JP2004286197A - Front fork - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a front fork capable of improving riding comfortableness of a motorcycle even in a type where damping force at the time of a compression stroke is compensated by adding damping force due to pressure loss when operating fluid in a fluid chamber passes an orifice to damping force generated by a damper. <P>SOLUTION: Working fluid O is charged in a gap between the inner circumference of a car body side tube 1 and an axle side tube 2 and the outer circumference of a damper D, and a passage for working fluid O to pass is formed between the outer circumference of a cylinder body 3 and the inner circumference of the car body side tube 1 or the axle side tube 2 as a surface level SL of the working fluid O rises when the front fork is most contracted at least. At least two orifices 13 and 17 of different opening area are provided on the passage in such a way that their opening area becomes smaller in order from the axile side. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a front fork in which an inverted damper is provided inside a body-side tube and an axle-side tube, and a gas chamber and a liquid chamber are formed between the body-side and axle-side tubes and the damper. The present invention relates to an improvement of a front fork which generates a damping force by the working liquid as the working liquid level in the liquid chamber rises at the time.
[0002]
[Prior art]
This type of front fork has a single cylinder inverted damper inside a body tube and an axle tube, and a gas chamber and an oil reservoir between the outer tube and the inner tube and the damper. And a partition member supported by the cylinder and slidably in contact with the inner tube; an oil passage formed in the partition member; and a check valve having an orifice. The check valve closes and shuts off to provide throttling resistance to the movement of hydraulic oil in the oil reservoir by the orifice, and when the front fork is extended, the check valve opens to open the oil passage and pass the hydraulic oil. (For example, see Patent Document 1).
[0003]
According to this front fork, the damping force generated during the compression stroke is compensated for by adding the damping force due to the pressure loss when the hydraulic oil in the oil reservoir passes through the orifice to the damping force generated by the damper during contraction. At the time of extension, the check valve is opened and the hydraulic oil in the oil reservoir passes without resistance. Therefore, the ride force is improved by using only the damping force generated by the damper during the extension stroke.
[0004]
[Patent Document 1]
JP 2001-330076 A (page 5, left column, line 28 to page 5, right column, line 22; FIG. 1)
[0005]
[Problems to be solved by the invention]
However, the following problems may be pointed out in the above-described conventional front fork.
[0006]
That is, when the front fork contracts, the oil level rises due to the relative movement of the cylinder and the inner tube and the penetration of the cylinder into the oil reservoir. In the contraction process, damping force is generated by the damping force generating mechanism of the damper until the oil level reaches the orifice, and is generated when the hydraulic oil passes through the orifice after the oil level reaches the orifice. The damping force is added to the damping force generated by the damper.
[0007]
Further, since the partition member is supported by the cylinder, when the front fork contracts to a certain length, a damping force due to the hydraulic oil is suddenly generated, and this damping force is generated due to a pressure loss due to the orifice. , Which is proportional to the square of the relative speed of the inner tube to the outer tube.
[0008]
Therefore, there is a concern that the riding comfort of the motorcycle becomes rough due to the suddenly generated damping force, and the riding comfort is degraded. In particular, when the relative speed of the inner tube to the outer tube is relatively high, the ride quality is significantly deteriorated.
[0009]
Therefore, the present invention has been made in order to improve the above-described adverse effects, and an object of the present invention is to reduce the pressure loss when the working liquid in the liquid chamber passes through the orifice due to the damping force generated by the damper. It is an object of the present invention to provide a front fork that can improve the riding comfort of a motorcycle even in a front fork that supplements the damping force during a compression stroke by taking into account the damping force of the fork.
[0010]
[Means for Solving the Problems]
A first object of the present invention is to provide a damper in a vehicle body side tube by inserting an axle side tube slidably into a vehicle body side tube, providing a damper inside the vehicle body side tube and the axle side tube. A cylinder body is connected, and an axle tube is connected to a rod body that is inserted into and retractable from the cylinder body. A gap between the inner circumference of the vehicle body side tube and the axle side tube and the outer circumference of the damper is formed. In the front fork filled with the working liquid, a passage through which the working liquid passes between the outer periphery of the cylinder body and the inner periphery of the body-side tube or the axle-side tube at least when the front fork is in its maximum contraction as the working liquid level rises Is formed, and at least two orifices having different opening areas are provided in the flow passage so that the opening areas become smaller in order from the axle side. And wherein the door.
[0011]
According to the above configuration, as the front fork contracts, the generated damping force increases stepwise, that is, the generated damping force changes stepwise depending on the relative position between the vehicle body side tube and the axle side tube. Can be done.
[0012]
Therefore, since the damping force generated gradually increases with the contraction of the front fork, the problem that suddenly generated damping force like a conventional front fork makes the ride of a motorcycle rugged is solved. It is possible to improve the riding comfort of the motorcycle.
[0013]
In particular, if the orifice diameter is set small, a high damping force can be generated, and the interference between the cylinder body and the axle side tube, the body side tube and the axle side tube, or the cylinder body and the rod body, so-called It is also possible to prevent bottoming out, and it is advantageous in terms of ride comfort as compared to bottoming out prevention by an oil lock.
[0014]
A second object of the present invention is the first object solution, wherein the vehicle body side tube is an outer tube and the axle side tube is an inner tube. A partition member, and a flow path and the orifice are provided in the partition member.
[0015]
Further, a third object of the present invention is the first object of the present invention, wherein the vehicle body side tube is an inner tube and the axle side tube is an outer tube. A partition member, and a flow path and the orifice are provided in the partition member.
