JPH04325721A - Power plant and mounting structure thereof - Google Patents

Abstract

PURPOSE:To suppress complicated vibration of a rigid body by respectively specifying a position of the center of gravity and a position on which reactions of explosive powers of respective cylinders act, in a power plant arranging a crankshaft between appointed two cylinders and arranging a transmission in a direction nearly orthogonal to the extending direction of the crankshaft. CONSTITUTION:A four cylinder engine 12 is transversely arranged so as to be parallel with a vehicle body a crankshaft 24 thereof, and a transmission 22 is longitudinally arranged before the engine 12 so as to be along a direction nearly orthogonal to the crankshaft 24 the rotation axis thereof. In such a constitution of power plant 23, a position of the center of gravity G thereof is set to nearly the center part of the first and the fourth cylinders for width direction of the vehicle body, and set to near a straight line connecting points of application of reactions due to respective explosions of the first and the fourth cylinders together, for longitudinal direction of the vehicle body. Moreover, direction of rotation of the crankshaft 24 and direction of rotation of a wheel axle 53 rotating the front wheels are made to reverse direction to each other, and the component power plant 23 is supported in three points by three engine mounts 13, 15A, 15B.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power plant that extracts power from between cylinders in a direction substantially perpendicular to the extending direction of a crankshaft, and its mounting structure.

0002

2. Description of the Related Art There are various possible arrangements for mounting an engine and a transmission on a vehicle, and for the direction in which the engine and transmission are connected. Among these, the ones that have been commonly adopted include mounting the engine vertically or horizontally on the vehicle body, and installing a flywheel and output gear at one end of the engine crankshaft to generate output power. Power is extracted from the gears to a transmission located parallel to the crankshaft.

0003

[Problems to be Solved by the Invention] However, in the above conventional example, the flywheel is attached to one end of the engine, and the transmission is connected to that part. The center of gravity of the power plant, including the aircraft, is located at a position that is quite offset relative to the overall external shape of the power plant. Therefore, when the engine is operated, complex rigid body vibrations are generated in the power plant due to the excitation force generated by the engine itself, which is transmitted into the passenger compartment, resulting in a problem in that ride comfort is impaired. In addition, in order to dampen the power plant's complex rigid body vibrations, the power plant is
Since the engine mount must be supported at points, there is less freedom in the arrangement of the engine mount, and this poses a problem in that it becomes an obstacle when trying to use the space in the engine room efficiently.

[0004] Therefore, the present invention has been made in view of the above-mentioned problems, and its purpose is to provide a power plant that can suppress complex rigid body vibrations and that can be supported with fewer support points to the vehicle body. and its mounting structure.

[0005]

[Means for Solving the Problems] In order to solve the above-mentioned problems and achieve the objects, the power plant of the present invention has a plurality of cylinders, and the crankshaft is connected between two predetermined cylinders among these cylinders. A power plant that connects an engine that extracts the rotational force of a shaft and a transmission arranged in a direction substantially perpendicular to the direction in which the crankshaft of the engine extends, the center of gravity of which is Regarding the extending direction of the crankshaft, it is set near the center between the cylinders located at both ends, and regarding the direction perpendicular to the extending direction of the crankshaft, the reaction force of the explosion in each cylinder acts on the engine. It is characterized by being set near the straight line connecting the points of application.

Further, in the power plant according to the present invention, the engine is disposed laterally with respect to the vehicle body, and the rotation direction of the crankshaft and the rotation direction of the drive shaft for rotationally driving the front wheels are opposite to each other. It is characterized by the direction. Further, in the power plant mounting structure of the present invention, one engine mount supporting the transmission and two engine mounts supporting the engine are arranged so as to surround the center of gravity of the power plant, and the power plant The engine is characterized by being supported at three points by these engine mounts.

[0007]

[Operation] As described above, the power plant and its mounting structure according to the present invention are configured, so that it is possible to balance the amplitude of the end of the power plant due to the rotational movement around the center of gravity of the power plant. Since it is possible to suppress the excitation force that tilts the power plant in an oblique direction, it works to suppress complex rigid body vibrations of the power plant and improve ride comfort.

Furthermore, by supporting the power plant at three points, the degree of freedom in arranging the engine mount is improved in response to the suppression of self-excited rigid body vibration of the power plant itself.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will now be described in detail with reference to the accompanying drawings. FIG. 1 shows the first embodiment of the present invention.
A power plant to which the engine structure of the example is applied,
It is a sectional view seen from the side. The engine 12 is connected to the vehicle body 10
The engine compartment 14 and the vehicle compartment 16 are separated by a dash panel 18. A radiator 20 is disposed at a front position within the engine room 14, and the engine 12 and transmission 22 are disposed in a space sandwiched between the radiator 20 and the dash panel 18. Although the details will be described later, the power plant 23, which is formed by connecting the engine 12 and the transmission 22 located in front of the engine 12, has its front part located at the front lower part of the transmission 22 in the vehicle width direction of the vehicle body 10. It is supported by an engine mount 13 disposed approximately in the center of the engine 12, and its rear end is located at the rear end of the engine 12, and is supported by an engine mount 13 located approximately at the center of the engine 12.
It is supported by engine mounts 15A and 15B arranged at certain locations. Therefore, this power plant 23 has engine mounts 13, 15A, 1 provided at three locations in total, one on the front side and two on the rear side with respect to the vehicle body 10.
5B (see Figure 5).

[0010] Here, the engine 12 is a four-cylinder reciprocating engine, and is arranged with respect to the vehicle body 10 so that the crankshaft 24 is parallel to the axle (horizontal installation). is connected to the engine 12 in front of the engine 12 so that its rotational axis is along a direction substantially perpendicular to the crankshaft 24 (vertically placed). Further, the engine 12 is mounted such that the axis of each cylinder is inclined forward at 45 degrees with respect to the horizontal axis of the vehicle body 10, thereby reducing the overall height of the engine 12 and reducing the overall height of the power plant 23. The center of gravity is lowered.

[0011] Also, the crankshaft 2 of the engine 12
A bevel gear 26 is coaxially attached to the crankshaft 4 for transmitting the rotational force in a direction substantially perpendicular to the crankshaft 24. This bevel gear 26 is connected to the crankshaft 24
The crankshaft 24 is mounted approximately at the center in the axial direction of the cylinder, that is, at a position corresponding to the space 60 formed between the second and third cylinders, and the crankshaft 24 is mounted on both sides to which the bevel gears 26 are mounted. The journal portions 24c and 24d are
It is supported by bearings 64c and 64d attached to the partition wall 27c of the cylinder and the partition wall 27d of the third cylinder, respectively (see FIG. 2).

On the other hand, the bevel gear 26 is meshed with a bevel gear 28 having a rotation axis perpendicular to the bevel gear 26 and along the horizontal axis of the vehicle body 10. The shaft 30 is connected to a support disk 34 that constitutes a clutch 32. The clutch 32 includes this support disk 34, a clutch disk 36 provided opposite to this, and this clutch disk 3.
6 and a pressure plate 38 for pressing the support disk 34 in a known manner. The input shaft 40 of the transmission 22 is attached to the clutch disc 36.
is connected, therefore, the clutch disc 36 is
Support disk 34 by pressure plate 38
When pressed, the rotational force of the crankshaft 24, that is, the power of the engine 10, is transmitted to the transmission 22 via the bevel gears 26, 28, the output shaft 30, the clutch 32, and the input shaft 40 in this order.

The transmission 22 has an input shaft 40 and an output shaft 42, which are parallel to each other and extend parallel to the horizontal axis of the vehicle body 10. A transmission gear is connected between the input shaft 40 and the output shaft 42. A column 44 is arranged. When any one set of gears in the transmission gear train 44 is selected to mesh inside the transmission 22, the power of the engine 10 input from the input shaft 40 is transmitted to that set of gears. Output shaft 4 through
2.

A gear 4 is attached to one end of the output shaft 42 of the transmission 22.
6 are coaxially provided, and the power output from this gear 46 is transmitted to a planetary gear type center differential 4.
8, it is divided into one for the front wheels and one for the rear wheels. The power for the front wheels is generated by the meshing of a pair of bevel gears 50 and 52 and the axle 53.
The power is then transmitted to a bevel gear type front differential (not shown) via the front differential, which then divides the power into left and right front drive shafts and transmits it to the left and right front wheels. Further, the power for the rear wheels is transmitted to a rear differential (not shown) at the rear of the vehicle body through the meshing of the pair of spur gears 54 and 56 and the propeller shaft 58 in sequence. In the first embodiment, it is assumed that the rotational direction of the axle 53 and the rotational direction of the left and right front drive shafts directly connected to the left and right front wheels, respectively, are the same direction.

