JPH02582B2 - - Google Patents

Description

[Detailed Description of the Invention] This invention is a rear mounting device for a power unit, especially a power unit that can be used in a transverse front engine/front drive vehicle to reduce both idling vibration and muffled noise during acceleration. This relates to a unit rear mounting device.

A power unit rear mounting device is a power unit that attaches to the rear of the vehicle body, where the engine and transmission (including the final reduction gear for front-engine, front-drive vehicles) are integrally combined. It is attached elastically to the

Conventional power unit rear mounting devices include those shown in Japanese Utility Model Application Laid-Open No. 55-163222 and those shown in FIGS. 1, 2, and 3, for example. Reference numeral 1 designates a power unit for a horizontally mounted front engine/front drive vehicle, which includes a front stopper 2 on the front F side of the vehicle body, a rear mounting device 3 on the rear R side of the vehicle body, a left mounting device 4 on the left L side of the vehicle body, and a vehicle body. It is elastically attached to a vehicle body (not shown) by a right mounting device 5 on the right r side. U indicates the upper part of the vehicle body, and D indicates the lower part of the vehicle body. As shown in FIG. 2, the rear mounting device 3 includes an outer cylinder 7 fitted into a cylinder 6a of a bracket 6 fixed to the vehicle body (not shown), and a bracket fixed to the power unit 1. The outer cylinder 7 and the inner cylinder 9 are connected by an insulator rubber 10 which is an elastic body. The insulator rubber 10 is located at a second position on the inner peripheral surface of the outer cylinder 7.
Projections 10a are integrally fixed to the left and right sides in the figure and project upward in FIG. 2.
A stopper 11 made of an elastic body is fixed to the lower side of the inner peripheral surface of the outer cylinder 7 in FIG. As shown in FIG. 2, in this mounting device 3, before the power unit 1 is assembled, the insulator rubber 10 is located in the upper part of the outer cylinder 7 in FIG. 2, and the inner cylinder 9 is in the upper part in FIG. power unit 1
When the static load W ₀ of the power unit 1 borne by the mounting device 3 is applied to the inner cylinder 9 from the top to the bottom in FIG. Inner cylinder 9
is located concentrically with the outer cylinder 7, and there are approximately equal gaps between the protrusion 10a of the insulator rubber 10 and the inner peripheral surface of the upper outer cylinder 7, and between the insulator rubber 10 and the lower stopper 11. _L1 ,
Cavities 12 and 13 having L ₂ are formed.

Figure 4 shows this conventional rear mounting device 3.
The characteristics are shown by broken lines, with the vertical axis representing the load P applied from the power unit 1 to the rear mounting device 3 in the downward direction of the vehicle body, and the horizontal axis representing the displacement X of the power unit 1 in the downward direction of the vehicle body. . The slope of the broken line graph represents the spring constant of the rear mounting device 3. As you can see from this graph,
In this rear mounting device 3, the range where the displacement X of the power unit 1 is from the downward direction L ₂ to the upward direction L ₁ (-L _{1 <}
2 does not collapse and the insulator rubber 10 undergoes shearing deformation, so it exhibits a small spring constant. If the displacement X of power unit 1 exceeds the above value (X<-
L ₁ , X>L ₂ ), the gap 12 or 13 collapses, and the insulator rubber 1
0 comes into contact with the outer cylinder 7 or the stopper 11 and is compressively deformed, so it exhibits a large spring constant. Therefore, this mounting device 3 absorbs relatively small amplitude vibrations of the power unit 1 within the range of a small spring constant and prevents the vibrations from being transmitted to the vehicle body, thereby ensuring sound and vibration damping properties. , power unit 1
For large displacements (X<-L ₁ , X>L ₂ ),
Support the power unit 1 with the part with a large spring constant.
This prevents excessive displacement.

However, in front-engine, front-drive vehicles, in addition to the weight of the power unit 1, the reaction force of the drive torque is applied to the rear mounting device. Therefore, the reaction force f of the drive torque acts on the rear mounting device 3 that attaches the rear portion of the power unit 1 to the vehicle body during forward acceleration in the same direction as the static load W ₀ of the power unit, that is, in the downward direction of the vehicle body. Therefore, the reaction force f of the driving torque pushes the inner cylinder 9 downward in FIG.
The cavity 13 in the lower part of the figure is crushed, and the insulator
The rubber 10 comes into contact with the stopper 11. As a result, when the insulator rubber 10 of the rear mounting device 3 comes into contact with the stopper 11 during forward acceleration, the power unit 1
Because of this support, rotational vibrations of the engine during acceleration are easily transmitted to the vehicle body, creating a problem in that the interior of the vehicle becomes crowded.

