JPH0524449A - Power train supporting structure for vehicle - Google Patents

Abstract

PURPOSE:To relieve pitching phenomena a in abrupt acceleration and braking of a vehicle to prevent deterioration of steering stability and riding comfortableness of a vehicle. CONSTITUTION:A power train device 1 for vehicle provided with a power plant frame 6 for connecting a power unit 2 to a differential device 5 is supported on a vehicle body by means of a rubber mount 10 on the power unit side and a rubber mount 12 on the differential device side. Then the power train device 1 can be swung only in the longitudinal direction of a vehicle body in abrupt acceleration and braking, by equalizing torque reactions M1 and M2 defined by the elastic coefficient k1 and k2 and distances to a horizontal surface at which the center of gravity is positioned L1 and L2 for the rubber mounts, respectively. Thus pitching phenomena of the vehicle can be relieved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle powertrain support structure having a frame for connecting a power unit and a differential device.

[0002]

2. Description of the Related Art Conventionally, a power unit including an engine and a mission mounted on the front side of a vehicle body and a differential device mounted on the rear side of the vehicle body are connected to each other via a power plant frame having a large bending rigidity to drive the vehicle. A power train device is known in which a wind-up phenomenon (vertical swinging phenomenon) of a differential device at the time of starting due to a reaction force is prevented to improve the startability (see, for example, Japanese Patent Laid-Open No. 56-28053). . In this conventional power train device, since the power unit, the propeller shaft, the differential device and the power plant frame are integrated, it is considered as one object, and the object is connected to the power unit and the differential device through the elastic member. It is attached to the car body.

[0003]

By the way, when a vehicle is suddenly accelerated or suddenly braked, a so-called pitching phenomenon in which a front portion and a rear portion of a vehicle body vertically swing in opposite phases due to inertial force is generally generated in the vehicle. However, if this pitching phenomenon becomes excessive, the steering stability and riding comfort of the vehicle deteriorate. Therefore, there is a demand to alleviate this pitching phenomenon when designing a vehicle.

On the other hand, in a power train device that does not have a connecting member such as a power plant frame, a power unit consisting of an engine and a mission, which occupies most of the weight, is supported on the vehicle body only below the power unit via an elastic supporting member. Therefore, due to inertia in the front-rear direction of the vehicle body that occurs when the vehicle suddenly accelerates and suddenly brakes, the power unit itself swings downward. This is because the center of rotation is below the elastic support member, and this swinging promotes the pitching phenomenon in the vehicle as a whole.

In the power train device in which the power unit and the differential device are installed in the power plant frame as described above, the power train device is considered as one object, and the power train device is mounted below the power unit and above the differential device. Since it is supported by an elastic support member, the acceleration of the pitching phenomenon is suppressed to some extent, but the inertia generated by this power train device is considered as one object without a connecting member such as a power plant frame. Since it is larger than a power train device that has no structure, simply supporting it on the vehicle body below the power unit and above the differential device is not sufficient to suppress the pitching phenomenon.

Therefore, the present invention has been made to solve the above problems, and suppresses a pitching phenomenon that occurs in a vehicle having a power train device in which a power unit and a differential device are installed in a power plant frame. Its main purpose is to provide a powertrain support structure for the.

[0007]

According to a first aspect of the present invention, there is provided a powertrain support structure for a vehicle, comprising: a power unit composed of an engine and a mission; a differential device for distributing driving force to driving wheels; A propeller shaft for transmitting an output to the differential device, a frame connecting the power unit and the differential device, and a vehicle powertrain device comprising:

The vehicle powertrain device is supported on the vehicle body by at least a first elastic support member on the power unit side and a second elastic support member on the differential device side, and the first elastic support member is The second elastic support member is disposed below a horizontal plane passing through the center of gravity of the powertrain device, and the second elastic support member is disposed above the horizontal plane, and is generated by inertia of the powertrain device in the vehicle longitudinal direction. A first torque reaction force defined by the elastic coefficient of the first elastic support member and the distance from the arrangement position of the first elastic support member to the horizontal plane, the elastic constant of the second elastic support member, and the second elasticity. The second torque reaction force defined by the distance from the arrangement position of the support member to the horizontal plane is configured to be equal to each other. It is intended.

According to a second aspect of the present invention, there is provided a powertrain support structure for a vehicle according to the first aspect of the present invention, wherein the first elastic support member and the second elastic support member are both in a vehicle width direction. It is provided in two places,

A torque reaction force, which is generated by inertia of the power train device in the front-rear direction of the vehicle body and is defined by the respective elastic coefficients of the two positions of the first elastic support member and the distance from the arrangement position to the vertical plane, And the torque reaction forces defined by the respective elastic coefficients of the two locations of the second elastic support member and the distance from the arrangement position to the vertical surface are equalized between the left and right sides. It is a feature.

