JP3384191B2 - Engine support device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine support device for supporting an engine on a subframe.

[0002]

2. Description of the Related Art Japanese Unexamined Utility Model Publication No. 2-41877 discloses a structure of a sub-frame for supporting a rear suspension device on a vehicle body. When the engine is mounted on such a sub-frame structure, an engine mount is provided between the sub-frame and the engine so that the vibration of the engine is not directly transmitted to the sub-frame. The structure of supporting the sub frame via the engine mount in this way will be described with reference to FIG. Note that, in FIG. 20, the arrow a indicates the front side of the vehicle.

As shown in FIG. 20, the front and rear of the engine 1 are mounted on the center member 11 via engine mounts 3 and 5.
Supported by. The center member 11 is arranged in the middle portion in the vehicle width direction along the vehicle front-rear direction, is supported by a suspension member (not shown) on the rear side, and is attached to the front cross member (not shown) on the front side via a rubber mount. It is supported. The center member 11 and the suspension member constitute a subframe that supports the engine. The left and right sides of the engine 1 are supported by front side members on both sides via engine mounts 7 and 9, respectively.

The engine mounts 3, 5 include insulators 13a, 13b fixed on the center member 11,
A bracket 17 having one side rotatably connected to the insulators 13a and 13b and the other side fixed to the engine 1.
It consists of a and 17b. Insulators 13a, 13b
Is formed by press-fitting a rubber mount 15 in the outer shell member 12.
The brackets 17a and 17b are rotatably connected with each other.

The engine mounts 7 and 9 are rotatably connected to insulators 19a and 19b fixed to the engine 1 and rubber mounts 21 of the insulators 19a and 19b, and also to left and right front side members (not shown). Brackets 23a and 23b.

Vibrations during engine operation are absorbed by the rubber mounts 15 and 21 of the insulators 13a, 13b, 19a and 19b so that the vibrations are not directly transmitted to the suspension member and the center member 11. As a result, noise (engine noise) due to vibration during engine operation is reduced.

[0007]

By the way, the sub-frame composed of the center member 11 and the suspension member has a small transmission force for high-frequency vibrations, but has a large transmission force for low-frequency vibrations, and has a sufficient vibration damping effect. No longer. Also, when the load on the engine increases, such as when the vehicle starts, the engine suddenly generates torque,
The engine strongly rotates (rolls) toward the rear of the vehicle due to the reaction force of the generated torque. For this reason, a large force is applied to the rubber mount 15 of the insulator 13a to deform it, and the bracket 17a abuts the outer shell member 12, so that the dynamic spring constant of the engine mount 3 sharply increases and the vibration damping effect deteriorates. As a result, the vibration force from the engine 1 is not blocked by the engine mount 3 and the center member 1
The vibration is transmitted to the sub-frame composed of 1 and the suspension member in the vertical direction.

On the other hand, due to the structure of the mount for supporting the sub-frame on the vehicle body, the sub-frame is formed so as to have low sensitivity to the input in the front-rear direction and has high sensitivity to the input in the vertical direction. It was something that would end up. Further, the subframe had a resonance point near about 50 Hz. Here, the engine speed at start is 100
The frequency of the rotational vibration of the engine centered on the engine roll center at this time is, for example, in the case of a four-cylinder vehicle, 33 to 32, which is the secondary component of the crankshaft rotational speed.
67 Hz. Therefore, at the time of starting, since the resonance point of the sub-frame exists between 33 to 67 Hz, which is the secondary component of the crankshaft rotation speed, the rotational vibration centered on the engine roll center due to the torque reaction of the engine and the center member 11 are generated. The engine noise is amplified by resonance with the vertical vibration of the engine.

Therefore, if the capacity of the insulator 13a is increased so that the dynamic spring constant of the engine mount 3 does not suddenly increase even if the vibration force due to the torque reaction force of the engine 1 is applied to the engine mount 3, the center member 11 will have a large capacity. Since the vibration force from the engine 1 is not applied, noise can be suppressed.

However, in this case, since the capacity of the engine mount 3 is large, the rotation amount (roll amount) of the engine 1 becomes large.

Further, it is conceivable to raise the dynamic spring constant in advance so that the dynamic spring constant of the engine mount 3 does not suddenly increase even if the exciting force resulting from the torque reaction of the engine is applied to the engine mount 3. However, in this case, the anti-vibration effect of absorbing the rotational vibration during the operation of the engine 1 is reduced.

In view of the above circumstances, an object of the present invention is to provide an engine support device capable of suppressing vertical vibration input to a subframe and reducing engine noise.

[0013]

In order to achieve the above-mentioned object, the invention according to claim 1 is an engine support device for supporting an engine on a subframe which is vibration-isolated and supported on a vehicle body, one end of which is on the engine side. Fixed and torque reaction at the other end
The bra extended below the roll center of the engine
And the other end of this bracket to the subframe
While connecting, it elastically moves more than a predetermined amount in the substantially horizontal direction.
Stopper for elastically blocking the rotation of the roll center around the roll center due to the torque reaction force of the engine and inputting the torque reaction force to the sub-frame in a substantially horizontal direction. It is characterized by having a structure.