[0016]
Therefore, according to the second and third means for solving the problems, it is possible to easily change the generated damping force stepwise simply by providing the partition member having the orifice having the opening area different from the flow path. There is no need to have a complicated configuration such as forming a flow path and an orifice in the side tube, axle side tube or cylinder body, and there is an advantage that it can be applied to an existing front fork. In addition, since the partition member is configured as described above, the weight is reduced as compared with the case where the partition member is a thick cylinder, and the material cost is also advantageous.
[0017]
The fourth problem solving means of the present invention is the second problem solving means according to the second problem solving means, wherein the partition member is supported on the vehicle body side tube and has a cylindrical base end fitted to the outer periphery of the cylinder body. It is composed of a hollow truncated cone-shaped middle part extending from the middle part and a cylindrical tip part extending from the middle part and having a larger diameter than the base end part, and the inner periphery of the tip part and the middle part of the partition member. A flow passage and a first orifice are formed in a gap between the outer periphery of the cylinder body, a second orifice communicating the flow passage with the outside of the middle portion is provided in an intermediate portion, and an inner periphery of an axle-side tube is provided in an outer periphery of a tip portion. A sliding contact portion that slides on the sliding member is provided.
[0018]
According to a fifth aspect of the present invention, in the third aspect, the partition member is supported on the vehicle body-side tube and has a cylindrical base end fitted to the outer periphery of the cylinder body. A hollow truncated cone-shaped middle portion extending from the middle portion, and a cylindrical tip portion extending from the middle portion and having a larger diameter than the base end portion. A flow path and a first orifice are formed in a gap between the circumference and the outer periphery of the cylinder body, a second orifice communicating the flow path with the outside of the intermediate part is provided at an intermediate portion, and a vehicle body side tube is provided at a distal end portion. It is characterized in that a sliding portion or a connecting portion that slides on the periphery is provided.
[0019]
Therefore, according to the fourth and fifth means for solving the problem, since one of the plurality of orifices required for the present invention can be an annular orifice, a decrease in the strength of the partition member can be compensated, and thereby, the deformation of the partition member can be reduced. Evil, that is, the generated damping force does not reach a predetermined value, or the expansion and contraction of the front fork is hindered, and furthermore, when the partitioning member also functions as a spring receiver, the suspension spring is deformed by the body side tube, the axle side tube or It is possible to prevent damage to these members due to interference with the cylinder body, generation of abnormal noise and malfunction due to the interference. Therefore, performance deterioration and deterioration of the front fork can be prevented.
[0020]
Further, according to a sixth aspect of the present invention, in any one of the second to fifth aspects, the partition member supports a suspension spring interposed between the vehicle body side tube and the axle side tube. It is also characterized by serving as a spring receiver.
[0021]
Therefore, according to the sixth means for solving the problems, since the partition member also serves as the spring receiver, the number of components is reduced and the manufacturing cost is reduced as compared with the case where a separate partition member is provided.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to FIGS. 1 shows a first embodiment of a front fork according to the present invention, FIG. 2 shows a second embodiment of the front fork according to the present invention, and FIG. 3 shows a modification of a partition member of the front fork according to the present invention. FIG. 4 shows another modification of the partition member of the front fork of the present invention. As shown in FIG. 1, the front fork according to the first embodiment includes a body-side tube 1, an axle-side tube 2, a damper D, an inner periphery of the body-side tube 1 and the axle-side tube 2, and the damper D. And a partition member 10 and a suspension spring 18.
[0023]
More specifically, the vehicle body side tube 1 is formed in a bottomed cylindrical shape and has a bottom portion, that is, a collar 1a depending from the inside of the upper end in FIG. 1, and an inner peripheral side of the collar 1a. , The cylinder body 3 constituting the damper D is connected. Although the vehicle body side tube 1 has a cylindrical shape with a bottom as shown in the figure, it is composed of a cylindrical body and a sealing member for sealing an end portion, and the cylinder body 3 is connected to this sealing member. The collar 1a may also be configured so that it can be moved up and down in FIG. 1 with respect to the cylinder body 3 and the above-mentioned cylinder body as separate members. In this case, the collar 1a By being movable, the initial load on the suspension spring 18 described later can be adjusted, which is convenient.
[0024]
On the other hand, the axle-side tube 2 is also formed in a bottomed cylindrical shape, and a rod body 5 constituting a damper D is connected to the bottom portion, that is, the inside of the lower end in FIG. Although the axle-side tube 2 has a cylindrical shape with a bottom as shown in the figure, it is composed of a cylindrical body and a sealing member for sealing an end portion, and the rod member 5 is connected to this sealing member. Of course, it may be possible. Although not shown, a bracket (not shown) for connecting the axle of the motorcycle is appropriately provided near the lower end of the axle-side tube 2.
[0025]
The axle-side tube 2 is slidably inserted into the above-described body-side tube 1. That is, in this case, the body-side tube 1 is set as a so-called outer tube, and the axle-side tube 2 is set as a so-called inner tube. Although not shown, a bearing member (not shown) for ensuring the slidability between the vehicle body side tube 1 and the axle side tube 2 and the body side tube 1 and the axle side tube 2 are provided. A seal for properly sealing the inside is provided.