In order to solve this problem, the insulator rubber 10 of the rear mounting device 3 has been
The static load (W ₀ ) of the power unit borne by the rear mounting device 3 is increased by increasing the elastic constant of
is applied to the inner cylinder 9, the insulator rubber 10 is not deformed too much, and the gap _L2 of the lower cavity 13 of the rear mounting device 3 is made larger than the gap _L1 of the upper cavity 12. Even when the static load _W0 of the power unit 1 and the torque reaction force f during forward acceleration are applied, the lower cavity 13 is prevented from being crushed, and the insulator rubber 10 is maintained within the range of shear deformation during forward acceleration. It has been considered to absorb the vibrations of the power unit 1. However, when the elastic constant of the insulator rubber 10 of the rear mounting device 3 is increased in this manner, another problem arises in that idling vibrations are more easily transmitted to the vehicle body.
In addition, by enlarging the shape of the rear mounting device 3 and increasing the gap L ₂ of the lower cavity 13, even when the weight W ₀ borne by the power unit and the torque reaction force f during forward acceleration are applied, the cavity remains 13 from being crushed, but if the shape of the rear mounting device 3 is enlarged in this way, the rear mounting device 3 will occupy a large amount of space in the engine room, which is disadvantageous in terms of space utility. be. It is also possible to deviate the center of the inner cylinder as far upward as possible with respect to the outer cylinder so that the lower cavity 13 becomes larger than the upper cavity 12 during static loads, but the static load of the power unit However, there is a limit due to the spring constant of the elastic body, and it was not possible to make the lower cavity 13 too large.

The present invention was made by focusing on such conventional problems, and includes an outer cylinder attached to either the rear of the vehicle body or the rear of the power unit, an inner cylinder attached to the other, and an inner cylinder attached to the other. In the mounting device for a power unit, the mounting device has an elastic body connecting an outer cylinder and an inner cylinder, and a gap is formed in the vertical direction between the outer cylinder and the inner cylinder when the power unit is subjected to a static load. When a bracket having a notched opening is press-fitted into the outer cylinder, and the elastic body is compressed and deformed between the inner cylinder and the bracket when no load is applied, and the inner cylinder is press-fitted into the outer cylinder. , the elastic body has a contact portion that protrudes from the opening and comes into contact with the inner circumferential surface of the outer cylinder, and when the power unit is under static load, the contact portion separates from the inner circumferential surface of the outer cylinder and the outer cylinder One gap is formed between the inner circumferential surface and the abutting part, and the gap in the other gap located on the opposite side of the one gap with the inner cylinder in between is larger than the gap in the one gap. By providing a rear mounting device that has a low spring constant in the vertical direction of the vehicle body without increasing the shape and can maintain this low spring constant until a larger forward torque reaction force is applied. , aims to solve the above problems.

The present invention will be explained below based on the drawings.

5, 6 and 7 show a first embodiment of the invention.

First, the configuration will be explained. 21 is a rear mounting device that elastically attaches the rear part of the vehicle body of the power unit (not shown) to the vehicle body (not shown), and in FIG. be. The rear mounting device 21 is provided within a cylindrical outer cylinder 22 fixed to a vehicle body (not shown). The upper corner of the outer cylinder 22 in FIG. 5 (in the same direction as the upper direction of the vehicle body) is rounded. Inside the outer cylinder 22, there is an opening 23a having a similar shape to the outer cylinder 22 and having a cutout on the upper side of the vehicle body.
Bracket 2 of mounting device 21 having
3 are integrally press-fitted. As shown in detail in FIGS. 6 and 7, this bracket 23 has an inner cylinder 24 therein, which is attached to a power unit (not shown) with bolts. This inner cylinder 24 is connected to both left and right sides of the inner circumferential surface of the bracket 23 in FIG. 6 by insulator rubbers 25 as elastic bodies. A protrusion 25a is integrally provided at the upper center of the insulator rubber 25 and protrudes upward in FIG. 6 from the opening 23a before the bracket 23 is press-fitted into the outer cylinder 22. A lower stopper 26 made of an elastic body is provided at the lower part of the bracket 23 in FIG. 6, and a slit 23b is provided at the center of the lower part. This bracket 23 has a slit 2 in the outer cylinder 22.
3b and are integrally press-fitted, the protrusion 25a (abutting portion in the claims) of the insulator rubber 25
5, the inner circumferential surface of the outer cylinder 22 is pressed into contact with the upper part of the vehicle body in FIG. The upper portion of the inner circumferential surface of the outer cylinder 22 in FIG. 5 serves as an upper stopper 27 that restricts the movement of the insulator rubber 25 in the upward direction of the vehicle body. Further, the lower stopper 26 restricts the movement of the insulator rubber 25 in the downward direction of the vehicle body. When the power unit is attached to the inner cylinder of the mounting device 21 and the static load _W0 of the power unit is applied to the inner cylinder 24 in the downward direction of the vehicle body (downward in Fig. 5), the insulator rubber 25 is slightly deformed. , the protrusion 25a is spaced apart from the upper stopper 27 to form an upper gap 28 having a gap _L3 between the inner peripheral surface of the upper stopper 27 and the protrusion 25a.
On the other hand, a lower cavity 29 is formed between the insulator rubber 25 and the lower stopper 26, that is, at a position opposite to the upper cavity 28 with the inner cylinder ₂₄ interposed therebetween. Note that the gap in the vertical cavity of the rear mounting device 21 in this embodiment is pressed by the upper stopper 27 before the static load _W0 of the power unit is applied, so the gap L in the lower cavity 29 is ₄ is larger than the gap L ₂ of the lower cavity 13 of the conventional mounting device 3.

