger than the axial length l of the piston 2.

The operation of the above-mentioned hydraulic shock absorber will be explained with reference to FIG.

Now, if the internal cross-sectional area of the main cylinder 1 in the direction perpendicular to the axial direction is Ac, the cross-sectional area of the rod 4 in the direction perpendicular to the axial direction is Ar, and the stroke speed of the piston 2 is v, then the piston 2 is connected. During the compression stroke in the normal use range where the port 18 is not reached, the cylinder chambers 1a to 1b are compressed via the valve 12.
The flow rate Q ₁ of the hydraulic oil flowing to is Q ₁ = (Ac-Ar) x v
and the sub cylinder 13 via the communication passage 17.
The flow rate Q ₂ of the hydraulic oil flowing to the side is Q ₂ =Ar×v. When the piston 2 further advances its compression stroke and passes the connection port 18, the communication passage 17
Since there is no more hydraulic oil escaping to the valve 12,
The flow rate Q ₁ of the hydraulic oil passing through increases to Q ₁ =Ac×v. Therefore, at the compression end of the stroke, the damping force increases by the amount of increase in flow rate Ar×v.

In this case, as shown in the relationship graphs between flow rate Q ₁ and stroke S and buffering force F and stroke S shown in FIG. 3, if notch 18a is not provided in connection port 18, flow rate Q ₁ and The buffering force F means that when the piston 2 passes through the connection port 18, it closes the connection port 18, so the flow rate _Q2 becomes 0 and _Q1 becomes as shown by the chain line A. Since the oil in the oil chamber 1a is trapped, an impact force as shown by the chain line a is temporarily applied to the rod 4. However, when the connection port 18 is provided with the notch 18a with the relationship L>l as in the embodiment, the flow rate
Q ₁ and the damping force F change smoothly as shown by the solid lines B and b, thereby eliminating the sense of discomfort when the damping force increases.

FIG. 4 shows another embodiment of the present invention.

In this embodiment, the connection port 18 of the communication path 17
The notch 18a as in the first embodiment is not provided, but a sub passage 17' is provided instead, and between the two passages 17, 17' there is a connection from the sub passage 17' to the communication passage 17. A pressure regulating valve 20 that allows flow from the communication passage 17 to the auxiliary passage 17', and a check valve 21 that allows flow from the communication passage 17 to the sub passage 17' are provided. Also, these two passages 17, 17'
The connection port 18, 1 opens on the main cylinder 1 side of the
The distance L between the farthest axial ends of the piston 8' is set to be greater than the axial length l of the piston 2.

In the case of the hydraulic shock absorber of this embodiment, its operation is similar to that of the first embodiment, and as shown in FIG. The flow rate Q ₁ of the hydraulic oil passing through is Q ₁ = (Ac-Ar)×v, and the flow rate Q ₂ of the hydraulic oil flowing toward the sub cylinder 13 side via the communication passage 17 is Q ₂ = Ar×v. becomes. As the piston 2 continues its compression stroke and passes the connecting ports 18, 18', the flow rate Q ₁ of the hydraulic fluid passing through the valve 12 increases to Q ₁ =Ac×v. Therefore, at the compression end of this stroke, the damping force increases by the amount of increase in flow rate Ar×v.

Moreover, the increase in the damping force F at this time is due to the fact that the piston 2 is located between the connecting ports 18 and 18', as shown in the relationship graph between the flow rate _Q1 and the stroke S and the buffering force F and the stroke S shown in FIG. When stroking, some of the hydraulic oil flows into the sub-flow path
7' to the sub cylinder 13 via the pressure regulating valve 20, the flow rate _Q1 and the buffering force F are as follows from the curves C and c.
It changes smoothly as shown in . Therefore, it is possible to eliminate the sense of discomfort when the damping force increases.

[Effect of idea]

As mentioned above, the present invention provides a connection port in which the communication passage communicating with the sub-cylinder opens to the main cylinder side near the maximum compression end within the sliding stroke range of the piston. The notches extending in the main cylinder are connected to each other, or the connecting port of the sub passage connected to the communication passage is opened at a position apart in the axial direction of the main cylinder, and the length L of the notch in the axial direction of the main cylinder is Since the maximum main cylinder axial length L between the two connection ports is made larger than the axial length l of the piston, the piston can exert a large damping force while closing the connection port at the most compression end of its stroke. When the damping force is generated, the damping force can be smoothly changed. Therefore, there is no impact reaction force that causes discomfort, and extremely good riding comfort can be achieved.

[Brief explanation of the drawing]

Fig. 1 is a longitudinal sectional view showing a hydraulic shock absorber for a motorcycle according to an embodiment of the present invention in a horizontal state, Fig. 2 is a view taken in the direction of - arrow in Fig. 1, and Fig. 3 is a flow rate Q of hydraulic oil. FIG _{. 1} is an explanatory diagram illustrating the operation of the hydraulic shock absorber, in which a graph of the relationship between 1 and the stroke S of the piston and a graph of the relationship between the buffering force F and the stroke S of the piston are shown. Fig. 4 is a vertical sectional view showing the main parts of a hydraulic shock absorber for motorcycles according to another embodiment of the present invention, and Fig. 5 is a graph of the relationship between the flow rate _Q1 of hydraulic oil and the stroke S of the piston and the buffer force. F
FIG. 4 is an explanatory diagram illustrating the operation of the hydraulic shock absorber, with graphs of the relationship between S and the stroke S of the piston, respectively. 1... Main cylinder, 2... Piston, 4... Rod, 9... Spring, 12... Valve, 13
...Sub-cylinder, 14...Free piston, 15...
...Gas chamber, 17...Communication passage, 17'...Sub-passage,
18, 18'... Connection port, 18a... Notch.

Claims (1)

[Scope of utility model registration request] In a hydraulic shock absorber for vehicle suspension, in which a piston is slidably fitted into a main cylinder filled with hydraulic oil, and an auxiliary cylinder filled with gas is connected to the main cylinder via a communication path, the communication path 17 is A connection port 18 for the main cylinder 1 side is opened near the most compression end within the sliding stroke range of the piston 2, and a notch 18a extending in the axial direction of the main cylinder is connected to this connection port 18, or A connecting port 18' of a sub passage 17' that communicates with the communicating passage 17 is opened at a position separated from the axial direction, and the length L of the notch 18a in the main cylinder axial direction or the two connecting ports 18 ,1
A hydraulic shock absorber for vehicle suspension, characterized in that a maximum main cylinder axial length L between 8' and 8' is larger than an axial length l of the piston 2.