[0026]
Further, a conventionally known damper may be used for the damper D provided inside the vehicle body side tube 1 and the axle side tube 2, and a detailed description thereof will be omitted. A piston (not shown) slidably inserted into the cylinder body 3, a plurality of flow paths (not shown), and a damping force generating element (not shown) provided in each flow path (not shown). And a rod body 5 which is movably inserted into the cylinder body 3 via a piston (not shown) provided with the piston body (not shown), and operates the cylinder body 3 with the piston (not shown). A piston-side chamber (not shown) and a rod-side chamber (not shown), which are chambers, are separated from each other, and a working liquid such as working oil is sealed in a cylinder body 3. The free piston in the cylinder body 3 (Fig. ) Is slidably inserted to separate the inside of the cylinder body 3 from the working chamber and the gas chamber, and compensates for the excess or deficiency of the working liquid when the rod body 5 is protruded and retracted with respect to the cylinder body 3. On the other hand, in the case of a double cylinder type, an inner cylinder is further provided in the cylinder body 3 and the piston (not shown) and the rod body are provided in the inner cylinder (not shown). 5 and a gap between the inner circumference of the cylinder body 3 and the outer circumference of the inner cylinder (not shown) is used as a reservoir so as to compensate for an excess or deficiency of the working liquid when the rod body 5 is protruded and retracted from the inner cylinder. It is something that is made. That is, according to the above, when the rod body 5 protrudes and retracts in the cylinder body 3 in both the single cylinder type and the double cylinder type, the damping force generating element damping force (not shown) provided on the piston (not shown) is provided. ) Can generate a predetermined damping force.
[0027]
Therefore, in the above description, the cylinder body 3 constituting the damper D is connected to the vehicle body side tube 1 and the rod body 5 that is inserted into and retractable from the cylinder body 3 is connected to the axle side tube 2. When the axle-side tube 2 moves relative to the body-side tube 1, the damper D can generate a damping force so as to suppress the relative movement. That is, in this front fork, for example, Although not shown, the vicinity of the upper end of the vehicle body side tube 1 is connected to the vehicle body side of the motorcycle via a bracket (not shown), and a bracket (not shown) that will be provided near the lower end of the axle side tube 2 ) Is connected to the axle side of the two-wheeled vehicle, and is used to suppress vibration input from the road surface while the two-wheeled vehicle is traveling.
[0028]
Next, the partitioning member 10 will be described. The partitioning member 10 includes a cylindrical base end portion 11, a hollow frustoconical intermediate portion 12 extending from the base end portion 11, and an extending portion extending from the intermediate portion 12. It is provided with a cylindrical distal end portion 14 having a diameter larger than that of the base end portion 11, a guide 15 fitted on the outer periphery of the distal end portion 14, and a bush 16 fitted on the outer periphery of the guide 15. The base end 11 is fitted into the cylinder body 3, and the upper end of the base end 11 in FIG. 1 is brought into contact with the collar 1 a of the vehicle body side tube 1, and the middle part 12 is provided inside and outside thereof. A plurality of orifices 13 are formed to communicate with each other, and a guide 15 is fitted from the lower end in FIG. 1 to the outer periphery of the tip portion 14, and between the lower end in FIG. 1 of the guide 15 and the bottom surface of the axle tube 2. Is provided with a suspension spring 18. That is, the partition member 10 is carried by the collar 1a of the vehicle body side tube 1 and has a role as a spring receiver. Further, the distal end portion 14 is opposed to the cylinder body 3 with a slight gap, and a flow path is formed in the gap between the distal end portion 14 and the outer periphery of the cylinder body 3 and at the same time, the inner circumference of the guide 15 is formed. An annular orifice 17 is formed in a gap between the cylinder body 3 and the outer periphery. The opening area of the annular orifice 17 is set to be larger than the total opening area of the plurality of orifices 13.
[0029]
A bush 16 is fitted on the outer circumference of the guide 15 fitted on the outer circumference of the distal end portion 14. The bush 16 is slidably contacted with the inner circumference of the axle-side tube 2 so that the The slidability between the tube 1 and the axle-side tube 2 is ensured. In this partition member 10, a guide 15 and a bush 16 are provided and slidably contact the axle-side tube 2 to make the bush 16 a sliding contact portion. For example, from the viewpoint of protection of the axle-side tube 2 and ensuring slidability, the tip portion 14 of the 10 has a three-layer structure, the outer periphery is a fluoroethylene resin layer, and the intermediate layer is a porous alloy of copper and tin. The inner circumference may be made of steel or bronze, and the outer circumference of the tip portion 14 may be slid on the inner circumference of the axle-side tube 2. In this case, the lower end of the distal end portion 14 may be bent or bent inwardly to form an annular orifice in the gap between the lower end and the outer periphery of the cylinder body 3. The partition member 10 functions as a spring receiver for the suspension spring 18, but has sufficient strength to withstand the compressive force applied from the suspension spring 18 and the collar 1a, and has a sliding property. The guide 15 and the bush 16 may be omitted in this case as well.
[0030]
Further, in the present embodiment, the partition member 10 is fixed at a predetermined position by the collar 1a and the suspension spring 18, but the base end 11 of the partition member 10 is eliminated and the inner periphery of the intermediate portion 12 is formed as a cylinder body. 3 with a snap ring, or the upper and lower lengths of the base end 11 are made shorter than in the present embodiment, and the shortened upper end of the base end 11 is locked with the cylinder body 3 by a snap ring. Is also good. In this case, the initial load of the suspension spring 18 may be adjusted by providing a collar for moving the suspension spring 18 in the vertical direction in FIG. In the present embodiment, since the base end portion 11 is merely fitted to the outer periphery of the cylinder body 3, especially when the damper D is set to a single cylinder type, the cylinder body 3 Since the strength is not unnecessarily reduced, it is advantageous in terms of the durability of the front fork as compared with the case where the partition member 10 is locked to the cylinder body 3 using a snap ring or the like as described above. Since there is no fear that the cylinder body 3 will be deformed when the partition member 10 is overloaded, the performance of the front fork is prevented from deteriorating. The partition member has the above-described base end portion, and a thick-walled cylindrical body that slides on the outer periphery of the cylinder body 3 and the inner periphery of the axle-side tube 2 at the lower end of the base end portion. The passages may be formed with the orifices 13 and 17, but since the partitioning member 10 is configured as described above, it becomes lighter than a thick cylindrical body, and is advantageous in terms of material cost. is there.