[0011]

The powertrain support structure for a vehicle according to the first aspect of the present invention is configured as described above,
The first torque reaction force (elastic coefficient of the first elastic support member and the first elastic support member) generated in the first elastic support member due to inertia of the powertrain device in the front-rear direction of the vehicle body that occurs when the vehicle suddenly accelerates and brakes. (Defined by the distance from the position of the support member to the horizontal plane that passes through the overall center of gravity of the powertrain device)
And a second torque reaction force generated in the second elastic support member (second
Since the elastic coefficient of the elastic support member and the distance from the position where the second elastic support member is arranged to the horizontal plane passing through the overall center of gravity of the powertrain device are equal), the powertrain device only moves in the front-rear direction. It is possible to prevent swinging that is biased in either direction.

With the vehicle powertrain support structure according to the second aspect of the present invention, by adopting the above-mentioned configuration, the same operation as that of the vehicle powertrain support structure according to the first aspect of the invention can be obtained. When the vehicle is suddenly accelerated or suddenly braked, the torque reaction forces generated at the two left and right positions of the first elastic support member are equal, and the torque reaction forces generated at the two left and right positions of the second elastic support member are also equal. Therefore, the power train device can be prevented from swinging in one of the left and right directions.

[0013]

Since the powertrain support structure for a vehicle according to the first aspect of the present invention operates as described above, the powertrain device only moves in the front-rear direction when the vehicle suddenly accelerates and brakes. Therefore, it is possible to prevent the pitching behavior of the vehicle from being promoted. Therefore, it is possible to prevent deterioration of the steering stability and riding comfort of the vehicle.

Further, in the powertrain support structure for a vehicle according to the second aspect of the present invention, the powertrain device moves only in the front-rear direction when the vehicle is suddenly accelerated or suddenly braked because the powertrain support structure acts as described above. Therefore, since the swing that is biased to either the left or right of the vehicle width does not occur, it is possible to prevent the lateral swinging phenomenon that occurs in the vehicle, that is, the so-called yawing phenomenon, from being promoted.

By controlling the behavior of the powertrain device as described above, the behavior of the powertrain device which occurs when the vehicle is suddenly accelerated or suddenly braked is only the movement in the front-rear direction, and the behavior to the vehicle is stable. As a result, driving stability and riding comfort can be improved.

[0016]

Embodiments of the present invention will be described in detail below with reference to FIGS.

1 and 2, reference numeral 1 denotes the entire power train device, and the power train device 1 is configured as follows. That is, the power unit 2 is mounted on the front part of the vehicle body, and the power unit 2 is
It is composed of an engine 3 and a transmission 4. A differential device 5 is mounted on the rear part of the vehicle body, and this differential device 5 is connected via an output shaft.
The driving force is distributed to driving wheels (not shown). The power unit 2 and the differential device 5 are connected by a power plant frame 6. The power plant frame 6 is formed in a laterally open U-shaped cross section, has a large bending rigidity, and is flexible against twisting. The power unit 2 and the differential device 5 are connected by a propeller shaft 7, and the power of the engine 3 is transmitted to drive wheels (not shown) via the propeller shaft 7 and the differential device 5.

As shown in FIG. 1, the point A indicates the position of the center of gravity of the power train device 1 including the power unit 2, the differential device 5, the power plant frame 6 and the propeller shaft 7. Power unit 2
Is attached to the cross member 11 by the rubber mount (first elastic member) 10.
Is further fixed to the vehicle body (not shown). Similarly, the differential device 5 is also attached to the cross member 13 by the rubber mount (second elastic member) 12, and the cross member 13 is further fixed to the vehicle body (not shown).

Further, the rubber mount (first elastic member) 10 of the power unit 2 is arranged below the horizontal plane S1 passing through the point A which is the position of the center of gravity of the power train device 1. The rubber mount (second elastic member) 12 of the differential device 5 is arranged above the horizontal plane S1. Next, the operation of the above embodiment will be described with reference to the simulated views of FIGS.

This power train support structure can be considered to be mechanically supported by the two elastic bodies 10 and 12 when the power train device 1 is considered as one rigid body. When suddenly braking the vehicle,
In this powertrain device 1, inertia acts to move forward as it is. When this inertia acts on a rigid body (powertrain device) 1 ′, the center of gravity of the rigid body is replaced by the simulated diagram of FIG. 3. Force F due to forward inertia on A
(Hereinafter, F is an inertial force) is defined to act. In addition, when a force having a certain direction and magnitude acts on the rigid body, the force can be moved with the same magnitude on the same line on the rigid body, so FIG. 3 is further simplified. As shown in FIG. 4, it can be considered that the inertial force F acts on the point A of the both-end burr (power train device) 1 ″ whose both ends are elastically supported.

According to this FIG. 4, the double-ended burr 1 "
In order to elastically support it so that it does not lean to one side,
ー Elasticity k of mount 10₁And rubber mount 10
Shape x₁And the distance L from point A to rubber mount 10₁To
Torque reaction force M obtained by multiplying₁And the rubber mount
Elastic coefficient k of g₂And rubber mount 12 deformation x₂When
Distance L from point A to rubber mount 12₂Multiplied by
Torque reaction force M obtained by₂And must be equal
Absent. That is, when expressed by the formula, M₁= M₂   It has to be. M₁, M₂As above M₁= K₁× x₁× L₁                   M₂= K₂× x₂× L₂   However, the displacement x₁And x₂Is always inclining
be equivalent to. Therefore, k₁× L₁= K₂× L₂・ ・ ・ ・ ・ ・ ・ ・ (I) Can be Of course, this formula is only for braking
It also holds true during acceleration.