Next, the effect will be explained. FIG. 4 shows the characteristics of the mounting device 21 of this embodiment in comparison with the conventional mounting device 3, and the vertical axis shows the power unit to rear mounting device 2.
The load P applied to the inner cylinder 24 of No. 1 in the downward direction of the vehicle body is taken as a positive value, and the displacement of the inner cylinder in the downward direction of the vehicle body, that is, the displacement X of the power unit in the downward direction of the vehicle body is taken as positive. The solid line graph shows the graph of the rear mounting device 21 of this embodiment, and the slope represents its spring constant. In the rear mounting device 21 of this embodiment, the static load of the power unit is
The range _in which the _displacement
L ₄ ), the lower cavity 29 is not crushed and the insulator rubber 25 undergoes shear deformation, so the spring constant is small. This range (0<X<L ₄ ) is the range of the conventional rear mounting device 3 (0<X<L ₂ )
It is larger than . On the other hand, within the range where the absolute value of the displacement X of the power unit in the upward direction of the vehicle body is smaller than L ₃ (-L ₃ < The spring constant of the rear mounting device 21 is small. This range (-L ₃ <X < 0) is the range of the conventional rear mounting device 3 (-L ₃
<X<0). Displacement of the power unit exceeding the above range, i.e. (X
>L _{4 ,}
7 and compressively deforms, the spring constant increases. Rear mounting device 2 of this embodiment
1, the gap L ₄ of the lower cavity 29 is large, so
Accordingly, the spring constant can be kept small against a large load P applied in the downward direction of the vehicle body. Therefore, even if the reaction force f of the drive torque during forward acceleration is applied to the rear mounting device 21 in the downward direction of the vehicle body in addition to the static load _W0 of the power unit, the lower cavity 29 is not crushed and the acceleration is prevented. It is possible to absorb the vibration of the power unit caused by the shearing deformation with a small spring constant. For this reason, the vibration of the power unit during forward acceleration is transmitted to the vehicle body, creating a muffled sound (100 Hz).
(before and after) can be prevented from occurring. In addition, in response to engine idling vibration, the rear mounting device 21 has an upper cavity 28 and a lower cavity 29.
Since it can be absorbed within a range of small spring constants that do not collapse, transmission to the vehicle body can be prevented. In addition, in the case of a power unit with an automatic transmission, when idling in the D range, a torque reaction force is applied downward to the rear mounting device 21 of the vehicle body, but this rear mounting device 21 has a spring constant that does not collapse the lower cavity 29 Since the idling vibration of the power unit can be absorbed within a small range, it is possible to prevent it from being transmitted to the vehicle body. In addition, the drive reaction force during deceleration acts to displace the rear mounting device 21 upward, but vibration during deceleration, especially during braking, is not much of a problem, and the drive reaction force is large during deceleration other than during braking. However, it does not work on the power unit.

FIG. 8 shows a second embodiment of the invention. In this embodiment, the outer cylinder 2 attached to the power unit
2 has an inner cylindrical shape, and a bracket 23 press-fitted into the outer cylinder 22 also has an inner cylindrical shape, and the central part of the insulator rubber 25 has a protrusion 25a that protrudes downward from the vehicle body, and a protrusion 25a that protrudes upward from the vehicle body. Projecting part 2
5b is provided. Further, the inner cylinder 24 is attached to the vehicle body, and the lower part of the inner peripheral surface of the outer cylinder 22 directly serves as an upper stopper 27. The protruding portion 25a of the insulator rubber 25 on the lower side of the vehicle body presses against the upper stopper 27 when the load of the power unit is not applied to the outer cylinder 22. The static load of the power unit is applied to the outer cylinder 22 of the mounting device 21.
When W ₀ is applied, as shown in FIG. 8, an upper gap 28 having a gap L ₃ is formed between the upper stopper 27 and the protrusion 25a of the insulator rubber 25 below the vehicle body, and the lower stopper 26 and the protrusion 2 above the vehicle body of the insulator rubber 25
5b, a lower cavity 29 having a gap _L4 larger than the gap _L3 is formed. Since the other configurations and operations are the same as those in the first embodiment, the same parts are given the same numbers and the explanation will be omitted.

