JP2019127913A - Internal combustion engine of vehicle - Google Patents

Abstract

To properly suppress the vibration of a surge tank by a dynamic damper while supporting the dynamic damper by using a member having sufficient rigidity.SOLUTION: An internal combustion engine of a vehicle comprises a bracket 60 for connecting a surge tank 56 and a second cylinder head 26 to each other. A first fixing part 71 of a support member 70 is fixed to the bracket 60. A second fixing part 73 of the support member 70 is fixed to the surge tank 56. A dynamic damper 80 for suppressing the vibration of the surge tank 56 is fixed to the surge tank 56 side rather than a fixing position fixed to the bracket 60 in the support member 70. A material of the support member 70 is higher than a material of the surge tank 56 in rigidity. When setting a direction of the vibration which is vibration-controlled by the dynamic damper 80 as a vibration control direction, the bending rigidity of the support member 70 in the vibration control direction is lower than the bending rigidity of the bracket 60 in the vibration control direction.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an internal combustion engine of a vehicle.

  The internal combustion engine of Patent Document 1 includes a cylinder block in which a plurality of cylinders are partitioned, and a cylinder head fixed to the upper end surface of the cylinder block. Inside the cylinder head, a plurality of intake ports are defined for guiding intake air to each cylinder of the cylinder block. An intake manifold is connected to each intake port of the cylinder head. In addition, a surge tank for temporarily storing intake air is connected to the intake manifold.

  A plate-like support plate is fixed to the surge tank in the internal combustion engine of Patent Document 1. The support plate is fixed to one end of the bracket. The other end of the bracket is fixed to the cylinder block. That is, the surge tank is supported by the bracket and the support plate.

JP-A-7-332182

  In the internal combustion engine disclosed in Patent Document 1, the surge tank may vibrate due to vibration accompanying combustion of fuel in the cylinder or movement of the vehicle. Therefore, it is conceivable to attach a dynamic damper for suppressing the vibration of the surge tank.

  Here, in the internal combustion engine of Patent Document 1, it is assumed that a dynamic damper is directly attached to the surge tank. In this case, since the dynamic damper is supported by the surge tank, the size and weight of the dynamic damper are limited according to the rigidity of the surge tank. As a result, a dynamic damper having desired vibration damping characteristics may not be attached. On the other hand, in the internal combustion engine of Patent Document 1, it is assumed that a dynamic damper is temporarily attached to a bracket or the like. In this case, since the bracket has high rigidity, the bracket does not vibrate so much even if the surge tank vibrates. As a result, the vibration of the surge tank is not easily transmitted to the dynamic damper through the bracket, and the vibration damping effect of the dynamic damper may not be sufficiently exhibited.

  As described above, when applying a dynamic damper to an internal combustion engine as disclosed in Patent Document 1, a structure is required that can appropriately suppress the vibration of the surge tank by the dynamic damper while supporting the dynamic damper with a sufficiently rigid member. .

  An internal combustion engine of a vehicle for solving the above problems includes a cylinder block having a plurality of cylinders defined therein, and a plurality of intake ports fixed to an upper end surface of the cylinder block and connected to the plurality of cylinders. A cylinder head partitioned inside, an intake manifold connected to the plurality of intake ports, a surge tank connected to the intake manifold and for temporarily storing intake air, and the cylinder An internal combustion engine comprising a bracket connected to at least one of the block and the cylinder head, and a dynamic damper for suppressing vibration of the surge tank, a support member extending from the bracket, The support member is fixed to the surge tank, and the support member The quality is a material whose rigidity is higher than the material of the surge tank, and when the direction of vibration that can be damped by the dynamic damper is a damping direction, the bending stiffness of the support member in the damping direction is It is lower than the bending rigidity of the bracket in the vibration direction, and the dynamic damper is fixed to the surge tank side with respect to the fixing position of the support member with the bracket.

  In the above configuration, the surge tank is appropriately supported by the bracket. Further, in the above configuration, the dynamic damper is fixed to the support member having a bending rigidity lower than that of the bracket. Therefore, the support member is easier to vibrate than the bracket in the vibration damping direction of the dynamic damper. And since a dynamic damper vibrates with a supporting member, the damping effect of a surge tank can be exhibited appropriately. Further, the material of the support member is a material having rigidity higher than that of the surge tank. Therefore, the weight and the like of the dynamic damper are less likely to be limited than when the dynamic damper is directly attached to the surge tank.