[0022] Thus, holds the distance L _1, L ₂ from the elastic coefficient k _1, k ₂ and the horizontal plane S1 of the rubber mount 10 and De fa Ren Shall device 5 of the rubber mount 12 of the power unit 2 to the rubber mount formula (I) By setting in this way, the behavior of the power unit device 1 due to the inertial force F generated when the vehicle is suddenly accelerated or suddenly braked can be limited to movement in the front-rear direction. In this embodiment, since the distance L ₁ is about 1.5 times L ₂ , the elastic coefficient k _{2 is set} to k ₁
It is about 1.5 times higher. By setting in this way, the powertrain device does not promote the pitching behavior that occurs in the vehicle, so that the steering stability and the riding comfort are prevented from being deteriorated due to the pitching behavior at the time of sudden acceleration or braking of the vehicle. be able to.

Further, as shown in FIG. 2, the power unit 2
Rubber mount (first elastic member) 10 and rubber mount (second elastic member) 12 of the differential device 5
Are both provided on the left and right in the vehicle width direction, but both of them are provided at equal distances from a vertical plane S2 extending in the vehicle front-rear direction in which the overall center of gravity of the powertrain device 1 is located ( L _1L = L _1R , L _2L = L _2R ), and the elastic coefficients are made equal (k _1L = k _1R , k _2L = k _2R ),
As shown in the above formula (I), the reaction forces generated by the left and right rubber mounts are equal.

For this reason, the power train device does not cause left and right swinging behavior, so-called yawing phenomenon, when the vehicle is suddenly accelerated or suddenly braked. You can increase comfort.

[Brief description of drawings]

FIG. 1 is a side view showing an embodiment of a vehicle powertrain support structure of the present invention.

FIG. 2 is a plan view showing an embodiment of a vehicle powertrain support structure of the present invention.

3 is a side view of the vehicle powertrain support structure of FIG. 1. FIG.

FIG. 4 is a simplified side view of FIG.

[Explanation of symbols]

1 ... Power train device, 2 ... Power unit, 3 ... Engine, 4 ... Transmission, 5 ... Differential device, 6 ... Power plant frame (frame),
7 ... Propeller shaft, 10 ... Rubber mount (first elastic support member), 12 ... Rubber mount (second elastic support member), A ... Overall center of gravity of power train device, S1 ... Horizontal plane passing through overall center of gravity of power train device, S2 ... Vertical plane passing through the center of gravity of the power train device, F ... Inertial force, k
₁ ... Elastic coefficient of rubber mount (first elastic support member),
k the modulus of elasticity of ₂ ... rubber mount (second elastic support member), the distance from the position of L ₁ ... rubber mount (first elastic support member) to a horizontal plane passing through the entire center of gravity of the power train device, L ₂ ... rubber mount (Second elastic support member)
To the horizontal plane passing through the overall center of gravity of the power train device, M ₁ ... the first torque reaction force generated in the rubber mount (first elastic supporting member), M ₂ ... the rubber mount (second elastic supporting member) Second torque reaction force generated in the.

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location F16F 15/08 W 9138-3J

Claims (2)

[Claims] 1. A power unit composed of an engine and a mission, a differential device for distributing a driving force to driving wheels, a propeller shaft for transmitting an output from the power unit to the differential device, the power unit and the differential device. A power train device for a vehicle, the power train device for a vehicle comprising at least a first elastic support member on the power unit side and a second elastic support member on the differential device side. Is supported by the vehicle body, the first elastic support member is disposed below a horizontal plane passing through the overall center of gravity of the powertrain device,
The second elastic support member is arranged above the horizontal plane, and the elastic coefficient of the first elastic support member and the arrangement of the first elastic support member are generated by inertia of the powertrain device in the vehicle front-rear direction. The first torque reaction force defined by the distance from the position to the horizontal plane, and the second torque reaction force
A power train support for a vehicle, characterized in that the elastic constant of the elastic support member and the second torque reaction force defined by the distance from the arrangement position of the second elastic support member to the horizontal plane are equal. Construction. 2. The first elastic support member and the second elastic support member both sandwich a vertical plane extending in the vehicle body front-rear direction passing through the overall center of gravity of the powertrain device, and are located at two left and right positions in the vehicle width direction. It is provided, and is defined by the respective elastic coefficients of the two locations of the first elastic support member and the distance from the arrangement position to the vertical plane, which are caused by inertia of the powertrain device in the vehicle front-rear direction. The torque reaction force is equalized between the left and right sides, and the torque reaction force defined by the respective elastic coefficients of the two locations of the second elastic support member and the distance from the arrangement position to the vertical plane is equalized between the left and right sides. The powertrain support structure for a vehicle according to claim 1, wherein: