JPH0479876B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a motorcycle equipped with a unit swing type engine, and particularly to a suspension system for the engine unit.

This type of unit swing type engine has an integrated structure with an engine and a transmission case housing an automatic transmission, and a rear wheel driven by the automatic transmission is installed at the rear of the transmission case to form a unit. The front end of this unit is swingably supported by the vehicle body, and the rear part of the transmission case is suspended by a shock absorber installed between the unit and the vehicle body. In such an engine, when an impact is applied to the rear wheels, the entire unit swings around the front end pivot, so a link member is used to connect the front end of the unit and the vehicle body to absorb and alleviate the impact applied to the front end pivot. It is known that the vehicle body and the link member are connected through a link member, and a rubber vibration isolator is interposed between the vehicle body and the link member.

In this case, it is better to set the spring constant of the vibration isolator to a low value in terms of vibration isolation performance, but since the initial load due to the weight of the unit is applied to this vibration isolator through the link member, the life of the vibration isolator may be affected. In consideration of this, the spring constant has to be set relatively high, and as a result, vibration-proofing performance is sacrificed, leading to problems such as poor riding comfort. Furthermore, since the link member bears the weight of the unit, it is necessary to increase the rigidity of the link member, which results in a disadvantage that the link member becomes larger and increases in weight.

The present invention was developed based on these circumstances, and it is possible to reduce the load burden on the vibration isolating material due to the weight of the unit and the displacement of the link member, and to improve the vibration isolating performance without reducing the life of the vibration isolating material. An object of the present invention is to provide a suspension system for a unit swing type engine in a motorcycle, which can increase the engine speed and reduce the size and weight of link members.

That is, in order to achieve the above object, the present invention
A transmission case extending rearward is integrally provided at one side end of the engine, and a rear wheel driven by a power transmission means housed in the transmission case is provided at the rear end of the transmission case to form a unit. The front end of this engine unit is swingably supported via a link member extending approximately longitudinally with respect to the vehicle body, and these shafts are attached to the entire outer circumference of a shaft member that connects this link member and the vehicle body. A cylindrical vibration isolator that is sandwiched between the member and the link member and torsionally deforms in the direction around the axis of the shaft member is installed, and a cylindrical vibration isolator is installed between the rear of the transmission case and the vehicle body in the vertical direction. In a motorcycle equipped with a shock absorber extending from the front, the connection part between the transmission case and the shock absorber is located behind the axle of the rear wheel, and the upper end of the shock absorber, which is the connection part with the vehicle body, is located behind the transmission case and the shock absorber. It is characterized by being tilted forward to an angle that is located forward of the lower end, which is the connection part with the case.

An embodiment of the present invention will be described below based on the drawings in which the present invention is applied to a scooter type motorcycle.

1 in the figure is a frame as a vehicle body, and this frame 1 is a front fork 3 that pivotally supports a front wheel 2.
The bottom part 5 is bent greatly downward between the bottom part 5 and the seat 4, and a footrest plate 6 is installed on the bottom part 5. The front of the footrest 6 is covered with a leg shield 7 that protects the legs from wind, and the lower part of the seat 4 is covered with a cover 8.

The rear end portion of the bottom portion 5 of the frame 1 is bifurcated and raised upwards, and engine brackets 10, 10 attached to the lower portions of these rising portions 9, 9 have an engine mounted thereon. The front end of the unit 11 is swingably connected. The engine unit 11 is composed of an engine 12 and a transmission case 14 extending rearward from one side end of a crankcase 13 of the engine 12 as an integral rigid body.The transmission case 14 also serves as a swing arm and Case 1
A power transmission means such as a V-belt type endless transmission is housed inside 4. An axle 16 for a rear wheel 15 is supported at the rear end of the transmission case 14, and the rear wheel 15 is rotationally driven by the power transmission means. A structure for connecting such an engine unit 11 to the frame 1 is shown in FIGS. 2 and 3. That is, the cross member 1 that connects the rising parts 9, 9 of the frame 1 with each other
A cylindrical body 18, 18 is interposed between the engine bracket 7 and the engine bracket 10, 10. cylindrical body 18,
Vibration isolators 20, 20 are installed inside the cylinder 18, and the cylindrical bodies 18, 18 are connected between the cross member 17 and the engine brackets 10, 10 by bolts 19, 19 as shaft members. is fixed. The vibration isolators 20, 20 of this embodiment are made by baking and fixing metal sleeves 22, 23 to the inner and outer peripheral surfaces of a hollow cylindrical rubber damper 21, and the inner metal sleeve 22 is attached to the outer peripheral surface of the bolt 19, and An outer metal sleeve 23 is fitted and fixed to the inner peripheral surfaces of the cylindrical bodies 18, 18, respectively. Plate-shaped link members 24, 24 are welded to the rear surfaces of the cylindrical bodies 18, 18, and between the rear ends of these link members 24, 24, a link member protruding from the front end of the engine unit 11 is provided. Left and right support protrusions 25, 25 are interposed. And the link members 24, 24 and the support protrusion 2
5 and 25 are tightened and fixed by bolts 26 installed between the supporting protrusions 25 and 25. Other vibration isolators 27, 27 having the same structure as the above-mentioned vibration isolators 20, 20 are provided at the portions of the support protrusions 25, 25 through which the bolts 26 are inserted. The vibration isolators 27, 27 have an outer metal sleeve 29 on the outer periphery of the rubber damper 28 which is fitted and fixed to the inner surface of the support protrusions 25, 25, and an inner metal sleeve 30.
is rotatably fitted to a collar 32 inserted into the outer peripheral surface of the bolt 26 via a bearing 31,
Therefore, the link members 24, 24 and the engine unit 11 are connected to be rotatable relative to each other using the bolt 26 as a fulcrum. And link member 24,
The connection point of 24 to the frame 1 side and the connection point to the engine unit 11 side are separated from each other in the longitudinal direction of the vehicle body, and therefore the link members 24, 24 extend substantially horizontally. Note that the link members 24, 24 are connected to each other by a cross pipe 33.

Further, the rear end portion of the transmission case 14 is suspended by one shock absorber 34 installed between the upper end portion of one of the rising portions 9 . The buffer 34 extends vertically and has a rising portion 9.
The upper end, which is the connection part with the transmission case 14, is tilted forward to such an angle that it is positioned further forward than the lower end, which is the connection part with the transmission case 14. The connecting portion 35 between the shock absorber 34 and the transmission case 14 is connected to the second
As shown in the figure, it is located a distance L behind the axle 16 of the rear wheel 15.

Therefore, as shown in FIG. 2, a repulsive force F acts on the rear end of the transmission case 14, causing the buffer 34 to extend diagonally downward, and this repulsive force F acts on the rear end of the transmission case 14. The force is divided into a component force F ₁ acting downward from the connecting portion 35 and a component force F ₂ acting approximately horizontally behind the connecting portion 35 .

According to such a configuration, when an impact is applied to the rear wheel 15 while the vehicle is running, the engine unit 11 swings up and down using the joints with the link members 24, 24 as fulcrums, transmits the impact to the shock absorber 34, and It is absorbed and relaxed by the buffer 34. By the way, if the above-mentioned impact is large, the engine unit 11 will not only be shaken, but the load accompanying this impact will cause the engine unit 11 to swing.
and link members 24, 24 and link member 24,
24 acts on the connecting portion between the link members 24, 24 and the frame 1. When a load acts on each connection part in this way, the rubber dampers 2 of the vibration isolators 20, 20 and 27, 27 interposed in this connection part
1 and 28 deform to absorb the load. Therefore, the impact applied to the front end, which is the pivot end of the engine unit 11, is attenuated in two stages, making it difficult for the impact to be transmitted to the vehicle body, improving ride comfort.

Therefore, at the connecting portion between the engine unit 11 and the link members 24, the engine unit 1
However, in the case of the above configuration, the connecting portion 35 between the engine unit 11 and the shock absorber 34 is connected to the axle 16 of the rear wheel 15.
Since the front end of the engine unit 11 is shifted further back than the front end of the engine unit 11, a moment is generated at the front end of the engine unit ₁₁ by a component force F1 of the repulsive force F of the shock absorber 34, and this front end is pushed up with the axle 16 as the center of rotation. A component force F ₃ will be added.

Therefore, when the rear wheel 15 is in contact with the ground, the reaction force _F3 is applied to the front end of the engine unit 11.
The reaction force F ₄ that the rear wheel 15 receives from the road surface acts synergistically, and the initial load W is offset or reduced by these reaction forces F ₃ and F ₄ .

Therefore, since the initial load W based on the weight of the engine unit 11 is not directly applied to the rubber dampers 21 and 28, the spring constants of the rubber dampers 21 and 28 are made lower, that is, the rubber dampers 21 and 28 are made softer. Anti-vibration performance can be improved.

Furthermore, by tilting the shock absorber 34 forward greatly, a horizontal component force F ₂ that tries to pull the engine unit 11 backward acts on the rear end of the engine unit 11. _F2 is caused by a large upward impact acting on the engine unit 11, and when the link members 24, 24 are rotated upward using the bolt 19 as a fulcrum, the link member 2
4 and 24 to return to their original positions.

That is, due to the presence of the component force _F2 , a tensile force always acts rearward on the connecting portion between the engine unit 11 and the link members 24, 24. Therefore, the rear end of the engine unit 11 is pushed up greatly toward the bound position, and the position of the bolt 26 connecting the engine unit 11 and the link members 24, 24 changes.
4 is displaced above the bolt 19 connecting the frame 1, a force acts on the link members 24, 24 to rotate them clockwise in FIG. I will do it.

Then, when the link members 24, 24 are rotated upward due to the large impact applied to the engine unit 11, the rubber damper 21 is torsionally deformed between the inner and outer metal sleeves 22, 23. If a force is applied to return the link members 24, 24 to their original positions as described above, the rubber damper 2
This means that the torsional deformation of No. 1 is suppressed.

Therefore, the load burden on the rubber damper 21 is reduced, and in addition to the fact that the initial load W of the engine unit 11 does not act on the rubber dampers 21 and 28, the life of the rubber dampers 21 and 28 is increased without sacrificing vibration damping performance. can be lengthened, improving ride comfort.

On the other hand, by tilting the buffer 34 forward,
A backward component force is applied to the rear end of the engine unit 11.
When F ₂ acts, vibrations in the longitudinal direction are likely to be transmitted to the connecting portions between the engine unit 11 and the link members 24, 24, and between the link members 24, 24 and the frame 1. However, since the rubber dampers 21 and 28 of each of the connecting portions are provided over the entire circumference of the bolts 19 and 26, the vibrations in the longitudinal direction can be absorbed and alleviated by the rubber dampers 21 and 28. Therefore, vibrations of the engine unit 11 are more difficult to be transmitted to the frame 1.

Further, since the initial load W from the engine unit 11 is applied to not only the rubber dampers 21 and 28 but also the link members 24 and 24 in a canceled or reduced state, the load burden on the link members 24 and 24 is reduced, and this link The members 24, 24 can be made smaller and lighter.

In addition, in the above-mentioned embodiment, a vibration isolating material was also interposed at the connecting part between the link member and the engine unit.
This vibration isolating material may be omitted and a structure may be adopted in which the link member and the engine unit are simply connected in a rotatable manner.

According to the present invention described in detail above, it is possible to apply a reaction force to the front end of the engine unit that pushes it up, and this reaction force causes the initial vibration of the engine unit based on its own weight applied to the vibration isolating material. The load can be offset or attenuated, and the spring constant of the vibration isolating material can be correspondingly lowered to improve vibration isolation performance.

In addition, by tilting the shock absorber significantly forward,
A horizontal component of force that tries to pull the engine unit backward acts on the rear end of the engine unit. When the link member is rotated upward using the member as a fulcrum, an opposite force acts to return the link member to its original position. As a result, torsional deformation of the vibration isolator is suppressed, reducing the load on the vibration isolator, and in combination with the fact that the initial load of the engine unit does not act on the vibration isolator, there is no need to sacrifice vibration isolation performance. Without this, the life of the vibration isolating material can be extended, and good riding comfort can be maintained over a long period of time.

In addition, since the vibration isolating material is provided around the entire circumference of the shaft member, vibrations in the longitudinal direction may be easily transmitted to the connecting portion between the link member and the vehicle body due to the forward tilting of the shock absorber. Regardless, this vibration can be effectively absorbed and alleviated by the vibration isolating material, making it difficult for vibrations from the engine unit to be transmitted to the vehicle body.

Furthermore, since the initial load from the engine unit is applied to not only the vibration isolating material but also the link member in a balanced or reduced state, the load burden on the link member is reduced, making it possible to make the link member smaller and lighter. There are some advantages.

[Brief explanation of drawings]

The drawings show one embodiment of the present invention; FIG. 1 is a side view of a motorcycle, FIG. 2 is a side view showing a suspended state of the engine unit, and FIG. 3 is a sectional view taken along the line - in FIG. be. DESCRIPTION OF SYMBOLS 1... Vehicle body (frame), 11... Engine unit, 12... Engine, 14... Transmission case, 15... Rear wheel, 16... Axle, 19... Shaft member (bolt), 20... Vibration isolation material, 24...link member, 34...buffer, 35...connecting portion.

Claims (1)

[Claims] 1. A transmission case extending rearward is integrally provided at one side end of the engine, and the rear end of the transmission case is driven by a power transmission means housed within the transmission case. A rear wheel is provided as a unit, and the front end of this engine unit is swingably supported via a link member extending approximately in the longitudinal direction with respect to the vehicle body, and a shaft member that connects the link member and the vehicle body. A cylindrical vibration isolator is installed around the entire outer circumference of the shaft member and the link member, and is torsionally deformed in the direction around the axis of the shaft member. Between,
In a motorcycle equipped with a shock absorber extending in the vertical direction, the connection part between the transmission case and the shock absorber is located behind the axle of the rear wheel, and the shock absorber is connected to the top end, which is the connection part with the vehicle body. 1. A unit swing type engine suspension system for a motorcycle, characterized in that the unit swing type engine suspension device for a motorcycle is tilted forward to an angle such that the lower end thereof is located forward of the lower end which is a connecting portion with a transmission case.