[0014]

The invention described in claim 2 is the same as that described in claim 1.
The engine support device, wherein the stopper is the bracket.
Slot on the other end of the
The stopper rubber that has been
Insert and connect the other end of the bracket to the stopper rubber
It is characterized by consisting of bolts .

The invention according to claim 3 is claim 1 or claim
Item 3. The engine support device according to Item 2, wherein the stopper
Insulation for supporting the subframe on the vehicle body
It is characterized in that the vibrator is arranged at substantially the same height .

The invention according to claim 4 is claim 1 or claim
Item 3. The engine support device according to Item 2, wherein the stopper
Insulation for supporting the subframe on the vehicle body
The vertical distance from the insulator is approximately horizontal to the insulator.
It is characterized in that the height is set to be inversely proportional to the directional rigidity .

According to a fifth aspect of the invention, the vehicle body is vibration-proofed.
.Engines supporting the engine on a supported subframe
In the support device, one end is fixed to the engine side and the other
The end extends below the engine roll center due to the torque reaction force.
The installed bracket and one end at the other end of this bracket
A bag that is rotatably connected and has the other end extended in a substantially horizontal direction.
The far rod and the other end of this buffer rod are
It is connected to the subframe and is more than a predetermined horizontal
The stopper that elastically blocks the movement of the
The topper is located at the other end of the buffer rod along a substantially horizontal direction.
And the slots fixed to the subframe.
Insert the para-bar and the slot and stopper rubber into the bag
The bolt that connects the other end of the
And the roll due to the torque reaction of the engine.
It prevents the rotation around the center more than a predetermined amount, and
Luke reaction force is input to the sub-frame along a substantially horizontal direction.
It is characterized by having a stopper structure that allows it.

[0019]

The invention according to claim 6 is the invention according to claim 5.
And the other end of the buffer rod and the subframe.
Up and down with an insulator that supports and isolates the chassis from the vehicle body
Is inversely proportional to the rigidity of the insulator in the substantially horizontal direction
It is characterized by being set to a height that is related to .

[0021]

According to the first aspect of the present invention, when the engine is rotated by the torque reaction force, the bracket rotates about the engine roll center in synchronization with the engine, and the rotation thereof is performed by the stopper substantially below the engine roll center. Be blocked. In this case, since the bracket is connected to the stopper substantially below the engine roll center, the torque reaction force of the engine is input to the subframe in a substantially horizontal direction.

According to the second aspect of the present invention, when the engine is rotated by the torque reaction force, the bracket rotates around the engine roll center in synchronization with the engine. When the bracket rotates, the bolt relatively moves in the elongated hole provided at the other end of the bracket and comes into contact with the end wall of the elongated hole. At this time, since the bolt is inserted through the stopper rubber that restricts the horizontal movement beyond the predetermined amount, the other end of the bracket moves in the substantially horizontal direction, and the horizontal movement above the predetermined amount is restricted. It Therefore, excessive rotation of the engine is prevented.

According to the third aspect of the present invention, since the stopper and the insulator for supporting the subframe on the vehicle body are arranged at substantially the same height, the torque reaction force input to the subframe via the stopper is substantially equal. Since the input is made along the horizontal direction, the subframe is displaced only in the horizontal direction.

According to the invention of claim 4 , the vertical distance between the stopper and the insulator for supporting the sub-frame on the vehicle body is set to a height which is in inverse proportion to the rigidity of the insulator in the horizontal direction. As a result, the torque reaction force input to the subframe via the stopper is input in a substantially horizontal direction, and the subframe is displaced only in the horizontal direction.

[0026]

According to the fifth aspect of the present invention, when the engine is rotated by the torque reaction force, the bracket rotates about the engine roll center in synchronization with the engine. When the bracket rotates, the buffer rod connected to the other end of the bracket moves to the front side, and the bolt relatively moves in the long hole provided on the other side of the buffer rod to come into contact with the end wall of the long hole. . At this time, since the bolt is inserted through the stopper rubber, the other end of the bracket moves in a substantially horizontal direction. Then, the stopper rubber restricts the other end of the bracket from moving more than a predetermined amount in the horizontal direction, and prevents excessive rotation of the engine.

According to the sixth aspect of the present invention, the vertical distance between the other end of the buffer rod and the insulator supporting the subframe on the vehicle body is set to a height that is inversely proportional to the rigidity of the insulator in the horizontal direction. As a result, the sub-frame is displaced in the substantially horizontal direction with respect to the torque reaction force applied to the sub-frame via the stopper.

[0029]

Embodiments of the engine support device according to the present invention will be described below.

First Embodiment FIGS. 1 to 3 show the front side of a vehicle on which an engine 25 is supported by an engine support device according to the first embodiment. As shown in FIGS. 1 and 2, a suspension member 29 is arranged between the front wheels 27a and 27b. Both ends of the suspension member 29 are bifurcated, and each end is supported by a vehicle body (not shown) via the insulators 31, 31, 31, 31. Suspension arms 33a, 35a, 33b, 35b connected to the axle 28 are connected to the suspension member 29, respectively. Further, one end 37 a of the center member 37 is connected to an intermediate portion in the width direction of the suspension member 29. The other end 37b of the center member 37 extends forward and is supported by the lower end of the front cross member 39 via an insulator 41. The suspension member 29 and the center member 37 are combined to form the sub-frame 40.
Are configured. Further, the engine 25 is disposed in a horizontal position in front of the suspension member 29.