[0031]
Further, in the front fork configured as described above, the gap between the outer periphery of the damper D and the inner periphery of the body-side tube 1 and the axle-side tube 2 has a working liquid O serving as a liquid surface SL. Is filled. Regarding the filling amount of the working liquid O, at least when the axle-side tube 2 enters the vehicle-body-side tube 1 and reaches the most contracted state, the volume of the cylinder body 3 entering the working liquid O is reduced. The liquid level SL rises upward in FIG. 1 by the amount obtained by dividing the volume of the rod body 5 entering the cylinder body 3 and the relative movement between the cylinder body 3 and the axle-side tube 2. The upper portion of the partition member 10 in FIG. 1 is filled as needed, that is, the partition member 10 is filled in such an amount as to reach the liquid level SU indicated by the broken line.
[0032]
In the space above the liquid level SL, that is, between the outer circumference of the damper D and the inner circumferences of the vehicle body side tube 1 and the axle side tube 2 and above the liquid level SL, gas (not shown) is used. ) Is sealed, and this gas (not shown) is compressed as the above-mentioned liquid level SL rises, so that it can function as a gas spring. This gas may be pressurized and sealed when the effect as a gas spring is particularly expected.
[0033]
Now, with the operation of the front fork configured as described above, when the front fork contracts, that is, when the axle-side tube 2 enters the vehicle-body-side tube 1, the vehicle-body-side tube of the axle-side tube 2 1 and the rod body 5 enters the cylinder body 3 of the damper D, so that the liquid surface SL of the working liquid O is pushed upward in FIG. Further, when the front fork contracts, the liquid level SL of the working liquid O eventually rises to a position where the guide 15 of the partition member 10 and the annular orifice 17 formed on the outer periphery of the cylinder body 3 are located. At this time, the working liquid O passes through the annular orifice 17 because the bush 16 of the partition member 10 is in sliding contact with the inner periphery of the axle-side tube 2. A pressure loss occurs before and after the annular orifice 17, and a damping force is generated to prevent the front fork from contracting. Further, when the front fork contracts, the working liquid O passes through a flow path formed between the cylinder body 3 and the tip end portion 14 of the partition member 10, and the liquid surface SL is provided at an intermediate portion of the partition member 10. Orifice 13. Then, the working liquid O flows into the outer peripheral side of the intermediate portion 12 through the orifice 13 as the front fork continues to contract. Then, the front fork generates a damping force due to the pressure loss generated when the working liquid O passes through the orifice 13, but the total opening area of each orifice 13 is equal to the opening area of the annular orifice 17. Since it is set to be smaller, the damping force when the working liquid O passes through the orifice 13 is higher than the damping force when passing through the annular orifice 17. That is, in this front fork, as the shrinkage proceeds, the generated damping force increases stepwise, that is, the front fork is generated stepwise depending on the relative position between the vehicle body side tube 1 and the axle side tube 2. The damping force can be changed.
[0034]
Therefore, since the damping force generated gradually increases with the contraction of the front fork, the problem that suddenly generated damping force like a conventional front fork makes the ride of a motorcycle rugged is solved. It is possible to improve the riding comfort of the motorcycle.
[0035]
In particular, if the orifice diameter is set small, a high damping force can be generated, and the bottom of the vehicle body side tube and the axle side tube can be prevented.
[0036]
Further, since the partition member also serves as the spring receiver, the number of components is reduced and the manufacturing cost is reduced as compared to providing a separate partition member separately from the spring receiver.
[0037]
Further, in the present invention, a plurality of orifices are required, and a number of orifices having different diameters must be formed in the partition member.One of the orifices is an annular orifice. As a result, when the partition member performs a function as a spring receiver, the harmful effect due to the deformation of the partition member, that is, the generated damping force does not reach a predetermined value, the expansion and contraction of the front fork is inhibited, and the deformation of the suspension spring is caused by the deformation. Can interfere with the vehicle body side tube, the axle side tube, or the cylinder body to damage these members, and can prevent generation of abnormal noise due to the interference. Therefore, performance deterioration and deterioration of the front fork can be prevented.
[0038]
Further, by merely providing a partition member having an orifice having a different opening area from the flow path, the generated damping force can be easily changed stepwise, so that the body-side tube, the axle-side tube or the cylinder body can be used. There is no need to have a complicated structure such as forming a flow path and an orifice, and there is an advantage that the present invention can be applied to an existing front fork.
[0039]
In addition, since the partition member is configured as described above, the partition member is lighter in weight than a thick cylindrical body that fills the gap between the cylinder body and the axle-side tube, and is advantageous in terms of material cost. is there.
[0040]
Next, a description will be given of a front fork according to a second embodiment of the present invention. As shown in FIG. 2, the front fork according to the second embodiment includes a body-side tube 21, an axle-side tube 22, a damper D, an inner periphery of the body-side tube 21 and the axle-side tube 22, and the damper D. And a partition member 30 and a suspension spring 18.