  In a state where the internal combustion engine having the above configuration is mounted on a vehicle, the vibration damping direction of the dynamic damper is a direction that can suppress vibration in the front-rear direction of the vehicle, and the support member and the surge tank are fixed to each other. The position may be located closer to the center of gravity of the surge tank in the vehicle width direction than the fixed position between the bracket and the surge tank.

  In a vehicle, a change in acceleration in the longitudinal direction of the vehicle generally tends to occur. As the acceleration in the longitudinal direction of the vehicle changes, the acceleration in the longitudinal direction of the vehicle also acts on the surge tank, so that the vibration in the longitudinal direction of the vehicle is likely to occur in the surge tank. In the above configuration, for example, when the vibration in the front-rear direction of the vehicle is generated in the surge tank, the vibration of the surge tank is supported by the support member when compared with the configuration in which the support member is fixed to one end of the surge tank in the vehicle width direction. Is easily transmitted to the dynamic damper. As a result, the vibration damping effect in the longitudinal direction of the vehicle in the surge tank by the dynamic damper can easily reach the entire surge tank. As a result, in the above configuration, the vibration in the front-rear direction of the vehicle in the surge tank can be appropriately suppressed by the dynamic damper.

  The surge tank is located above the cylinder block in the vertical direction of the vehicle in the above configuration, and the dynamic damper is located behind the surge tank in the longitudinal direction of the vehicle. Good.

  In a vehicle, generally, acceleration (deceleration) at the time of sudden deceleration tends to be larger than acceleration at the time of sudden acceleration. In addition, the speed at which the vehicle travels forward tends to be greater than the speed at which the vehicle travels backward. Therefore, when the vehicle is moving forward and a rapid deceleration occurs, a large inertial force toward the vehicle front may act on the dynamic damper. If the dynamic damper is attached only to a relatively weak surge tank, the fixed position of the surge tank with the dynamic damper may be damaged and the dynamic damper may fall off. If the dynamic damper is positioned rearward of the main body of the surge tank as in the above configuration, the dropped dynamic damper may blow forward to contact other parts. In such a configuration, fixing the dynamic damper to a support member of a material having a rigidity higher than that of the material of the surge tank is extremely effective in suppressing the above-described dropout of the dynamic damper and contact with other parts. It is

In the above configuration, the dynamic damper may be fixed at a fixed position between the support member and the surge tank.
In the above configuration, the dynamic damper is fixed at the position where the vibration of the surge tank is most easily transmitted in the support member. Thereby, the vibration damping effect of the dynamic damper can be maximized.

The front view which looked at an internal combustion engine from the front side of vehicles. The rear view which looked at an internal combustion engine from the back side of vehicles. The enlarged view of the internal combustion engine shown in FIG. Sectional drawing in line 4-4 in FIG.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. First, a schematic configuration of a V-type internal combustion engine 100 to which the present invention is applied will be described. In the following description, the internal combustion engine 100 is assumed to be mounted on a vehicle, and description will be made with reference to the front, rear, left, and right of the vehicle.

  As shown in FIG. 1, the internal combustion engine 100 includes a cylinder block 10 that is V-shaped as a whole when viewed from the front side of the vehicle. At an upper portion of the V-shape in the cylinder block 10, a plurality of cylinders 11 are defined therein. Three cylinders 11 </ b> R are defined in the bank (one side of the V-shape) on one side of the cylinder block 10. The three cylinders 11R are located on the right side (left side in FIG. 1) of the vehicle with respect to the crank journal 43c, which is the rotation center of the crankshaft 43. Further, in the bank on the other side of the cylinder block 10, three cylinders 11L are partitioned. The three cylinders 11L are located on the left side (right side in FIG. 1) of the vehicle with respect to the crank journal 43c, which is the rotation center of the crankshaft 43. In FIG. 1, only one of the three cylinders 11R is illustrated, and only one of the three cylinders 11L is illustrated.

  In the lower portion of the V-shape in the cylinder block 10, a storage space 12 connected to six cylinders 11 is defined. A crankshaft 43 is housed in the housing space 12. An oil pan 33 for storing engine oil is fixed to the lower end surface of the cylinder block 10.

  Inside each cylinder 11R in the cylinder block 10, a piston 41 that reciprocates in the cylinder 11R is disposed. The piston 41 is connected to a crankpin 43a in the crankshaft 43 via a connecting rod 42. The crank pin 43a is connected to a crank journal 43c, which is the rotation center of the crankshaft 43, via a crank arm 43b. Similarly, in each cylinder 11L in the cylinder block 10, a piston 41 that reciprocates within the cylinder 11L is arranged. The piston 41 is connected to a crankpin 43a in the crankshaft 43 via a connecting rod 42. The crank pin 43a is connected to a crank journal 43c, which is the rotation center of the crankshaft 43, via a crank arm 43b.

  A first cylinder head 21 is fixed to an upper end surface on the right side (left side in FIG. 1) of the V-shaped cylinder block 10. The combustion chamber 22 is recessed toward the upper side of the lower end surface of the first cylinder head 21 that faces the cylinder 11R. The first cylinder head 21 includes a total of three combustion chambers 22 corresponding to the three cylinders 11R.

  An intake port 23 for introducing intake air from the outside is defined inside the first cylinder head 21. The downstream end of the intake port 23 opens to the combustion chamber 22. That is, the intake port 23 is connected to the cylinder 11R via the combustion chamber 22. The upstream end of the intake port 23 is open at the center side in the vehicle width direction of the first cylinder head 21 (the center side of the V-shape). The first cylinder head 21 includes a total of three intake ports 23 corresponding to the three combustion chambers 22.

  An exhaust port 24 for exhausting the exhaust gas to the outside is defined inside the first cylinder head 21. The upstream end of the exhaust port 24 opens to the combustion chamber 22. The downstream end of the exhaust port 24 opens at the outer side in the vehicle width direction (outside of the V shape) of the first cylinder head 21. The first cylinder head 21 has a total of three exhaust ports 24 corresponding to the three combustion chambers 22.

  A second cylinder head 26 is fixed to the upper end surface of the left side of the vehicle (the right side in FIG. 1) of the V shape in the cylinder block 10. The combustion chamber 27 is recessed toward the upper side of the portion of the lower end surface of the second cylinder head 26 facing the cylinder 11L. The second cylinder head 26 includes a total of three combustion chambers 27 corresponding to the three cylinders 11L.

  An intake port 28 for introducing intake air from the outside is defined inside the second cylinder head 26. The downstream end of the intake port 28 opens into the combustion chamber 27. That is, the intake port 28 is connected to the cylinder 11L via the combustion chamber 27. The upstream end of the intake port 28 is open at the center side in the vehicle width direction (the center side of the V-shape) of the second cylinder head 26. The second cylinder head 26 includes a total of three intake ports 28 corresponding to the three combustion chambers 27.

  An exhaust port 29 for discharging exhaust to the outside is defined inside the second cylinder head 26. The upstream end of the exhaust port 29 is open to the combustion chamber 27. The downstream end of the exhaust port 29 is open on the outer side in the vehicle width direction (outside of the V shape) in the second cylinder head 26. The second cylinder head 26 includes a total of three exhaust ports 29 corresponding to the three combustion chambers 27.

  A first head cover 31 that covers the upper end surface of the first cylinder head 21 is fixed to the upper end surface of the first cylinder head 21. A second head cover 32 that covers the upper end surface of the second cylinder head 26 is fixed to the upper end surface of the second cylinder head 26.

  A connecting body 35 is disposed between the first cylinder head 21 and the second cylinder head 26. The connection body 35 includes three first connection pipes 36 connected to the intake port 23 of the first cylinder head 21 and three second connection pipes 37 connected to the intake port 28 of the second cylinder head 26. It is done. The first connection pipe 36 and the second connection pipe 37 extend apart in the vehicle width direction toward the lower side of the vehicle. In this embodiment, the three first connection pipes 36 and the three second connection pipes 37 are integrally formed to constitute the connection body 35.

  An intake manifold 51 that branches external intake air into a plurality of passages is fixed to the upper end surface (upstream end) of the connection body 35. A part of the upstream side of the intake manifold 51 is a tubular collecting portion 52, and the downstream side of the collecting portion 52 is branched into six branch pipes 53. Three of the six branch pipes 53 are connected to the first connection pipe 36 in the connection body 35, and the other three are connected to the second connection pipe 37 in the connection body 35. The collective portion 52 extends substantially in the vehicle width direction from the branch pipe 53 toward the left side in the vehicle width direction (right side in FIG. 1).

  A main body portion 57 of a surge tank 56 for temporarily storing intake air is connected to the upstream end of the collecting portion 52 in the intake manifold 51. The main body 57 of the surge tank 56 has a cylindrical shape as a whole. In the present embodiment, the surge tank 56 and the intake manifold 51 are integrally formed of a resin material. Further, in the present embodiment, the surge tank 56 is located above the cylinder block 10, the second cylinder head 26, and the second head cover 32 in the vehicle vertical direction.