Next, FIG. 2 is a cross-sectional view of the engine 12 taken along the line AA when viewed from the rear of the vehicle body. First, the cylinders are arranged in the cylinder block 27 in the order of the first cylinder 62a, the second cylinder 62b, the third cylinder 62c, and the fourth cylinder 62d from the left side in the figure. As mentioned above, the crankshaft 24 is
It is arranged laterally with respect to the vehicle body 10, and each journal part 24a-24f is supported by journal bearing 64a-64f provided in the partition wall 27a-27f between each cylinder of the cylinder block 27, respectively. A substantially central portion of the cylinder block 27 in the axial direction of the crankshaft 24;
That is, the partition wall 27c of the second cylinder and the partition wall 27 of the third cylinder
A space 60 in which a gear for extracting the power of the engine 12 is housed is formed between the space 60 and the space 60. As described above, the bevel gear 26 is coaxially provided in the portion of the crankshaft 24 located within the space 60. A bevel gear 28 that enters the cylinder block from the front of the space 60 is meshed orthogonally with this bevel gear 26, and the power of the engine 12 is taken out to the transmission 22 according to the path described above. It will be done.

On the other hand, both ends of the crankshaft 24 are
Pulleys 66a and 66b, which protrude from both sides of the cylinder block 27 and have substantially the same weight and moment of inertia, are attached to the tips of each of the pulleys 66a and 66b, which also serve as flywheels. In addition, auxiliary machines 68a and 68b are arranged at the rear upper part of the cylinder block 27, that is, on the opposite side of each cylinder from the transmission (see FIG. 3).
Each of the above pulleys 66a, 66b and these auxiliary machines 6
Pulleys 70a and 70 provided at 8a and 68b, respectively
Belts 72a and 72b are wound between the parts b. Therefore, when the engine 12 is started and the crankshaft 24 rotates, the auxiliary machines 68a, 68b
is being driven.

[0017] For example, in a conventional type of engine in which the engine is installed vertically and power is taken out from one end of the crankshaft to the transmission side, a flywheel is installed only on the side from which the power of the crankshaft is taken out. is provided. As a result, the end of the crankshaft on the side where the flywheel is installed wobbles relative to the opposite end due to the weight of the flywheel, causing undesirable vibrations in the crankshaft and the engine as a whole. There is a problem of causing However, in this first embodiment, as described above, there is a pulley 66 on both sides of the crankshaft 24 which also serves as a flywheel and has approximately equal weight and approximately equal moment of inertia.
Since the pulleys 66a and 66b are attached respectively, the balance on both sides of the crankshaft 24 is maintained, and even if whirling occurs, the central part between the two pulleys 66a and 66b, that is, the axial center of the crankshaft 24, is maintained. We will be rotating around the club. Therefore, the amplitude of the whirling is
Since both ends of the crankshaft 24 are approximately equal and averaged, as a result, the amplitude of the whirling can be suppressed to a small level compared to the conventional type of engine described above.
Vibrations of the crankshaft 24 and the engine 12 as a whole can be suppressed.

Next, the relationship between the pair of bevel gears 26 and 28 for extracting power from the engine 12 will be described. The number of teeth and the outer diameter of the bevel gear 26 provided on the crankshaft 24 are equal to It is set larger than the outer diameter of the bevel gear 28 that transmits power to the transmission 22 side. There are three reasons for this: (1) As is well known, there is a relationship between horsepower, transmitted torque, and rotation speed: horsepower ∝ torque x rotation speed. Therefore, when trying to transmit the same horsepower, the number of teeth of the bevel gear 28 on the side that transmits power to the transmission 22 is made smaller than the number of teeth of the bevel gear 26 on the crankshaft 24 side. By increasing the rotational speed of the output shaft 30, which is the rotational shaft on the transmission 22 side, higher than the rotational speed, the torque transmitted from the engine 12 to the transmission 22 side can be reduced. By reducing the transmitted torque in this way, even if the same horsepower is transmitted, the gears and rotating shaft diameters that make up each part of the transmission 22 can be made smaller, and the transmission 22 can be made smaller. It becomes possible. (2) By increasing the outer diameter of the bevel gear 26 on the crankshaft 24 side, this bevel gear 26 plays the role of a flywheel, and the flywheel effect of the pulleys 66a and 66b provided outside the cylinder block 27 is reduced. You can make up for it. Furthermore, in order to obtain the same flywheel effect, the outer diameter of the external pulleys 66a, 66b can be made smaller compared to the case where only the external pulleys 66a, 66b are used as flywheels, and the space around the engine 12 can be reduced. You can save money. (3) By reducing the outer diameter of the bevel gear 28, the second
Since the width of the space 60 between the cylinder partition wall 27c and the third cylinder partition wall 27d can be narrowed, the engine 12
The axial length of the crankshaft 24 can be reduced.