[0041]
Hereinafter, a description will be given in detail focusing on points different from the first embodiment. The vehicle body side tube 21 is formed in a bottomed cylindrical shape similarly to the first embodiment, and its bottom portion, that is, in FIG. It has a collar 21a hanging down from the inside of the upper end, and the cylinder body 3 constituting the damper D is connected to the inner peripheral side of the collar 21a. Although the vehicle body side tube 21 has a cylindrical shape with a bottom as shown in the figure, it is composed of a cylindrical body and a sealing member for sealing an end portion, and the cylinder body 3 is connected to this sealing member. The collar 21a may also be configured so as to be able to be moved up and down in FIG. 2 with respect to the cylinder body 3 and the above-described cylinder body as separate members. As described in the first embodiment, it is convenient to adjust the initial load of the suspension spring 18 to be described later by making it movable.
[0042]
On the other hand, similarly to the first embodiment, the axle-side tube 22 is formed in a cylindrical shape with a bottom, and the rod, which constitutes the damper D, is connected to the bottom, that is, the inside of the lower end in FIG. . Although the axle-side tube 22 has a bottomed cylindrical shape as shown in the drawing, the axle-side tube 22 is composed of a cylindrical body and a sealing member for sealing an end portion, and the rod member 5 is connected to the sealing member. Of course, it may be possible. Although not shown, a bracket (not shown) for connecting the axle of the motorcycle is appropriately provided near the lower end of the axle-side tube 2.
[0043]
The vehicle body side tube 21 is slidably inserted into the axle side tube 22. That is, in the first embodiment, the body-side tube 1 is set as a so-called outer tube, and the axle-side tube 2 is set as a so-called inner tube. Reference numeral 21 is different from the first embodiment in that a so-called inner tube is set, and the axle-side tube 2 is set as a so-called outer tube.
[0044]
Although not shown, a bearing member (not shown) for ensuring the slidability between the vehicle body side tube 21 and the axle side tube 22 and the body side tube 21 and the axle side tube 22 are provided. As in the first embodiment, a seal for appropriately sealing the inside is provided.
[0045]
The dampers D provided inside the vehicle body side tube 21 and the axle side tube 22 are the same as those in the above-described embodiment.
[0046]
Therefore, in the above description, the cylinder body 3 that constitutes the damper D is connected to the body-side tube 21 and the rod body 5 that is inserted into and retractable from the cylinder body 3 is connected to the axle-side tube 22. When the axle-side tube 22 moves relative to the body-side tube 21, the damper D can generate a damping force so as to suppress this relative movement. It is used to suppress vibration input from the road surface during traveling.
[0047]
Next, the partitioning member 30 will be described. The shape of the partitioning member 30 is substantially the same as that of the first embodiment, and the partitioning member 30 has a cylindrical base end 31 and a hollow base extending from the base end 31. It is composed of a conical intermediate portion 32 and a cylindrical distal end portion 34 extending from the intermediate portion 32 and having a larger diameter than the base end portion 31. The base end 31 is fitted into the cylinder body 3, and the upper end of the base end 31 in FIG. 2 abuts on the collar 21 a of the vehicle body side tube 21, and the middle part 32 has inner and outer sides thereof. A plurality of orifices 33 are formed to communicate with each other, and the outer periphery in FIG. 2 of the distal end portion 34 is in sliding contact with the inner periphery of the vehicle body side tube 21. Therefore, in this case, the outer periphery of the distal end portion 34 is a sliding contact portion. Further, a suspension spring 18 is interposed between the lower end of the distal end portion 34 in FIG. 2 and the bottom surface of the axle-side tube 22. That is, the partition member 30 is carried by the collar 21a of the vehicle body side tube 21 and has a role as a spring receiver. Further, the distal end portion 34 is opposed to the cylinder body 3 with a slight gap, and a flow path is formed in the gap between the distal end portion 34 and the outer periphery of the cylinder body 3 to form the annular orifice 37. The opening area of the annular orifice 37 is set to be larger than the total opening area of the plurality of orifices 33.
[0048]
In addition, according to the above description, the outer periphery of the distal end portion 34 is in sliding contact with the inner periphery of the vehicle body side tube 22, but may be connected instead of being in sliding contact. In this case, the outer periphery of the distal end portion 34 becomes the connecting portion. However, since the initial load of the suspension spring 18 cannot be adjusted by the collar 21a of the vehicle body side tube 21, the initial load of the suspension spring 18 is adjusted by the vehicle body side tube. A collar for moving the suspension spring 18 in the vertical direction in FIG.
[0049]
Also, in the present embodiment, the proximal end 31 of the partition member 30 is discarded and the inner periphery of the intermediate portion 32 is locked to the cylinder body 3 by a snap ring. May be shortened, and the upper end of the shortened base end portion 31 may be locked to the cylinder body 3 by a snap ring.
[0050]
Also in the front fork thus configured, similarly to the above-described first embodiment, the gap between the outer circumference of the damper D and the inner circumferences of the body-side tube 21 and the axle-side tube 22 is formed. The gap is filled with the working liquid O that becomes the liquid surface SL. Regarding the filling amount of the working liquid O, at least when the axle-side tube 22 enters the vehicle-body-side tube 21 to be in the most contracted state, the volume of the cylinder body 3 entering the working liquid O is reduced. The liquid surface SL is pushed upward in FIG. 2 by the amount obtained by dividing the volume of the rod body 5 entering the cylinder body 3 and the relative movement between the cylinder body 3 and the axle-side tube 22. At this time, the liquid surface SL is partitioned. The part 30 is filled with an amount above the middle part 32 of the member 30 in FIG.