  A throttle valve mechanism 45 having a throttle valve for controlling the amount of intake air introduced from the outside is connected to the upstream end of the surge tank 56. In FIG. 1, the illustration of the throttle valve disposed inside the throttle valve mechanism 45 is omitted.

  An exhaust pipe 46 for exhausting exhaust to the outside is fixed to the exhaust port 24 of the first cylinder head 21 and the exhaust port 29 of the second cylinder head 26. Although detailed illustration is omitted, three branch pipes are respectively connected to the three exhaust ports 24 of the first cylinder head 21, and these three branch pipes are connected to one first exhaust pipe 46a on the downstream side. It is gathering. Similarly, three branch pipes are connected to the three exhaust ports 29 of the second cylinder head 26, respectively, and these three branch pipes are gathered in one second exhaust pipe 46b on the downstream side. Then, the first exhaust pipe 46a and the second exhaust pipe 46b are gathered on the downstream side to form a collecting exhaust pipe 46c.

Next, the configuration of the surge tank 56 and its peripheral configuration will be specifically described.
As shown in FIG. 1, the main body 57 in the surge tank 56 can be roughly divided into an upstream main body 57a located on the upstream side and a downstream main body 57b located on the downstream side of the upstream main body 57a. . As shown in FIG. 2, the upstream main body portion 57 a extends in the vehicle width direction as a whole behind the connection body 35 and the intake manifold 51. In this embodiment, the upstream side of the upstream side main body portion 57a is the right side of the vehicle, and the downstream side is the left side of the vehicle. From the downstream end of the upstream side main body portion 57a, a downstream side main body portion 57b extends toward the front side of the vehicle. As shown in FIG. 1, the downstream main body 57 b is located on the left side of the vehicle with respect to the intake manifold 51 and above the second head cover 32. That is, the surge tank 56 extends so as to surround the intake manifold 51 from the rear side and the left side of the vehicle. The downstream end of the downstream side main body portion 57 b is connected to the upstream end of the collecting portion 52 in the intake manifold 51.

  As shown in FIG. 4, from the lower surface of the upstream side main body portion 57a in the surge tank 56, a plate-shaped first support plate 58a protrudes toward the lower side of the vehicle. As shown in FIG. 2, the first support plate 58 a is located on the left side of the center in the extension direction of the upstream side main body portion 57 a. In this embodiment, the first support plate 58 a is located behind the second head cover 32 and the second cylinder head 26. As shown in FIG. 3, the surface direction of the first support plate 58a is orthogonal to the longitudinal direction of the vehicle. Plate-shaped first ribs 58c protrude from the edges of the first support plate 58a on both sides in the vehicle width direction toward the rear side of the vehicle. The first rib 58c extends over the entire first support plate 58a in the vehicle vertical direction. A substantially cylindrical first boss 58b protrudes toward the rear of the vehicle from the lower end portion of the first support plate 58a. The rear end surface of the first boss 58b extends to substantially the same position as the rear end of the first rib 58c. Further, the rear end surface of the first boss 58b is at substantially the same position as the rear end surface of the second cylinder head 26 in the vehicle longitudinal direction. A metal insert nut (not shown) is fixed inside the first boss 58b.

  As shown in FIG. 3, a steel bracket 60 that connects the surge tank 56 to the second cylinder head 26 is fixed to the rear end surface of the first boss 58 b in the surge tank 56. The bracket 60 includes a substantially rectangular plate-like connecting plate 61 extending in the vertical direction of the vehicle. The surface direction of the connecting plate 61 is orthogonal to the longitudinal direction of the vehicle. A bolt hole 61 a passes through the connecting plate 61 at the upper end of the vehicle in the thickness direction of the connecting plate 61. Further, at the lower end portion of the vehicle in the connecting plate 61, a bolt hole 61b penetrates in the thickness direction of the connecting plate 61. A first connecting plate 62 having a substantially square plate shape protrudes from the left edge of the vehicle in the connecting plate 61 toward the rear side of the vehicle. The first connection plate 62 extends over the entire connection plate 61 in the vertical direction. Further, a substantially square plate-like second connection plate 63 projects from the right edge of the vehicle in the connecting plate 61 toward the rear side of the vehicle. The second connection plate 63 extends over the entire connection plate 61 in the vertical direction. A substantially square plate-like fixing plate 64 extends from the protruding leading edge (rear edge) of the second connection plate 63 toward the right side of the vehicle. The dimension in the vertical direction of the fixing plate 64 is shorter than the dimension in the vertical direction of the second connection plate 63, and the fixing plate 64 extends from a part of the upper side of the second connection plate 63. The bolt holes 64 a pass through the fixing plate 64 in the thickness direction of the fixing plate 64.

  As shown in FIG. 3, the upper end portion of the bracket 60 is inserted into the bolt hole 61 a of the connection plate 61 and the insert nut of the first boss 58 b of the surge tank 56 so that the first boss of the surge tank 56 is inserted. It is fixed to 58b. In the present embodiment, the contact position between the connection plate 61 in the bracket 60 and the first boss 58 b in the surge tank 56 is the fixed position between the bracket 60 and the surge tank 56.

  The lower end of the bracket 60 is fixed to the second cylinder head 26 by inserting a bolt 93 through the bolt hole 61b of the connecting plate 61 and the screw hole 26a provided at the rear end of the second cylinder head 26. There is.

  As shown in FIG. 4, a plate-shaped second support plate 59 a protrudes from the lower surface of the upstream main body portion 57 a of the surge tank 56 toward the lower side of the vehicle. The second support plate 59a is located rearward of the first boss 58b in the front-rear direction of the vehicle. As shown in FIG. 2, the second support plate 59 a is located on the center side of the upstream main body portion 57 a with respect to the first support plate 58 a in the extending direction of the upstream main body portion 57 a. As shown in FIG. 4, the surface direction of the second support plate 59a is orthogonal to the longitudinal direction of the vehicle. Plate-like second ribs 59c protrude from the edges of both sides of the second support plate 59a in the vehicle width direction toward the rear side of the vehicle. The second rib 59c extends in the vertical direction over the entire second support plate 59a, and the upper end of the second rib 59c extends to the upstream main body 57a. A substantially cylindrical second boss 59b protrudes from the lower end of the second support plate 59a toward the rear side of the vehicle. The rear end surface of the second boss 59 b is located on the rear side of the vehicle than the rear end of the second rib 59 c and on the rear side of the rear end of the upstream main body portion 57 a in the surge tank 56. A metal insert nut 91 is fixed to the inside of the second boss 59b.

  As shown in FIG. 3, a plate-like support member 70 is fixed to the fixing plate 64 in the bracket 60. The support member 70 extends from the fixing plate 64 of the bracket 60 toward the second boss 59 b of the surge tank 56 as a whole toward the upper right side of the vehicle.

  As shown in FIG. 3, the support member 70 includes a plate-like first fixing portion 71 that contacts the rear surface of the fixing plate 64 in the bracket 60. A bolt hole 71 a passes through the first fixing portion 71 in the thickness direction of the first fixing portion 71. A plate-like connecting portion 72 extends from the right edge of the vehicle in the first fixed portion 71 toward the right side of the vehicle. As shown in FIG. 4, the connecting portion 72 extends toward the rear side of the vehicle toward the right side of the vehicle. As shown in FIG. 3, a plate-like second fixing portion 73 extends from the right edge of the vehicle at the connecting portion 72 toward the right side of the vehicle. A bolt hole 73 a passes through the second fixing portion 73 in the thickness direction of the second fixing portion 73. As shown in FIG. 4, the second fixing portion 73 is in contact with the rear end surface of the second boss 59 b in the surge tank 56. As shown in FIG. 3, most of the support member 70 extends so as to be located on the right side of the vehicle with respect to the edge of the fixing plate 64 in the bracket 60 when viewed from the rear side in the vehicle front-rear direction.

  The material of the support member 70 is the same steel as the bracket 60. That is, the material of the support member 70 is a material having rigidity higher than that of the resin which is the material of the surge tank 56. Further, the plate thickness of the support member 70 is thinner than the plate thickness of the connecting plate 61 and the fixed plate 64 in the bracket 60. Therefore, the bending rigidity of the support member 70 in the vehicle front-rear direction is lower than the bending rigidity of the bracket 60 in the vehicle front-rear direction. Here, the rigidity of the material means the Young's modulus of the material. The bending rigidity is the difficulty of bending deformation of a member, and is a value determined by the product of the sectional moment of inertia of the member and the Young's modulus of the material of the member.

  As shown in FIG. 4, the first fixing portion 71 in the support member 70 includes a bolt 94 inserted into the bolt hole 71 a of the first fixing portion 71 and the bolt hole 64 a of the bracket 60 (fixing plate 64), and a fixing plate. It is fixed to the fixing plate 64 in the bracket 60 by a nut 95 located on the front side of the 64. In the present embodiment, the portion sandwiched between the bolt 94 and the nut 95 is the fixing position of the bracket 60 and the support member 70.

  As shown in FIG. 4, on the rear side of the second fixing portion 73 in the support member 70, a dynamic damper 80 for suppressing the vibration of the surge tank 56 is disposed. The dynamic damper 80 has a substantially cylindrical shape, and the axis of the cylinder is disposed along the longitudinal direction of the vehicle. The front end surface of the substantially cylindrical dynamic damper 80 in the vehicle front-rear direction is in contact with the second fixed portion 73 of the support member 70. As described above, since the rear end surface of the second boss 59b is located on the rear side of the rear end of the upstream main body portion 57a in the surge tank 56, the dynamic damper 80 is on the rear side of the surge tank 56. It is located in A bolt hole 81 is defined at the center of the substantially cylindrical dynamic damper 80. The dynamic damper 80 damps the surge tank 56 by vibrating an internal weight (not shown) in the axial direction of the cylindrical shape. In the present embodiment, the vibration damping direction, which is the direction of vibration that can be controlled by the dynamic damper 80, is along the vehicle longitudinal direction.

  A bolt 96 is inserted through the bolt hole 81 of the dynamic damper 80. The bolt 96 is inserted through the bolt hole 73 a of the support member 70 (second fixing portion 73) and the insert nut 91 of the second boss 59 b in the surge tank 56. That is, in this embodiment, the dynamic damper 80 is fixed integrally with the support member 70 and the surge tank 56 at the fixed position. In the present embodiment, the contact position between the second fixing portion 73 in the support member 70 and the second boss 59 b in the surge tank 56 is the fixing position between the support member 70 and the surge tank 56.

  As described above, the second support plate 59a is located closer to the center of the upstream body portion 57a than the first support plate 58a in the extending direction (vehicle width direction) of the upstream body portion 57a. Further, the center of gravity of the surge tank 56 in the vehicle width direction is located slightly on the left side of the vehicle than the central portion in the extending direction (vehicle width direction) of the upstream side main body portion 57a. Therefore, the center of gravity of the surge tank 56 in the vehicle width direction is located in the vicinity of the second support plate 59a. That is, in the present embodiment, the fixing position of the support member 70 and the surge tank 56 is located closer to the center of gravity of the surge tank 56 in the vehicle width direction than the fixing position of the bracket 60 and the surge tank 56.

The operation and effects of the present embodiment will be described.
In the internal combustion engine 100, the surge tank 56 may vibrate due to vibration accompanying combustion of fuel in the cylinder 11 in the cylinder block 10 or movement of the vehicle. In the above embodiment, the vibration of such a surge tank 56 is damped by the dynamic damper 80.

  Here, it is assumed that the dynamic damper 80 is directly attached to the second boss 59 b in the surge tank 56 without providing the support member 70. In this case, the dynamic damper 80 is supported only by the second support plate 59a and the second rib 59c in the surge tank 56. Moreover, in the above embodiment, the entire surge tank 56 including the second support plate 59a and the second rib 59c is formed of a resin having a relatively low rigidity. Therefore, the size and weight of the dynamic damper 80 are limited by the size and weight that can be supported by the resin-made second support plate 59a and the second rib 59c.

  Further, suppose that the dynamic damper 80 is directly attached to the bracket 60. However, since the bracket 60 is made of steel with high rigidity and the first connection plate 62 and the second connection plate 63 function as reinforcing ribs, the bending rigidity with respect to bending in the vehicle longitudinal direction is high. Therefore, even if the surge tank 56 vibrates, the bracket 60 does not vibrate so much. As a result, the vibration of the surge tank 56 is not easily transmitted to the dynamic damper 80 via the bracket 60, and the vibration damping effect of the dynamic damper 80 may not be sufficiently exhibited.

  As shown in FIG. 3, in this embodiment, the dynamic damper 80 is supported by a support member 70 having a higher rigidity than the material of the surge tank 56. Therefore, in the present embodiment, the weight and the like of the dynamic damper 80 are less likely to be limited than when the dynamic damper 80 is directly attached to the surge tank 56. As a result, the dynamic damper 80 having a desired vibration damping characteristic can be attached to dampen the surge tank 56. Specifically, the surge tank 56 easily vibrates at a frequency close to the natural frequency of the surge tank 56. Even if the dynamic damper 80 having a high damping characteristic with respect to the natural frequency is correspondingly heavy, the dynamic damper 80 can be appropriately supported by the support member 70.