The engine 25 is supported by left and right front side members (not shown) via engine mounts 43 and 45, respectively, as shown in FIG.
Since the engine mounts 43 and 45 have the same structure as the engine mounts 7 and 9 shown in FIG. 20, their description is omitted here. The rear side of the engine 25 is vibration-isolated and supported by the center member 37 via an engine mount 47. As shown in FIG. 3, the engine mount 47 has a substantially L-shaped bracket 49 having one end fixed to the rear side of the engine 25 with a bolt 44 and the other end extending to a lower portion of the engine 25. The intermediate portion is rotatably supported and includes an insulator 51 fixed to the suspension member side of the center member 37.

As shown in FIG. 3, the bracket 49 has an upper bracket 49a and a lower bracket 49b which are bolts 48.
Are joined together to form an L-shape. One end of the upper bracket 49a is fixed to the rear side of the engine 25 with the bolt 44 as described above. The lower bracket 49b is attached to the engine 25 with three bolts (not shown).
It is fixed on the rear side. Furthermore, the lower bracket 49
A connecting portion 52 between the b and the upper bracket 49a is rotatably connected to the rubber mount 51a of the insulator 51 by a bolt 46. The insulator 51 is fixed to the center member 37. The lower bracket 49b is
It is formed in a U-shaped cross section, and long holes 57 and 59 are formed at the tip end on the side opposite to the coupling portion 52, respectively. In FIG. 3, reference numeral 56 is a rubber sheet.

Further, as shown in FIG.
The rear side suppresses the vertical input of the vibration force centered on the engine roll center 61, which is the center of rotation due to the torque reaction of the engine 25, to the sub-frame 40 including the center member 37 and the suspension member 29. In addition to inputting in a substantially horizontal direction, it is supported by a stopper structure 55 that prevents the engine 25 from rotating more than a predetermined amount.

One end of the stopper structure 55 is the engine 25.
And a bracket 49 having the other end extending substantially below the engine roll center 61 and the other end of the bracket 49 being rotatable below the engine roll center 61 and rotatable about the engine roll center 61. It comprises a stopper 53 which is displaceable and regulates a predetermined amount of horizontal movement and is connected to the center member 49. In addition,
In the stopper structure 55 of this embodiment, the bracket 49 of the engine mount 47 is also used.

The stopper 53 is fixed to the elongated holes 57 and 59 (see FIG. 3) provided at the other end of the bracket 49 and the center member 37, as shown in FIG. 5, and rotates about the engine roll center 61. A stopper rubber 63 that is deformable in the vertical direction and in the vertical direction, and that restricts the other end of the bracket 49 from moving more than a predetermined amount in the horizontal direction,
It is composed of bolts 65 which are inserted through the long holes 57 and 59 and the stopper rubber 63 and connect the other side of the bracket 49 to the stopper rubber 63.

As shown in FIG. 6, the stopper rubber 63 is composed of a metal outer shell member 67 having a rectangular cross-section with openings on both sides, and a mount rubber 69 press-fitted inside the outer shell member 67. The mount rubber 69 includes a main body 71 that comes into close contact with the inner wall of the outer shell member 67 and a bolt 73.
Is integrally formed with a support portion 77 in which an insertion hole 75 through which is inserted is formed. The main body portion 7 is provided on both sides of the support portion 77.
Bending spaces 79 and 79 are formed between them and 1, respectively. Therefore, the support portion 77 is flexibly deformable with respect to the main body portion 71 in the vertical direction and the horizontal direction, but the movement in the horizontal direction more than a predetermined amount is restricted. A sleeve 81 is fitted in the insertion hole 75 of the support portion 77. Both sides of the sleeve 81 project from the inside of the insertion hole 75. As shown in FIG. 7, a bolt 65 is inserted into the sleeve 81, and a nut 80 is screwed into the tip portion. Two washers 83, 83 are fitted to the bolt 73 on both sides of the collar 85 with a predetermined space therebetween at predetermined intervals. The space between the washers 83 is inserted into the long holes 57 on the other end side of the bracket 49. In such a stopper rubber 63, the outer shell member 67 is welded to the center member 37, or is fixed by a bolt or the like.

Then, in the operating state of the engine 1,
When the load on the engine becomes large like when the vehicle starts,
The engine 1 is rotated by a torque reaction force, and as shown in FIG. 1, the engine 1 rolls around the engine roll center 61 so as to fall toward the rear of the vehicle. When the engine 1 rotates about the engine roll center 61, the bracket 49 fixed to the rear side of the engine 1 is also rotationally displaced about the engine roll center 61 in synchronization with the engine 1. At this time, since the long holes 57 and 59 provided at the other end of the lower bracket 49b are located below the engine roll center 61, they are displaced in a substantially horizontal direction. As a result, the rear ends of the long holes 57 and 59 come into contact with the bolt 65 inserted through the stopper rubber 63, and the vibration force centering on the engine roll center due to the torque reaction force of the engine causes the center member to vibrate. The input in the vertical direction is suppressed with respect to 37, and the input is performed in the substantially horizontal direction. Further, by restricting the displacement of the lower bracket 49b in the substantially horizontal direction more than a predetermined value,
The rotational displacement of the bracket 49 is blocked to prevent the engine 1 from rotating excessively.