As described above, by making the number of teeth and the outer diameter of the bevel gear 26 larger than those of the bevel gear 28, there is an effect that the engine 12 and the transmission 22 can be made smaller in many respects. Next, FIG. 3 is a diagram showing the arrangement of auxiliary machines to the engine 12. As mentioned above, auxiliary equipment 6
8a is provided on the opposite side of the transmission 22 across each cylinder 62a to 62d of the engine 12. A belt 72a is stretched between a pulley 66a that also serves as a flywheel provided at one end of the crankshaft 24 and a pulley 70a provided on an auxiliary machine 68a. is driven by the rotation of the Although not shown, the engine 12
An auxiliary machine 68b is arranged on the opposite side of the engine 12 at a substantially symmetrical position with respect to the center line in the left-right direction of the engine 12.
Similarly, a belt 72 is placed between the pulleys 66b provided at the
b is crossed.

Here, it is assumed that the crankshaft 24 rotates in a clockwise direction in the figure. At this time, when the piston 61a of the first cylinder 62a enters the explosion stroke from the compression stroke and attempts to rotate the crankshaft 24 in the clockwise direction as shown in FIG.
A force P as shown in the figure is applied from the connecting rod 63a along the axial direction of the connecting rod 63a. Therefore, the crankshaft 24 has a
The component force Pθ that tries to rotate 4 and the component force Pr that tries to push it down in the figure are added impulsively, and this component force P
r, the journal portion 24a of the crankshaft 24
-24f are pressed against the inner surfaces of journal bearings 64a-64f. As a result, the journal bearings 64a to 6
The inner circumferential lower surface of 4f receives the impact force from the crankshaft 24 and is connected to the crankshaft 24 and the journal bearing 64a.
A metal hitting sound of ~64f is generated, and the crankshaft 24 itself vibrates.

Therefore, in the first embodiment, as described above, the belts 72a and 72b for driving the auxiliary machines 68a and 68b, respectively, are tilted at a predetermined angle as shown in the figure with respect to each cylinder 62a to 62d. The belt tension pulls the crankshaft 24 upward in a direction that cancels out the component force Pr (in a direction that pulls up the crankshaft 24).
It seems to be energizing. In this way, the occurrence of the above-mentioned metal tapping sound and the vibration of the crankshaft 24 itself can be alleviated.

Furthermore, in the first embodiment, since the transmission 22 is disposed in front of the engine 12, when no auxiliary equipment is installed, the power plant 23 connecting the engine 12 and the transmission 22 The position of the center of gravity G is located quite close to the transmission 22 side (front side) in the longitudinal direction of the vehicle body. On the other hand, the auxiliary machinery is connected to each cylinder 62a~
By arranging the cylinders 62a to 62d on the opposite side of the transmission 22, the center of gravity G of the power plant 23 is moved to the rear, and each cylinder 62a to 62d excites rigid body vibration of the power plant 23. It can be brought close to the point of action of the reaction force of the explosion, thereby suppressing diagonal rigid body vibration of the power plant 23. The effect of suppressing diagonal rigid body vibration of the power plant 23 will be described later.

Furthermore, as mentioned above, the crankshaft 2
4 rotates in the clockwise direction in FIG. 3, and the axle 53 and left and right front drive shafts directly connected to the left and right front wheels, respectively, rotate in the counterclockwise direction in the forward running mode. That is, the crankshaft 24 and the left and right drive shafts rotate in opposite directions. Here, when the crankshaft 24 rotates, the power plant 23 receives a rotational moment around the crankshaft 24 in a direction opposite to the rotational direction of the crankshaft 24 due to the reaction force. Further, the power plant 23 receives a rotational moment around the axle 53 in a direction opposite to the rotational direction of the axle 53 due to the reaction force of the torque that rotates the axle 53 . Therefore, when the rotation direction of the crankshaft 24 and the rotation direction of the axle shaft 53 are set in the same direction, the power plant 23 receives a moment trying to rotate in the same direction due to reaction forces around the respective axes. It turns out. On the other hand, as in the first embodiment, the crankshaft 2
If the rotational direction of 4 and the rotational direction of the axle shaft 53 are reversed, the rotational moments due to reaction forces around the respective axes will be in opposite directions, so that the respective rotational moments will cancel each other out. Therefore, as a result, the power plant 23
The excitation force applied to the power plant 23 is weakened, and vibrations of the power plant 23 can be suppressed.

Next, FIG. 5 is a plan view of the power plant 23 viewed from above. As described above, the power plant 23 is attached to the vehicle body 10 at two locations: one location below the transmission 22 at approximately the center in the vehicle width direction, and one location at both ends of the rear end of the engine 12 in the vehicle width direction. It is supported by engine mounts 13, 15A, and 15B (three-point support). In addition, the position of the center of gravity G of the power plant 23 is set approximately at the center of the first cylinder and the fourth cylinder in the vehicle width direction, and at each of the first to fourth cylinders in the longitudinal direction of the vehicle body. On the straight line connecting the points of action of the reaction force caused by the explosion (if the cylinder is placed vertically upward,
On the straight line i connecting S1, S2, S3, S4, but the first
In this example, since the cylinder is tilted forward, it is on the straight line j connecting S1', S2', S3', and S4')
is set as close as possible to .