  In the present embodiment, the support member 70 has a relatively thin plate thickness, and the support member 70 includes a boundary portion between the first fixing portion 71 and the connection portion 72, and the connection portion 72 and the second fixing portion 73. It is bent at the boundary with the. Therefore, the support member 70 is easy to bend with the boundary portion as a bending ridgeline, and is more likely to vibrate than the bracket 60 in the vehicle front-rear direction, which is the vibration damping direction of the dynamic damper 80. Accordingly, the dynamic damper 80 can appropriately exhibit the vibration damping effect of the surge tank 56 by vibrating with the support member 70 as compared with the case where the dynamic damper 80 is fixed to the bracket 60.

  By the way, in a vehicle, a change in acceleration in the longitudinal direction of the vehicle generally tends to occur. As the acceleration in the longitudinal direction of the vehicle changes, acceleration in the longitudinal direction of the vehicle also acts on the surge tank 56. Therefore, vibration in the longitudinal direction of the vehicle is likely to occur in the surge tank 56. In the present embodiment, the support member 70 extending from the bracket 60 extends from the side of the first support plate 58a that is relatively far from the center of gravity of the surge tank 56 in the vehicle width direction to the center of gravity of the surge tank 56 in the vehicle width direction. On the other hand, it extends toward the second support plate 59a which is relatively close. Since the dynamic damper 80 is fixed to the support member 70, the dynamic damper 80 is positioned closer to the center of gravity of the surge tank 56 in the vehicle width direction than the configuration in which the dynamic damper 80 is fixed to the bracket 60. Therefore, in the present embodiment, for example, in the vehicle width direction, the vehicle is placed in the surge tank 56 in the surge tank 56 as compared with the configuration in which the second support plate 59a is located at the vehicle left end portion of the upstream body portion 57a of the surge tank 56. When the vibration in the front-rear direction occurs, the vibration of the surge tank 56 is easily transmitted to the dynamic damper 80 via the support member 70. Then, the damping effect of the dynamic damper 80 in the front-rear direction of the vehicle in the surge tank 56 is likely to extend to the entire surge tank 56. As a result, in the present embodiment, the dynamic damper 80 can appropriately suppress the longitudinal vibration of the vehicle in the surge tank 56.

  Further, in a vehicle, generally, acceleration (deceleration) at the time of sudden deceleration tends to be larger than acceleration at the time of sudden acceleration. Also, the speed at which the vehicle travels forward tends to be greater than the speed at which the vehicle travels rearward. Therefore, when the vehicle is moving forward and the vehicle decelerates rapidly, a large inertial force may be applied to the dynamic damper 80 toward the front of the vehicle. If the dynamic damper 80 is attached only to the second boss 59b in the relatively low strength surge tank 56, the second support plate 59a and the second rib 59c in the surge tank 56 will be damaged, and the dynamic damper 80 will May fall out. In particular, if the dynamic damper 80 is located on the rear side of the surge tank 56, the dropped dynamic damper 80 may blow off to the front side and come into contact with other parts. In particular, in the above embodiment, since it is a so-called V-type internal combustion engine 100, a fuel injection valve, a purge pipe for guiding evaporated fuel, and the like are provided in the space between the first cylinder head 21 and the second cylinder head 26. May be placed. If the dynamic damper 80 contacts such a member, it may lead to a failure of the internal combustion engine 100. In such a configuration of the internal combustion engine 100, fixing the dynamic damper 80 to the support member 70 having rigidity higher than that of the material of the surge tank 56 suppresses the dropout of the dynamic damper 80 described above and the contact with other parts. It is very effective in

  In the present embodiment, the dynamic damper 80 is fixed at a fixed position between the support member 70 and the surge tank 56. That is, in the present embodiment, the dynamic damper 80 is fixed at a position where the vibration of the surge tank 56 is most easily transmitted in the support member 70. Thereby, in this embodiment, the damping effect of the dynamic damper 80 can be maximized.

The present embodiment can be modified as follows. The present embodiment and the following modifications can be implemented in combination with one another as long as there is no technical contradiction.
In the above embodiment, the vibration damping direction of the dynamic damper 80 may be changed. For example, the damping direction of the dynamic damper 80 may be inclined in the vertical direction with respect to the vehicle longitudinal direction. Even if the vibration suppression direction of the dynamic damper 80 is inclined, the dynamic damper 80 can suppress the vibration of the surge tank 56 in the longitudinal direction as long as the vibration damping direction has a component in the vehicle longitudinal direction.