FIG. 9 shows a third embodiment of the invention. In this embodiment, the insulator rubber 25 is disposed diagonally within the bracket 23. Inner cylinder 2
If the static load _W0 of the power unit is not applied to 4, the protrusion 25 of the insulator rubber 25
A is in pressure contact with the upper stopper 27 of the outer cylinder 22, but when the static load _W0 of the power unit is applied, it separates and forms an upper gap 28 as shown in FIG. The gap L ₃ of this upper cavity 28 is the lower cavity 2
9 gap L is smaller than ₄ . Other configurations and operations are the same as those of the first and second embodiments, so the same parts are given the same reference numerals and explanations will be omitted.

As explained above, according to this invention,
It has an outer cylinder that is attached to either the vehicle body or the rear of the power unit, an inner cylinder that is attached to the other, and an elastic body that connects the outer cylinder and the inner cylinder. In a rear mounting device for a power unit in which gaps are formed in the vertical direction between a cylinder and an inner cylinder, a bracket having a cutout opening is press-fitted into the outer cylinder, and the elastic body is mounted under no load. When the elastic body is inserted between the inner cylinder and the bracket so as to be compressively deformed and press-fitted into the inner cylinder and the outer cylinder, the elastic body protrudes from the opening and the abutting part that abuts on the inner circumferential surface of the outer cylinder. When the power unit is under a static load, the abutting portion separates from the inner circumferential surface of the outer cylinder, forming one gap between the inner circumferential surface of the outer cylinder and the abutting portion, and pinching the inner cylinder. Therefore, the gap between one cavity and the other cavity located on the opposite side is made larger than the gap between the other cavity, so that an elastic body with a low spring constant is used to suppress minute vibrations in the vertical direction of the vehicle body during idling. Since the muffled sound during forward acceleration is received by an elastic body with a low spring constant, the muffled sound can be reduced. There is an effect. Moreover, since the shape of the mounting device does not become large, the space in the engine room can be used effectively. In the second and third embodiments, the spring constant of the mounting device can be freely set by selecting the shapes of the outer cylinder and the elastic body.

[Brief explanation of drawings]

Fig. 1 is a schematic perspective view showing a conventional power unit mounting device together with the power unit, Fig. 2 is a cross-sectional view showing the conventional power unit rear mounting device in a state where no static load of the power unit is applied; Fig. 3 is a sectional view showing a conventional rear mounting device for a power unit with a static load of the power unit applied to it, and Fig. 4 shows the characteristics of the conventional rear mounting device for a power unit and a first embodiment of the present invention. 5 is a graph showing a comparison of the characteristics of the rear mounting device of the power unit of the first embodiment of the present invention, and FIG. figure,
Fig. 6 is a sectional view of the rear mounting device of the power unit of this embodiment excluding the outer cylinder, Fig. 7 is a side view of the rear mounting device of the power unit of this embodiment, and Fig. 8 is a sectional view of the rear mounting device of the power unit of this embodiment. A sectional view showing a state in which a static load of the power unit is applied to the rear mounting device of the power unit according to the second embodiment, and FIG. FIG. 3 is a cross-sectional view showing a state where a static load is applied. 21...Mounting device, 22...Outer cylinder,
23a...Opening, 24...Inner cylinder, 25...Insulator rubber (elastic body), 25a...Protrusion (contact part), 26...Lower stopper, 27...
...Upper stopper, 28...Upper gap, 29...Lower gap.

Claims (1)

[Claims] 1. An outer cylinder that is attached to either the vehicle body or the rear of the power unit, an inner cylinder that is attached to the other, and an elastic body that connects the outer cylinder and the inner cylinder. In a rear mounting device for a power unit in which cavities are formed in the vertical direction between a cylinder and an inner cylinder, a bracket having a cutout opening is press-fitted into the outer cylinder, and the elasticity is increased when no load is applied. When the body is compressed and deformed between the inner cylinder and the bracket and the inner cylinder is press-fitted into the outer cylinder, the elastic body protrudes from the opening and comes into contact with the inner peripheral surface of the outer cylinder. When the power unit is under static load, the abutting part separates from the inner peripheral surface of the outer cylinder to form one hollow part between the inner peripheral surface of the outer cylinder and the abutting part, and the inner A rear mounting device for a power unit characterized in that the space between one hollow part and the other hollow part located on the opposite side of the cylinder is larger than the space between one hollow part.