[0051]
In the space above the liquid level SL, that is, between the outer circumference of the damper D and the inner circumferences of the vehicle body side tube 21 and the axle side tube 22 and above the liquid level SL, gas (not shown) is used. ) Is sealed, and this gas (not shown) is compressed as the above-mentioned liquid level SL rises, so that it can function as a gas spring. This gas may be pressurized and sealed when the effect as a gas spring is particularly expected.
[0052]
Now, with the operation of the front fork configured as described above, if the front fork contracts, that is, if the axle-side tube 22 enters the body-side tube 21, the axle-side tube of the body-side tube 21 Since the rod body 5 penetrates into the cylinder body 3 of the damper D and the rod body 5, the liquid surface SL of the working liquid O is pushed upward in FIG. 2. Further, when the front fork contracts, the liquid level SL of the working liquid O eventually rises to a position where the annular orifice 37 formed by the inner periphery of the lower end of the distal end portion 34 of the partition member 30 and the outer periphery of the cylinder body 3 is located. At this time, since the outer periphery of the distal end portion 34 of the partition member 30 is in sliding contact with the inner periphery of the vehicle body side tube 21, the working liquid O passes through the annular orifice 37. A pressure loss occurs before and after the annular orifice 37, and a damping force is generated so as to prevent the front fork from contracting. Further, when the front fork contracts, the working liquid O passes through a flow path formed between the cylinder body 3 and the distal end portion 34 of the partition member 30, and the liquid surface SL is provided at an intermediate portion of the partition member 30. Orifice 33. Then, the working liquid O flows into the outer peripheral side of the intermediate portion 32 through the orifice 33 as the front fork continues to contract. Then, the front fork generates a damping force due to a pressure loss generated when the working liquid O passes through the orifice 33. The total opening area of each orifice 33 is equal to the opening area of the annular orifice 37. Since it is set larger, the damping force when the working liquid O passes through the orifice 33 is higher than the damping force when the working liquid O passes through the annular orifice 37. In other words, in this front fork, the damping force generated gradually increases as the contraction proceeds, that is, the front fork gradually increases depending on the relative position between the vehicle body side tube 21 and the axle side tube 22. The damping force can be changed.
[0053]
That is, the same operation as the first embodiment can be obtained. Therefore, the effect is also the same as that of the first embodiment, and the generated damping force is gradually increased with the contraction of the front fork. It is possible to solve the problem that the ride comfort is rough, and it is possible to improve the ride comfort of the motorcycle.
[0054]
In particular, if the orifice diameter is set to be small, a high damping force can be generated, and the bottom of the cylinder body and the axle-side tube can be prevented.
[0055]
Further, as is apparent from the above description, the vehicle body side tube may be set as an inner tube or an outer tube.
[0056]
Further, since the partition member also serves as the spring receiver, the number of components is reduced and the manufacturing cost is reduced as compared to providing a separate partition member separately from the spring receiver.
[0057]
Further, in the present invention, a plurality of orifices are required, and a number of orifices having different diameters must be formed in the partition member.One of the orifices is an annular orifice. As a result, when the partition member performs a function as a spring receiver, the harmful effect due to the deformation of the partition member, that is, the generated damping force does not reach a predetermined value, the expansion and contraction of the front fork is inhibited, and the deformation of the suspension spring Can interfere with the vehicle body side tube, the axle side tube, or the cylinder body to damage these members, and can prevent generation of abnormal noise due to the interference. Therefore, performance deterioration and deterioration of the front fork can be prevented.
[0058]
Further, by merely providing a partition member having an orifice having a different opening area from the flow path, the generated damping force can be easily changed stepwise, so that the body-side tube, the axle-side tube or the cylinder body can be used. There is no need to have a complicated structure such as forming a flow path and an orifice, and there is an advantage that the present invention can be applied to an existing front fork.
[0059]
In addition, since the partition member is configured as described above, the partition member is lighter in weight than a thick cylindrical body that fills the gap between the cylinder body and the axle-side tube, and is advantageous in terms of material cost. is there.
[0060]
Further, a modified example of the partition member will be described. As shown in FIG. 3, the partition member 50 in this modified example includes a cylindrical base end portion 51, a hollow frustoconical first intermediate portion 52 extending from the base end portion 51, A second intermediate portion 54 extending from the intermediate portion 52 and having a cylindrical shape larger in diameter than the base end portion 51; a hollow frusto-conical third intermediate portion 56 extending from the second intermediate portion 54; A fourth intermediate portion 58 that extends from the third intermediate portion 56 and fits into the cylinder body 3; a hollow frustoconical fifth intermediate portion 59 that extends from the fourth intermediate portion 58; 5, a distal end portion 61 extending from the intermediate portion 59 and having a larger diameter than the base end portion 51, a guide 62 fitted on the outer periphery of the distal end portion 61, a bush 63 fitted on the outer periphery of the guide 62, And a bush 55 fitted around the outer periphery of the intermediate portion 54. The base end 51 is fitted into the cylinder body 3 and the upper end of the base end 51 in FIG. 3 is not shown, but is attached to the collar 1a of the vehicle body side tube 1 in the same manner as in the first embodiment. Have been abutted. Further, a plurality of orifices 53, 57, 60 communicating the inside and the outside thereof are formed in the first intermediate portion 52, the third intermediate portion 56, and the fifth intermediate portion 59, respectively. A guide 62 is fitted from the lower end in FIG. 3 to the outer periphery, and a suspension spring is provided between the lower end in FIG. 3 of the guide 62 and the bottom surface of the axle-side tube 2 as shown in FIG. 18 are interposed. That is, the partition member 50 is also carried by the collar 1a of the vehicle body side tube 1 and has a role as a spring receiver. Further, the tip portion 61 is opposed to the cylinder body 3 with a slight gap, and a gap between the tip portion 61 and the outer circumference of the cylinder body 3, the inner circumference of the cylinder body 3 and each of the intermediate portions 52, 54,. A flow path is formed by the space formed by the space 56 and the space formed by the intermediate portions 56, 58, 59 and the inner circumference of the axle-side tube 2, and at the same time, the inner circumference of the guide 62 and the outer circumference of the cylinder body 3 An annular orifice 64 is formed in the gap between the two. In this case, the total opening area of the plurality of orifices 53, the total opening area of the plurality of orifices 57, the total opening area of the plurality of orifices 60, and the opening area of the annular orifice 64 are the total opening area of the plurality of orifices 53, The total opening area of the plurality of orifices 57, the total opening area of the plurality of orifices 60, and the opening area of the annular orifice 64 are set to be larger in this order.
[0061]
Bushes 63 and 55 are fitted on the outer circumference of the guide 62 and the outer circumference of the second intermediate portion 54, which are fitted on the outer circumference of the distal end portion 61, respectively. Sliding contact with the inner circumference. Note that the material of the partition member 50 is also the same as that of the first embodiment, and a detailed description thereof will be omitted.
[0062]
Therefore, in the front fork provided with the partition member 50, as in the first embodiment, when the front fork is contracted, the working liquid O is supplied to each of the orifices 53 and 57 as the liquid level of the working liquid O rises. , 60 and the annular orifice 64, but the generated damping force can be changed to another stage as compared with the first embodiment, so that the operation and effect of the first embodiment can be obtained. At the same time, it is possible to further improve the riding comfort of the motorcycle.
[0063]
Finally, another modification of the partition member will be described. As shown in FIG. 4, the partition member 70 in the other modified example includes a cylindrical main body 71 and a plurality of disks 72, 73, and 74 which are provided near the lower end of the main body 71 in FIG. 4. The main body 71 is fitted to the cylinder body 3, and the outer diameters of the plurality of disks 72, 73, 74 are set so as to increase in the order of the disk 74, the disk 73, and the disk 72. Annular orifices 75, 76, 77 are formed in gaps between the outer periphery of each of the disks 72, 73, 74 and the inner periphery of the axle tube 2. That is, the opening area of the annular orifice 75, the opening area of the annular orifice 76, and the opening area of the annular orifice 77 are increased in the order of the opening area of the annular orifice 75, the opening area of the annular orifice 76, and the opening area of the annular orifice 77. Is set.
[0064]
Although not shown, the upper end of the main body 71 in FIG. 4 is in contact with the collar 1a of the vehicle body side tube 1 similarly to the first embodiment, and the lower end in FIG. A suspension spring 18 is interposed between the bottom and the bottom. That is, even in the partition member 70, it is carried by the collar 1a of the vehicle body side tube 1 and has a role as a spring receiver. In this case, a flow path is formed by a space formed by the main body 71, the disks 72, 73, 74 and the inner periphery of the axle-side tube 2.
[0065]
Therefore, even in the front fork provided with the partition member 70, as in the first embodiment, when the front fork is contracted, the working liquid O is supplied with the annular orifices 77, Although it passes through 76 and 75, the generated damping force can be changed to another stage as compared with the first embodiment, so that the effects and advantages of the first embodiment can be obtained, It is possible to further improve the riding comfort of the motorcycle.
[0066]
Further, since each of the disks 72, 73, 74 does not need to be brought into sliding contact with the inner periphery of the axle-side tube 2, it is not necessary to manufacture the partition member 70 with a material having particularly excellent slidability. Since there is no need to provide a bush, the number of parts can be reduced, and the manufacturing cost can be reduced.
[0067]
By the way, in the above description, a plurality of disks 72, 73, 74 are provided on the main body 71 of the partition member 70 to form a plurality of orifices having different opening areas. A cylindrical body having a thickness substantially equal to the width of the gap between the cylinder and the cylinder body, and a gap formed between the outer periphery thereof and the axle-side tube or the body-side tube as a flow path, the flow path being a partition member The outer periphery of the partition member may be sloped or curved so that it becomes narrower upward. In this case, as the working liquid rises, the flow path narrows steplessly, so that the generated damping force can be steplessly increased.
[0068]
By providing a projection at the lower end in FIG. 4 of the partition member 70 into which the inner periphery of the suspension spring 18 is fitted, centering of the suspension spring 18 can be facilitated, and at the same time, the suspension spring 18 and the cylinder body 3 It is also possible to prevent occurrence of abnormal noise and deterioration of the cylinder body 3 by preventing interference with the cylinder body 3.
[0069]
Further, in the above description of the partition member 50 and the partition member 70 shown in FIGS. 3 and 4, the vehicle body side tube 1 has been described as the outer tube, but in these partition members 50 and 70, the vehicle body side tube 1 also has the inner tube. Needless to say, a tube may be used.
[0070]
This concludes the description of the embodiments of the present invention, but it goes without saying that the scope of the present invention is not limited to the details shown or described.
[0071]
【The invention's effect】
According to the invention of each claim, as the contraction of the front fork progresses, the generated damping force increases stepwise, that is, the damping occurs stepwise depending on the relative position between the vehicle body side tube and the axle side tube. The force can be changed.