According to this embodiment, the engine mount 47
Since it is not necessary to support the torque reaction force of the engine 25, it is possible to use an insulator having a low spring constant, suppress vibration during engine operation, and effectively reduce noise.

Further, the stopper rubber 63 of the stopper 53
Has a high spring constant in the horizontal direction, and the vibration force due to the torque reaction force of the engine 25 is transmitted to the center member 37 via the stopper 53. However, since the stopper 53 is located below the engine roll center 61, this exciting force is mainly input in a substantially horizontal direction (front-rear direction), and the exciting force component in the up-down direction is small, so that the center member 37 is fed. It is possible to suppress the vertical input of. Therefore, since the sub-frame 40 does not resonate in the vertical direction, engine noise is not amplified and noise can be suppressed. Therefore, with respect to the horizontal (front-rear direction) input to the subframe 40, the vehicle body radiation transfer coefficient in the front-rear direction of the subframe 40 is higher than that in the vertical direction in the frequency band of the main excitation force component at the time of starting. Since it is small, noise does not increase so much as to impair comfort even if a large excitation force is input in the front-rear direction, so that a comfortable vehicle interior space can be provided.

Further, in this embodiment, since the bracket 49 is also used, the number of parts does not increase.

In the above embodiment, the bracket 49 of the stopper structure 55 is also used as the bracket of the engine mount 47. However, a separate bracket is set to fix one side to the engine 25 side and the other side to the engine 25 side. The sub-frame may be supported by the stopper 53 below the roll center 61.

Next, the structure of another stopper rubber shown in FIGS. 8 to 11 will be described. The stopper rubber 87 shown in FIGS. 8 to 11 is composed of a metal outer shell member 89 having a rectangular cross-sectional shape with openings on both sides, and a mount rubber 91 press-fit into the outer shell member 89. Mount rubber 91
The main body portion 93, which comes into close contact with the opposing inner walls 89a, 89a of the outer shell member 89, and the support portion 97 having the insertion hole 95 into which the bolt 65 is inserted are integrally formed. Bending spaces 99, 9 are provided on the upper and lower sides and both sides of the supporting portion 97.
9, 101, 101 are formed. Therefore, the support portion 97 is flexibly deformable with respect to the main body portion 93 in the vertical direction and the horizontal direction, but the movement in the horizontal direction beyond a predetermined level is restricted.

Further, as shown in FIG. 10, the sleeve 103 is fitted in the insertion hole 95 of the support portion 97.
Both sides of the sleeve 103 project from the inside of the insertion hole 95. Further, the bolt 65 is inserted into the sleeve 103, and the bolt 80 is screwed into the tip portion. Further, two washers 83, 83 are fitted to the bolt 65 on both sides with a collar 85 interposed therebetween at a predetermined interval. The space between the washers 83 is inserted into the long holes 59 on the other end side of the bracket 49.

Also in the stopper rubber 83 of this modified example, the outer shell member 67 is welded to the center member 37 or fixed by bolts and nuts.

Then, similarly to the above embodiment, the engine 2
When the engine 25 is rotated about the engine roll center 61 by the vibration force caused by the torque reaction force of 5, the bracket 49 fixed to the rear side of the engine 1 is also centered on the engine roll center 61 in synchronization with the engine 1. It is rotationally displaced. At that time, the long hole 59 provided in the bracket 49
Is disposed substantially below the engine roll center 61, and is displaced in a substantially horizontal direction. As a result, the rear end portion of the long hole 59 and the bolt 65 inserted into the stopper rubber 63 come into contact with each other, preventing the bracket 49 from rotating and preventing the engine 1 from rotating excessively.

Second Embodiment Next, a second embodiment will be described with reference to FIGS. 12 and 13. In the above-described embodiment, the example of the support device in the engine in which the engine 25 is placed horizontally, that is, the engine mounted on the vehicle so that the crankshaft extends along the vehicle width direction has been shown. It is a support device for a so-called vertical engine 107 that is mounted on a vehicle.

As shown in FIGS. 11 and 12, the front wheel 27
A suspension member 105 as a sub-frame 40 that supports the engine is arranged between a and 27b.
The suspension member 105 has a square shape, and its four corners are supported via mounts 109, 109, 109, 109 by cross members (not shown) provided between front side members on both sides of the front part of the vehicle. ing. One ends of suspension arms 111 are connected to the rear sides of both sides of the suspension member 105. The other end of the suspension arm 111 is connected to the left and right front wheels 27a and 27b on the axle side. Furthermore, on both front sides of the suspension member 105,
One ends of the suspension arms 113, 113 are connected. The other ends of the suspension arms 113, 113 are connected to intermediate portions of the suspension arms 111, 111. An engine 107 is vertically arranged above the suspension member 105.