Now, in order to clarify the relationship between the position of the center of gravity G and the rigid body vibration of the power plant 23, the excitation force acting on the power plant 23 will be explained. First, in the low rotation range of the engine 12, the excitation force acting on the power plant 23 is mainly a torque fluctuation component,
It can be broadly divided into the following two types. One is the reaction force generated by rotating the pulleys 66a and 66b, which are provided on the crankshaft 24 and also serve as flywheels. is subjected to an excitation force as a rotational moment. The other force comes from a reaction force due to fluctuations in the rotational torque of the axle 53, and the power plant 23 receives an excitation force as a rotational moment about the axle 53. Since the engine 12 is installed horizontally, the above-mentioned excitation force around the crankshaft 24 and excitation force around the axle 53 cause rotational vibration (so-called pitching vibration) of the power plant 23 in the longitudinal direction.
The excitation force is such that it causes Therefore, in the low rotation range, the power plant 23 tends to undergo pitching vibration in response to the two types of excitation forces in the longitudinal direction described above. This pitching vibration is absorbed by the engine mounts 13, 15A, and 15B provided in the front-rear direction of the power plant 23. Moreover, the position of the center of gravity G of the power plant 23 in the longitudinal direction at this time is the front and rear engine mounts 13 and 15A.
, 15B and the balance of vibration amplitudes at the front end and rear end of the power plant 23, the front engine mount 13 and the rear engine mount 1
It is thought that a position near the center between 5A and 15B, or a little further back than that is desirable. In addition, regarding only the above excitation force, the position of the center of gravity G in the vehicle width direction is as follows:
It is thought that there will be no significant impact anywhere.

Next, during high-speed rotation, the piston 6
The connecting rods 1a to 61d and the connecting rods 63a to 63d move up and down with high acceleration, and the crankshaft 24 and the pulleys 66a and 66b attached thereto also rotate with high angular acceleration. On the other hand, in the explosion process,
Pistons 61a to 61d and connecting rods 63a to 63d
reaction force F1 to F4, which is the sum of the reaction force that causes downward acceleration in the mass of the crankshaft 24 and the reaction force that causes angular acceleration to the moment of inertia of the crankshaft 24 and its attached pulleys 66a, 66b, etc. are installed on the ceiling surface of the combustion chamber of the cylinder head for each cylinder 62a to 62d.
is thought to act upward along the central axis of . That is, as shown in FIG. 4, reaction forces F1 to F4 act in diagonal directions at points S1' to S4'. And these reaction forces F
1 to F4 increase in proportion to the acceleration and angular acceleration, and as the rotation speed of the engine 12 increases, the acceleration of the pistons 61a to 61d and the angular acceleration of the crankshaft 24 increase as described above. Therefore, in addition to the torque fluctuation component described above, the excitation force due to these reaction forces cannot be ignored. However, the reaction force that causes angular acceleration in the crankshaft 24 and pulleys 66a, 66b is
This occurs when the angular velocity is changed during acceleration or deceleration, so when running at a constant speed at high revolutions, the pistons 61a to 61d and connecting rod 63 are
It is considered that the reaction force that causes acceleration at points a to 63d is dominant.

Rigid body vibration of the power plant 23 due to the positional relationship between the center of gravity G and the point of application of the excitation force when the above-mentioned excitation force is applied will be explained. First, to simplify the explanation, a case will be described in which the cylinders 62a to 62d are not inclined as in the first embodiment, but are oriented vertically upward. In this case, each cylinder 62a-6
The points of action of the reaction force 2d are directly above the crankshaft 24, and are at positions S1, S2, S3, and S4 in the figure. In addition, the engine 12 includes a first cylinder 6 from the bottom in the figure.
2a, second cylinder 62b, third cylinder 62c, fourth cylinder 62
Each cylinder is lined up in the order of d, and the firing order is 1-3.
-4-2.