[0072]
Therefore, since the damping force generated gradually increases with the contraction of the front fork, the problem that suddenly generated damping force like a conventional front fork makes the ride of a motorcycle rugged is solved. It is possible to improve the riding comfort of the motorcycle.
[0073]
In particular, if the orifice diameter is set small, a high damping force can be generated, and the interference between the cylinder body and the axle side tube, the body side tube and the axle side tube, or the cylinder body and the rod body, so-called It is also possible to prevent bottoming out, and it is advantageous in terms of ride comfort as compared to bottoming out prevention by an oil lock.
[0074]
According to the second and third aspects of the invention, the generated damping force can be easily changed stepwise simply by providing a partition member having an orifice having a different opening area from the flow path. There is no need to have a complicated configuration such as forming a flow path and an orifice in the side tube, axle side tube or cylinder body, and there is an advantage that it can be applied to an existing front fork. In addition, since the partition member is configured as described above, the weight is reduced as compared with the case where the partition member is a thick cylinder, and the material cost is also advantageous.
[0075]
Furthermore, according to the fourth and fifth aspects of the present invention, one of the plurality of orifices required for the present invention can be an annular orifice, so that a decrease in the strength of the partition member can be compensated for, and thereby, the deformation of the partition member can be reduced. Evil, that is, when the generated damping force does not reach a predetermined value, hinders the expansion and contraction of the front fork, and furthermore, when the partitioning member also functions as a spring receiver, this deformation causes the suspension spring to turn the vehicle body side tube, axle side tube or It is possible to prevent damage to these members due to interference with the cylinder body and generation of abnormal noise due to the interference. Therefore, deterioration of the front fork can be prevented.
[0076]
According to the invention of claim 6, since the partition member also serves as the spring receiver, the number of components is reduced and the manufacturing cost is reduced as compared with the case where a separate partition member is provided.
[Brief description of the drawings]
FIG. 1 is a schematic longitudinal sectional view of a front fork according to a first embodiment of the present invention.
FIG. 2 is a schematic longitudinal sectional view of a front fork according to a second embodiment of the present invention.
FIG. 3 is a longitudinal sectional view of a modification of the partition member of the front fork of the present invention.
FIG. 4 is a longitudinal sectional view of another modification of the partition member of the front fork of the present invention.
[Explanation of symbols]
1,21 Body side tube
2,22 axle side tube
3 cylinder body
5 Rod body
10,30,50,70 Partitioning member
11, 31, 51, 71 Base end
12, 32 Middle part
13,33,53,57,60 Orifice
14, 34, 61 Tip
15,62 Guide
16,55,63 bush
17, 37, 64, 75, 76, 77 annular orifice
18 suspension spring
52 1st intermediate part
54 2nd middle part
56 Third intermediate part
58 4th intermediate part
59 Fifth intermediate part
72, 73, 74 disk
D damper
O Working liquid
SL liquid level

Claims (6)

The axle-side tube is slidably inserted into the body-side tube, a damper is provided inside the body-side tube and the axle-side tube, and the cylinder body that constitutes the damper is connected to the body-side tube. In a front fork in which a working liquid is filled in a gap between an inner circumference of a body-side tube and an axle-side tube and an outer circumference of the damper, the rod body being connected to the cylinder body so as to be retractable and retractable. A flow path is formed between the outer periphery of the body and the inner circumference of the body-side tube or the axle-side tube, at least when the front fork is in its maximum contraction, through which the working liquid passes as the liquid level of the working liquid rises. Characterized in that at least two orifices having different opening areas are provided so that the opening area decreases in order from the axle side. . The vehicle body side tube is set as an outer tube, the axle side tube is set as an inner tube, a partition member is provided between the cylinder body and the axle side tube, and a flow path and the orifice are provided in the partition member. The front fork according to claim 1, wherein The vehicle body side tube is set as an inner tube, the axle side tube is set as an outer tube, a partition member is provided between the cylinder body and the vehicle body tube, and a flow path and the orifice are provided in this partition member. The front fork according to claim 1, wherein A partitioning member is supported by the body-side tube and extends from the cylindrical base end fitted into the outer periphery of the cylinder body, a hollow frustoconical intermediate part extending from the base end, and the intermediate part. A flow path and a first orifice formed by a gap between the inner periphery of the distal end portion and the intermediate portion of the partition member and the outer periphery of the cylinder body; 3. The front according to claim 2, wherein a second orifice is provided for communicating the flow path with the outside of the intermediate portion, and a sliding contact portion for slidingly contacting the inner periphery of the axle-side tube is provided on the outer periphery of the distal end portion. fork. The partitioning member is supported by the body-side tube and fitted to the outer periphery of the cylinder body, a cylindrical base end portion, a hollow frustoconical intermediate portion extending from the base end portion, and a hollow conical intermediate portion extending from the intermediate portion. A flow path and a first orifice formed by a gap between the inner periphery of the distal end portion and the intermediate portion of the partition member and the outer periphery of the cylinder body, and a flow path and a first orifice. A second orifice for communicating the flow path with the outside of the intermediate portion is provided at an intermediate portion, and a sliding portion or a coupling portion for slidingly contacting the inner periphery of the vehicle body side tube is provided at a distal end portion. Item 4. A front fork according to Item 3. The front fork according to any one of claims 2 to 5, wherein the partition member also serves as a spring receiver that supports a suspension spring interposed between the vehicle body side tube and the axle side tube.

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