The engine 107 has engine mounts 115, 1 on both left and right sides (right and left in the traveling direction of the vehicle).
It is supported by the suspension member 105 via 16. The engine mount 116 on the right side is the engine 10
7, a bracket 117 whose one end is fixed to the right side, and a mount rubber 119 which supports the other end of the bracket 117 and is fixed on the suspension member 105. The left engine mount 115 has a substantially L-shaped bracket 121, one end of which is fixed to the left side of the engine 107 and the other end of which extends to a lower portion of the engine 107, and a suspension member which supports an intermediate portion of the bracket 121. And a mount rubber 123 fixed on 105.

Further, one end of the left side of the engine 107 is fixed to the engine 107 side, and an engine roll center 125, which is a center of rotation caused by a torque reaction force during the operation of the engine 107 in synchronization with the engine 107, is centered. It is rotatable and movable in the vertical direction, and is supported by a stopper structure 127 that restricts a predetermined amount of horizontal movement.

One end of the stopper structure 127 is the engine 1
It is fixed on the left side of 07 and the other end is the engine roll center 1
The bracket 121 extending up to 25 and the other end of the bracket 121 can be rotationally displaced about the engine roll center 125, can be moved in the vertical direction, and regulate a movement in a horizontal direction beyond a predetermined level. It consists of a stopper 125. In this embodiment, the engine mount 1
The 15 brackets 121 are also used. The bracket 121 includes an upper bracket 121a and a lower bracket 121b, and the lower bracket 121b has a long hole 12
9 is formed.

The stopper 125 has the same structure as the stopper 53 shown in FIGS. 1 and 3, and is fixed to the elongated hole 129 provided at the other end of the bracket 121b and the suspension member 105 so as to rotate about the engine roll center 125. In addition, the stopper rubber 63 that is deformable in the vertical direction and that restricts the other end of the bracket 121 from moving in the horizontal direction more than a predetermined amount, and the other side of the bracket 121 through the elongated hole 129 and the stopper rubber 63. And a bolt 65 connecting the stopper rubber 63 to the stopper rubber 63.

Then, when the engine load becomes large when the engine 107 is operating, such as when the vehicle is starting,
The engine 107 is rotated by the torque reaction force, and as shown in FIG.
Roll so that 7 falls to the side of the vehicle. Engine 10
When 7 rotates about the roll center 125, the bracket 121 fixed to the side of the engine 107 is also rotationally displaced about the engine roll center 125 in synchronization with the engine 107.

At this time, since the elongated hole 129 provided in the bracket 121 is located below the engine roll center 125, the other end of the lower bracket 121b is displaced in a substantially horizontal direction. As a result, the rear end portion of the elongated hole 129 and the bolt 65 inserted into the stopper rubber 63 come into contact with each other, and the vibration reaction force centered on the engine roll center 125 due to the torque reaction force of the engine 25 causes the suspension member. 1
With respect to 05, the input in the vertical direction is suppressed and the input is performed in the substantially horizontal direction (vehicle width direction). Further, by restricting the displacement of the lower bracket 121b beyond a predetermined value, the rotational displacement of the bracket 121 is prevented, and the engine 107 is prevented from rotating excessively.

According to this embodiment, the engine mount 12
In No. 1, it is not necessary to support the exciting force caused by the torque reaction force of the engine 107, so that an insulator with a low spring constant can be used, vibration during engine operation can be sufficiently prevented, and noise is effective. Can be reduced.

Further, the stopper rubber 63 of the stopper 53
Has a high spring constant in the horizontal direction, and the vibration force due to the torque reaction force of the engine 25 is transmitted to the center member 37 via the stopper 53. However, since the stopper 53 is located below the engine roll center 61, the exciting force is mainly input in the horizontal direction, and the exciting force component in the vertical direction is small,
Vertical input to the suspension member 105 can be suppressed. Therefore, the suspension member 10
Since 5 does not resonate vertically, engine noise is not amplified. Therefore, with respect to the horizontal (front-back direction) input to the suspension member 105 as a sub-frame, the vehicle body radiation transfer coefficient in the front-back direction of the suspension member 105 rises and falls in the frequency band of the main excitation force component at the time of starting. Since it is smaller than the direction, noise does not increase so as to impair comfort even when a large excitation force is input in the front-rear direction, so that a comfortable vehicle interior space can be provided.

Third Embodiment Next, a third embodiment shown in FIGS. 14 to 16 will be described. In this embodiment, the stopper structure has the engine 2 at one end.
A bracket 139 fixed to the fifth side and having the other end extended to the lower part of the engine, the other end of the bracket 139 is rotatably connected below the engine roll center 61, and the other end is behind the engine 25. A buffer rod 131 extending in the vertical direction, and a stopper 133 that is capable of relatively rotating the other end of the buffer rod 131 and that restricts the horizontal movement beyond a predetermined level to connect to the suspension member 29 as a sub-frame. Become.

As shown in FIG. 15, the bracket 139 comprises an upper bracket 49a having the same structure as that of the first embodiment, and a lower bracket 139b connected to the upper bracket 49a by a bolt 48 at a connecting portion 52. On the opposite side of the connecting portion 52 of the lower bracket 139b, a connecting hole 140,
140 is formed. These connecting holes 140, 14
At 0, a connecting portion 130a at one end of the buffer rod 131 is rotatably supported. Buffer rod 13
The other end of 1 is supported by the suspension member 29 via a stopper 133.

The stopper 133, as shown in FIG.
The stopper rod 63 includes a long hole 135 provided on the other side of the buffer rod 131 along a substantially horizontal direction. Further, the stopper rubber 63 is used for the suspension member 29.
Bracket 1 fixed to the bottom side of the plate with bolts 137
It is fixed at 39. Further, the vertical height of the connecting portion 130a (see FIG. 15) between the lower bracket 139b and the buffer rod 131 is determined by the bolt 65 of the stopper 133.
Is approximately equal to the vertical height of.

Then, when the engine load increases in the operating state of the engine 25, such as when the vehicle is started,
The engine 25 rotates by the torque reaction force, and rolls around the engine roll center 61 so that the engine 25 falls toward the rear of the vehicle (see FIG. 1). When the engine 25 rotates about the roll center 61, the bracket 139 fixed to the rear side of the engine 25 is also rotationally displaced about the engine roll center 61 in synchronization with the engine 25. When the bracket 139 rotates about the engine roll center 61, the other end of the bracket 139, that is, the connecting portion 130a of the buffer rod 131 moves substantially horizontally to the front side, and the buffer rod 131 moves substantially horizontally to the front side as a whole. Let When the buffer rod 131 moves to the front side in a substantially horizontal direction, the buffer rod 13
The rear end portion of the long hole 135 provided at the other end of 1 and the bolt 65 inserted through the stopper rubber 63 come into contact with each other to prevent the buffer rod 131 from moving further, and as a result, the engine 25 becomes excessively large. Prevent rolling.

According to this embodiment, the engine mount 47
Since it is not necessary to support the torque reaction force of the engine 25, an insulator having a low spring constant can be used, vibrations during engine operation can be sufficiently prevented, and noise can be effectively reduced.

Further, the stopper rubber 6 of the stopper 133
3 has a high spring constant in the horizontal direction, and the vibration force due to the torque reaction force of the engine 25 is transmitted to the mounting bracket 139 and the suspension member 29 via the stopper 133. However, since the connecting portion between the lower bracket 139b and the buffer rod 131 is located substantially below the engine roll center 61, the exciting force is mainly input in the horizontal direction,
The vertical component of the exciting force is small, and the vertical input to the suspension member 29 can be suppressed. Therefore, since the suspension member 29 does not resonate in the vertical direction, engine noise is not amplified. Therefore,
It is possible to provide a comfortable vehicle interior space.

Further, according to this embodiment, by using the buffer rod 131 even in a structure in which there is no member substantially below the engine roll center 61, such as a double girder type subframe or an I-shaped subframe, The present invention can be applied.

Fourth Embodiment Next, a fourth embodiment will be described with reference to FIG. This embodiment has the same configuration as the third embodiment, and the connecting portion between the other end of the bracket 49 and the buffer rod 131 is located substantially below the roll center 61, and the connecting portion between the buffer rod 131 and the bracket 49 is a buffer. The height is the same as the height of the connecting portion between the other end of the rod 131 and the stopper 133.
In the present embodiment, the vertical distances L1 and L2 of the insulators 141 and 143 supporting the suspension member 29 to the vehicle body from the stopper 133 are inversely proportional to the rigidity (K1, K2) of these insulators 141 and 143 in the front-rear direction. The relationship is (L1: L2 = K2: K1).

That is, the product L1 × K1 of the vertical distance L1 from the stopper 133 to the insulator 141 on the lower side of the suspension member 29 and the rigidity K1 of the insulator 141 in the front-rear direction is calculated from the stopper 133 to the upper side of the suspension member 29. Insulator 14
The vertical positions of the insulators 141 and 143 that support the suspension member 29 on the vehicle body are set so that the product L2 × K2 of the vertical distance L2 to 3 and the longitudinal rigidity K2 of the insulator 143 becomes equal.

This embodiment has the same functions and effects as the third embodiment, and additionally, the stoppers 133 of the insulators 141, 143 for supporting the suspension member 29 on the vehicle body.
The vertical distances L1 and L2 from the
By setting the height in a relationship inversely proportional to (L1: L2 = K2: K1), the suspension member 29 is displaced by pitching or the like with respect to the longitudinal excitation force input via the buffer rod 131. It is possible to displace only in the substantially horizontal direction (front-back direction) without performing the above, and as a result, the resonance of the suspension member 29 in the vertical direction can be further suppressed.

Further, according to this embodiment, the insulators 141, 1 for supporting the suspension member 29 on the vehicle body are provided.
If the rigidity of 43 is changed, these insulators 1
Since it is possible to deal with the change of the mounting positions of 41 and 143, that is, the mounting position of the suspension member 29 to the vehicle body, the degree of freedom in design is high.

Fifth Embodiment Next, a fifth embodiment shown in FIG. 18 will be described. In this embodiment, the mounting position of the rear end of the center member 145 to the suspension member 29 is different from that of the first embodiment.

That is, as shown in FIG. 18, the rear end portion of the center member 145 of this embodiment is supported by the suspension member 29 through the insulator 147 on the same horizontal plane as the stopper 53.

In this embodiment, the same actions and effects as those of the above-described first embodiment can be obtained, and in addition, the suspension member 2
9, the stopper 53 and the support member on the rear end side of the center member 145 are on the same horizontal plane.
The suspension member 29 is displaced only in the front-rear direction without being displaced by pitching or the like with respect to the front-rear direction excitation force input to the center member 145 via 3.
As a result, the vertical resonance of the suspension member 29 can be suppressed.

Sixth Embodiment A sixth embodiment shown in FIG. 19 is different from the fifth embodiment in that
Insulator 4 for supporting the center member 149 on the vehicle body
1, 151 and the stopper 53 in the vertical direction L1, l
2 is the rigidity K of the insulators 41 and 151 in the front-rear direction
It is in inverse proportion to 1 and k2.

That is, as shown in FIG. 19, the front end of the center member 145 of this embodiment is supported by the front cross member via the insulator 41. The insulator 41 is vertically extended from the stopper 53.
It is located at a distance of 1. In addition, the center member 145
The rear end portion is supported by the suspension member 29 via the insulator 151. The insulator 151 is arranged at a distance L2 in the vertical direction with respect to the stopper 53.

The product L1 × K2 of the rigidity K1 of the insulator 41 in the front-rear direction and the distance L1 is determined by the stopper 53.
The center member 149 is supported by the vehicle body so that the product L2 × K2 of the distance L2 from the to the insulator 151 and the rigidity K2 of the insulator 151 in the front-rear direction becomes equal.

In this embodiment, in addition to the same effects and advantages as those of the first embodiment, the product L1 × K2 of the rigidity K1 of the insulator 41 in the front-rear direction and the distance L1 is calculated from the stopper 53 to the insulator 151. L2 × the distance L2 to the rigidity K2 of the insulator 151 in the front-rear direction
By making K2 equal, the stopper 53
The suspension member 29 is displaced only in the front-rear direction without being displaced by pitching or the like in response to the front-rear direction excitation force input to the center member 145 via the center member 145. Resonance can be further suppressed.

Further, according to this embodiment, if the rigidity of the insulators 41, 151 is changed, the center member 14
Since it is possible to deal with a change in the mounting position of the vehicle body 9 or the suspension member 29, the degree of freedom in design is high.

In the above embodiment, the example in which the engine mounted on the front side of the vehicle is supported has been described, but the present invention can be applied to the case where the engine mounted on the rear side is supported. . Furthermore, the present invention can be applied regardless of the type of drive wheels (front wheel drive, rear wheel drive, four-wheel drive).

[0076]

As described above, according to the first aspect of the present invention, when the engine rotates due to the torque reaction force of the engine, the vibration force due to this rotation is applied to the sub-frame through the stopper structure. It is input in a substantially horizontal direction while suppressing vertical vibration. Therefore, it is possible to suppress the vertical resonance of the subframe, and as a result, it is possible to prevent amplification of engine noise and provide a comfortable vehicle interior space. Also, since the bracket is connected to the stopper below the engine roll center, the vibration force due to the torque reaction of the engine is input in a substantially horizontal direction with respect to the sub-frame,
The vertical resonance of the subframe is suppressed.

[0077]

According to the second aspect of the present invention, when the engine rotates due to the torque reaction force of the engine, the bracket rotates about the engine roll center in synchronization with the engine and is provided at the other end of the bracket. The bolt relatively moves in the elongated hole and abuts on the rear end portion of the elongated hole. At this time, since the bolt is inserted through the stopper rubber, the other end of the bracket moves in a substantially horizontal direction, and the stopper rubber restricts the other end of the bracket from moving more than a predetermined amount in the horizontal direction. Therefore, excessive rotation of the engine is prevented.

According to the third aspect of the present invention, the stopper and the insulator for supporting the subframe on the vehicle body are arranged at substantially the same height, so that the vibration force applied to the subframe through the stopper is applied. Thus, the subframe does not resonate in the vertical direction, and the subframe is displaced only in the horizontal direction.

According to the invention of claim 4 , the vertical distance between the stopper and the insulator for supporting the sub-frame on the vehicle body is set to a height which is in inverse proportion to the rigidity of the insulator in the horizontal direction. By
The sub-frame is displaced only in the horizontal direction with respect to the vibration force input to the sub-frame via the stopper.

According to the fifth aspect of the present invention, by using the buffer rod, even if there is no member for supporting the other end of the bracket below the engine roll center, the vibration generated due to the torque reaction force of the engine is generated. The force can be input in the horizontal direction by suppressing the input in the vertical direction to the subframe via the stopper. Also, when the engine rotates due to the torque reaction of the engine, the bolts
Since it is inserted through the stopper rubber, the other end of the bracket moves in a substantially horizontal direction, and the stopper rubber restricts the other end of the bracket from moving more than a predetermined amount in the horizontal direction. Therefore, excessive rotation of the engine is prevented.

[0082]

According to the sixth aspect of the present invention, the vertical distance between the other end of the buffer rod and the insulator for isolating and supporting the sub-frame on the vehicle body is in the inverse proportion to the rigidity in the horizontal direction of the insulator. The height of the sub-frame causes the sub-frame to be displaced only in the horizontal direction with respect to the vibration force input to the sub-frame via the stopper.

[Brief description of drawings]

FIG. 1 is a side view showing an engine of a first embodiment supported by an engine support device according to the present invention and a center member supporting the engine.

FIG. 2 is a plan view showing an engine of a first embodiment supported by an engine support device according to the present invention and a center member supporting the engine.

FIG. 3 is an exploded perspective view showing an engine mount bracket of the first embodiment.

FIG. 4 is a side view showing the stopper structure of the first embodiment.

FIG. 5 is a perspective view showing a relationship between a suspension member, a center member and a stopper of an automobile.

FIG. 6 is a perspective view showing a stopper rubber of the first embodiment.

7 is a cross-sectional view showing the relationship between the stopper rubber shown in FIG. 6 and the other end of the bracket.

FIG. 8 is a front view showing a stopper rubber of a modified example of the stopper rubber in the first embodiment.

9 shows the stopper rubber shown in FIG. 8, IX-IX
It is sectional drawing cut | disconnected along the line.

10 is a cross-sectional view showing a mounting relationship between the stopper rubber shown in FIG. 8 and the other end of the bracket.

11 is a perspective view showing the stopper rubber shown in FIG. 8. FIG.

FIG. 12 is a side view showing an engine of a second embodiment supported by the engine support device according to the present invention and a suspension member supporting the engine.

FIG. 13 is a plan view showing an engine of a second embodiment supported by the engine support device according to the present invention and a suspension member supporting the engine.

FIG. 14 is a side view showing an engine and a center member supported by an engine support device of a third embodiment according to the present invention.

FIG. 15 is an exploded perspective view showing the relationship between the buffer rod and the bracket in the third embodiment.

FIG. 16 is an exploded perspective view showing the connection between the buffer rod and the stopper in the third embodiment.

FIG. 17 is a side view showing the relationship between the buffer rod and the stopper in the fourth embodiment.

FIG. 18 is a side view showing the relationship between the buffer rod and the stopper in the fifth embodiment.

FIG. 19 is a side view showing the relationship between the buffer rod and the stopper in the sixth embodiment.

FIG. 20 is an exploded perspective view showing an engine and a mount in a conventional engine support device.

[Explanation of symbols]

25 engine 29,105 Suspension member 31 mount 37, 145, 149 Center members (subframe) 40 subframes 55, 127 Stopper structure 53, 125 stopper 61 Engine Roll Center 63, 87 Stopper rubber 65 volts 131 buffer rod

─────────────────────────────────────────────────── ─── Continuation of front page (56) Bibliography Sho 63-69835 (JP, U) (58) Fields investigated (Int.Cl. ⁷ , DB name) B62D 21/00 B60K 5/12 B62D 21 / 11

Claims (6)

(57) [Claims] 1. An engine support device for supporting an engine on a subframe that is vibration-isolated / supported with respect to a vehicle body,
One end is fixed to the engine side and the other end is due to torque reaction force.
Bracket extending below the roll center of the engine
And connect the other end of this bracket to the subframe
It also elastically blocks more than a predetermined amount of horizontal movement.
A stopper structure for elastically blocking a predetermined or more rotation around the roll center due to the torque reaction force of the engine and inputting the torque reaction force to the sub-frame in a substantially horizontal direction. An engine support device having. 2. The engine support device according to claim 1,
The stopper is the length provided on the other end of the bracket.
Hole and stopper rubber fixed to the subframe
And insert it through the long hole and stopper rubber
An engine support device comprising: a bolt that connects the other end to a stopper rubber . 3. The engine support according to claim 1 or 2.
A holding device, the stopper and the sub-frame
Height that is almost equal to the insulator that supports and supports the vehicle body
The engine support device is characterized in that it is arranged in . 4. The engine support according to claim 1 or 2.
A holding device, the stopper and the sub-frame
Vertical distance from the insulator that supports and supports the vehicle body
The separation is inversely proportional to the rigidity of the insulator in the substantially horizontal direction.
An engine support device characterized by being set to a certain height . 5. A subframe that is vibration-isolated and supported with respect to a vehicle body.
In the engine support device that supports the engine on the chassis,
One end is fixed to the engine side and the other end is due to torque reaction force
Bracket extending below the engine roll center
And one end is rotatably connected to the other end of this bracket.
A buffer rod whose other end extends in a substantially horizontal direction, and
Connect the other end of the buffer rod to the subframe
It also elastically blocks more than a predetermined amount of horizontal movement.
It consists of a stopper to stop, and the stopper is a buffer
-In the other end of the rod,
The stopper rubber fixed to the subframe and the length
Insert the buffer rod through the hole and stopper rubber
Consists of a bolt connecting the end to the stopper rubber, the
A certain amount around the roll center due to the torque reaction of the engine
The upper rotation is elastically blocked, and the torque reaction force is
Stopper structure that allows input along the horizontal direction in the frame
An engine support device comprising: 6. The invention according to claim 5, wherein the bag is
Anti-vibration / support of the other end of the fur rod and the subframe to the vehicle body
The vertical distance from the insulator
Is installed at a height that is inversely proportional to the rigidity of the
An engine support device characterized by being specified .