First, when the first cylinder 62a enters the explosion stroke, a reaction force F1 acts vertically upward (direction perpendicular to the paper) at the position indicated by point S1, and the power plant 23 receives the excitation force. It moves in a rotational manner around the instantaneous center Q1 that occurs on the straight line e connecting the point of action S1 and the center of gravity G. Next, when the third cylinder 62c enters the explosion stroke, a reaction force F3 acts vertically upward at the position indicated by point S3, and the power plant 23 It rotates around the instantaneous center Q3 that occurs above. Similarly, when the fourth cylinder 62d explodes, the reaction force F4 acts on the point S4, and an instantaneous center Q4 is created on the straight line h connecting the point S4 and the center of gravity G. When the second cylinder 62b explodes, the instantaneous center Q4 is generated at the point S2. A reaction force F2 acts on the point S2, and an instantaneous center Q2 is generated on the straight line f connecting the point S2 and the center of gravity G. Therefore, in the power plant 23, as the cylinders 62a to 62d explode, the straight lines e, f, g, h, respectively, are adjusted to the instantaneous centers Q1 to Q on each straight line.
4, it vibrates as if rotating in the vertical direction (perpendicular to the page). In other words, the power plant 23 vibrates in an oblique direction.

However, when the power plant 23 is supported at three points as shown in the figure, it is not preferable that an excitation force that actively excites vibrations in the diagonal direction as described above be applied. One way to solve this problem is to use a straight line i connecting the points of action S1 to S4 of the reaction forces F1 to F4.
A possible method is to arrange the center of gravity G at a position as close to the top as possible so that the straight lines e to h connecting the center of gravity G and each of the points of action S1 to S4 of the reaction force are not inclined with respect to the straight line i. Moreover, on the straight line connecting the points of action S1 to S4 of the reaction force in this way,
If the position of the center of gravity G is brought closer, the distance between the points of action S1 to S4 of the reaction force and the center of gravity G becomes closer, so the rotational moment around the center of gravity G caused by the reaction force can also be reduced at the same time, reducing double vibration. Produces a suppressive effect.

However, for the engine 12, the transmission 22
If the crankshaft 24 is mounted at the front, it is quite difficult to bring the center of gravity G directly above the crankshaft 24. Therefore, in the first embodiment, each cylinder 62a
62d forward, the point of application of the reaction force is moved forward of the power plant 23, as shown in FIG. 4, and the center of gravity G
is set close to the straight line j connecting the points of action S1' to S4' of this reaction force. That is, in the first embodiment, by tilting the cylinder forward, the power plant 23 is made more compact and the center of gravity is lowered, and the center of gravity G is placed on the straight line j connecting the application points S1' to S4' of the excitation force. At the same time, it is possible to bring the positions closer together.

Next, the position of the center of gravity G in the vehicle width direction will be explained again, returning to the case where the cylinder faces vertically upward. Due to the explosion of each cylinder 62a to 62d, the above-mentioned reaction forces are generated in S1, S3, S4, and S2, respectively.
Even if the center of gravity G is on the straight line i, for example, the power plant 23 is always affected by the vehicle body 10.
A moment is applied to cause vibration in the left-right direction (pitching vibration). This moment is determined by the product of the distance between the center of gravity G and each of the points of action S1 to S4 of the reaction force, and the magnitude of the reaction force. It is considered that the reaction forces due to the explosion of each cylinder 62a to 62d acting on points S1, S2, S3, and S4 are approximately equal. Therefore, the moment that causes the power plant 23 to vibrate in the left-right direction is determined only by the distance between the point of application of the reaction force and the center of gravity G. Therefore, in order to balance the vibration amplitude at both ends of the power plant 23 in the left and right direction, the position of the center of gravity G must be changed to point S1.
It is desirable to set it at the center between and point S4 (also at the center between point S2 and point S3). Therefore, in the first embodiment, the horizontal position of the center of gravity G of the power plant 23 is set to approximately the center between the first cylinder 62a and the fourth cylinder 62d (the center between points S1' and S4'). are doing.

In this way, the position of the center of gravity G is set in the vicinity of the straight line j connecting the points of application of the reaction force in the longitudinal direction of the vehicle body 10, and in the vicinity of the straight line j connecting the points of application of the reaction force in the vehicle width direction.
By setting it in the center between the cylinders 62d, each cylinder 6
Due to the reaction force of the explosion at 2a to 62d, the engine 12
Even if a vertical excitation force is generated against the power plant 23, the left and right vibration amplitudes of the power plant 23 can be made approximately the same to balance the movement, and the power plant 23
As a result, the power plant 23 can be supported at three points as shown in the figure.

Next, FIG. 6 is a cross-sectional view of a power plant to which the engine structure of the second embodiment is applied, viewed from the side of the vehicle body, and FIG. 7 is a sectional view of the power extraction section of this second embodiment. FIG. The configuration of the second embodiment will be described based on FIGS. 6 and 7. In the second embodiment, as shown in FIGS. 6 and 7, a spur gear 90 is attached to the portion of the crankshaft 24 where the bevel gear 26 is attached in the first embodiment. Specifically, a spur gear 90 is coaxially attached to a portion of the crankshaft 24 sandwiched between the side wall 27c of the second cylinder and the side wall 27d of the third cylinder. gear 92
are meshing. The intermediate gear 92 has a central shaft 94 rotatably supported by a bearing 96 fixed to the cylinder block 27, and one end of the central shaft 94 has a
A bevel gear 98 is coaxially attached. This bevel gear 9
8 is meshed with a bevel gear 100 connected to the support disc 34 of the clutch 32. Therefore, the rotational force of the crankshaft 24 is transmitted to the central shaft 94 by the spur gear 90 and the intermediate gear 92. This rotation is further transmitted to the support disk 34 of the clutch 32 through the meshing of the pair of bevel gears 98 and 100. When the clutch is engaged, the rotational force of the crankshaft 24 is transmitted to the transmission 22. The other configurations and operations are exactly the same as in the first embodiment.

[0034] Also in this second embodiment, the first
As in the case of the above embodiment, by making the outer diameter of the spur gear 90 larger than the outer diameter of the intermediate gear 92, the spur gear 90 serves as a flywheel for the crankshaft 24. At the same time, since the rotational torque transmitted to the transmission 22 can be reduced, the diameters of the gears and rotating shafts of various parts of the transmission 22 can be reduced, and the entire power plant 23 can be downsized. be able to. Also, the first
In this embodiment, the distance between the partition wall 27c of the second cylinder and the partition wall 27d of the third cylinder is smaller than the diameter of the bevel gear 28 because the bevel gear 28 enters the space 60 between these partition walls. It is also necessary to make it large. On the other hand, in the second embodiment, as shown in FIG. 7, the distance between the partition walls 27c and 27d should be at least the thickness of the spur gear 90 plus some margin. Therefore, the distance between the space 60 between the second cylinder and the third cylinder can be narrowed, so that the size of the engine 12 in the direction of the crankshaft 24 can be reduced.

Next, FIGS. 8 and 9 are cross-sectional views showing a third embodiment. In this third embodiment, the space 60 between the second and third cylinders into which the bevel gear enters is utilized to
In this space 60, parallel to the crankshaft 24, two
Book balance shafts 102 and 103 are arranged. Specifically, the partition wall 27c of the second cylinder and the partition wall 27 of the third cylinder
d, two bearings 104 and 106 are arranged, and between the two pairs of bearings 104 and 106, balance shafts 102 and 103 are respectively parallel to the crankshaft 24. Rotatably supported. Gears 102a and 103a are integrally formed on the balance shafts 102 and 103, respectively. Of these, the gear 102a is connected to a gear 112 fixed to the crankshaft 24 through the meshing of intermediate gears 108 and 110. Rotationally driven. Moreover, the gear 103a is
It is rotationally driven by a gear 112 via an intermediate gear 110. Then, the number of teeth of the gear 112 and the intermediate gears 108, 11
0 has the same number of teeth, and the intermediate gears 108 and 11
The number of teeth at 0 is twice the number of teeth on gears 102a and 103a, so when crankshaft 24 rotates, balance shaft 102 rotates at twice the speed of crankshaft 24 in the same direction as crankshaft 24. , the balance shaft 103 rotates at twice the speed of the crankshaft 24 and in the opposite direction. Balance shaft 102, 103
has an amount of unbalance corresponding to the amount of unbalance around the rotation axis of the crankshaft 24, so that the secondary vibration of the crankshaft 24 can be reduced by a known action.

Next, FIG. 10 is a sectional view showing the fourth embodiment, and FIG. 11 is a sectional view taken along line BB in FIG. In the fourth embodiment, the counterweight portion 67b of the crankshaft 24 corresponds to the second cylinder 62b.
A bevel gear 120 is formed on the outer periphery of the partition wall 2 of the second cylinder.
A hole 122 is made in 7c, and a bevel gear 28 that meshes with this bevel gear 120 is inserted into the hole 122. By doing this, the partition wall 27c of the second cylinder and the partition wall 27d of the third cylinder
Since the space between the two parts can be narrowed, the size of the crankshaft 24 of the engine 12 can be reduced in the axial direction.

Furthermore, in the first embodiment, the bevel gear 2
6 is used as a flywheel as is, but bevel gear 26
A flywheel may be added to the outer periphery of the portion where the teeth are formed. With this configuration, the outer diameter of the flywheel can be freely determined without being influenced by the ratio of the number of teeth between the pair of bevel gears 26 and 28. Not only can the effect be increased, but also the degree of freedom in determining the size of the flywheel effect is improved.

Further, in the above embodiment, a space 60 is always formed between the partition wall 27c of the second cylinder and the partition wall 27d of the third cylinder. may be arranged. In this way, the surge tank, which was conventionally disposed outside the engine block, can be housed inside the cylinder block 27. Therefore, even if the engine 24 becomes slightly longer in the direction of the crankshaft 24 due to the space 60 created between the second and third cylinders, the engine 1
Since the space for the external surge tank 2 can be conversely reduced, the total space for the engine 12 can be prevented from increasing.

Furthermore, for the same reason as above, the space 60
An oil pump may be placed at the In addition, the intake pipe is normally provided with a resonator in order to attenuate the sound caused by air resonance within the intake pipe, but this resonator is arranged using the space between the transmission 22 and the cylinder. It's okay.

In the above embodiment, two pulleys 6 fixed to the crankshaft 24 are used to drive the auxiliary equipment.
6a, 66b and pulleys 72a, 72b provided in auxiliary machines 68a, 68b are connected by belts,
Gears may be provided on the crankshaft 24 instead of the pulleys 72a and 72b, and gears that mesh with these may be provided on the auxiliary machines 68a and 68b, so that the driving force is transmitted by the gears. In this way, the crankshaft 24
Since the diameter of the side gear can be made larger, the effect as a flywheel can be enhanced more than using a pulley.

It should be noted that the present invention can be applied to modifications or variations of the above embodiments without departing from the spirit thereof. For example, in the above embodiment, a four-cylinder engine has been described, but it goes without saying that the invention may be applied to an engine with a larger number of cylinders. Also, Figure 1
2, the engine 12 is installed vertically, and the transmission 2
Engine mount 130, 132A with 2 installed horizontally,
132B may support a power plant. With this arrangement, the center of gravity G of the power plant is located behind the axle 53, so that running stability is improved. Note that 134 is a front differential.

[0042]

As explained above, according to the power plant and its mounting structure of the present invention, it is possible to balance the amplitude of the end of the power plant due to rotational movement around the center of gravity of the power plant, and Since it is possible to suppress the excitation force that tilts the power plant in an oblique direction,
This has the effect of suppressing the complex rigid body vibrations of the power plant and improving ride comfort.

[0043] Furthermore, since the power plant's self-excited rigid body vibration is suppressed, supporting the power plant at three points has the effect of improving the degree of freedom in arranging the engine mount.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a power plant according to a first embodiment of the present invention, viewed from the side.

FIG. 2 is a sectional view taken along line AA in FIG. 1;

FIG. 3 is a diagram showing the arrangement of auxiliary machinery on the engine.

FIG. 4 is a diagram showing the force applied to the crankshaft.

FIG. 5 is a plan view of the power plant seen from above.

FIG. 6 is a cross-sectional view of the power plant of the second embodiment, viewed from the side of the vehicle body.

FIG. 7 is a partial cross-sectional view of the output extraction section of the second embodiment.

FIG. 8 is a sectional view showing a third embodiment.

FIG. 9 is a sectional view showing a third embodiment.

FIG. 10 is a sectional view showing a fourth embodiment.

FIG. 11 is a sectional view taken along line BB in FIG. 10;

FIG. 12 is a diagram showing a modification in which the engine is arranged vertically.

[Explanation of symbols]

10 Vehicle body 12 Engine 13
Engine mount 15A, 15B Engine mount 18 Dash panel 20
radiator 22
Transmission 23 Power plant 24
crankshaft 32
clutch 53
Axle 66a, 66b Pulley 68a, 68b Auxiliary equipment 102, 103 Balance shaft

Claims (3)

[Claims] Claims: 1. An engine having a plurality of cylinders and extracting rotational force of a crankshaft from between two predetermined cylinders; The power plant is connected to a transmission arranged in the direction, the center of gravity of which is set near the center between the cylinders located at both ends with respect to the direction in which the crankshaft extends, and A power plant characterized in that, in a direction perpendicular to the direction in which the shaft extends, the reaction force of the explosion in each cylinder is set near a straight line connecting points of action that act on the engine. 2. The engine is disposed laterally with respect to the vehicle body, and the rotational direction of the crankshaft and the rotational direction of a drive shaft for rotationally driving the front wheels are
The power plant according to claim 1, characterized in that the power plant is oriented in the opposite direction. 3. One engine mount supporting the transmission and two engine mounts supporting the engine are arranged so as to surround the center of gravity of the power plant according to claim 1, and the power plant is A power plant mounting structure characterized by three-point support using engine mounts.