  Further, the vibration damping direction of the dynamic damper 80 may be along the vehicle width direction or the vehicle vertical direction. As described above, when the damping direction of the dynamic damper 80 is in the vehicle width direction, the bending rigidity of the support member 70 in the vehicle width direction is lower than the bending rigidity of the bracket 60 in the vehicle width direction. Good. Similarly, when the damping direction of the dynamic damper 80 is in the vertical direction of the vehicle, the bending rigidity of the support member 70 in the vertical direction of the vehicle is lower than the bending rigidity of the bracket 60 in the vertical direction of the vehicle Good.

  In the embodiment, the support member 70 and the bracket 60 can be appropriately changed. For example, the thickness of the support member 70 may be equal to or greater than the thickness of the connection plate 61 and the fixing plate 64 in the bracket 60. Also in this case, the first connecting plate 62 and the second connecting plate 63 in the bracket 60 can relatively increase the bending rigidity of the bracket 60 in the vehicle front-rear direction. As a result, it is only necessary that the bending rigidity of the support member 70 in the vehicle front-rear direction is lower than the bending rigidity of the bracket 60 in the vehicle front-rear direction.

  Further, the bracket 60 in which the first connection plate 62 and the second connection plate 63 are omitted and the fixing plate 64 extends from the connection plate 61 may be employed. Also in the bracket 60, for example, the thickness of the support member 70 is thinner than the thickness of the connection plate 61 and the fixing plate 64 in the bracket 60, so that the bending rigidity of the support member 70 in the vehicle front-rear direction is What is necessary is just to be lower than the bending rigidity of the bracket 60 in the vehicle front-back direction.

  Furthermore, the bending rigidity of the supporting member 70 in the vehicle front-rear direction may be lower than the bending rigidity of the bracket 60 in the vehicle front-rear direction by changing the material of the support member 70 and the bracket 60.

  Moreover, you may adjust both bending rigidity by changing the shape of the supporting member 70 and the bracket 60. FIG. For example, the bending rigidity of the support member 70 in the vehicle front-rear direction may be lowered by providing a groove penetrating in the thickness direction of the support member 70 in the support member 70. Moreover, the bending rigidity of the support member 70 in the vehicle front-rear direction may be lowered by adopting a corrugated plate material that is curved a plurality of times in the vehicle front-rear direction as the connection portion 72 in the support member 70. As described above, the bending rigidity of the support member 70 in the vehicle longitudinal direction may be lower than the bending rigidity of the bracket 60 in the vehicle longitudinal direction.

  In the above embodiment, for example, if the vibration of the surge tank 56 in the vehicle longitudinal direction can be sufficiently suppressed, the fixing position of the bracket 60 and the surge tank 56 is more than the fixing position of the support member 70 and the surge tank 56. Alternatively, it may be located on the gravity center side of the surge tank 56 in the vehicle width direction. Further, when the vibration damping direction of the dynamic damper 80 is along the vehicle width direction or the vehicle vertical direction, the fixing position of the bracket 60 and the surge tank 56 is more in the vehicle width direction than the fixing position of the support member 70 and the surge tank 56. The center of gravity of the surge tank 56 may be located.

  In the above embodiment, the position of the surge tank 56 relative to the cylinder block 10 may be changed. For example, when an in-line cylinder internal combustion engine is employed, the surge tank 56 may be positioned on the front side of the vehicle or on the outside in the vehicle width direction with respect to the cylinder block 10.

  In the embodiment, the fixing configuration of the bracket 60 can be changed as appropriate. For example, the connection plate 61 and the second cylinder head 26 in the bracket 60 may be fixed by welding. Similarly, the fixing plate 64 in the bracket 60 and the first fixing portion 71 in the support member 70 may be fixed by welding. When welding is performed in this manner, a portion where the fixing plate 64 of the bracket 60 and the first fixing portion 71 of the support member 70 are connected by welding is a fixing position of the bracket 60 and the support member 70. .

  In the embodiment, the bracket 60 and the support member 70 may be integrally formed. For example, the bracket 60 and the support member 70 may be formed by performing sheet metal processing on a single metal plate. Also in this case, the bending rigidity of the support member 70 in the vehicle longitudinal direction may be lower than the bending rigidity of the bracket 60 in the vehicle longitudinal direction. In this configuration, the boundary portion of the bending rigidity in the longitudinal direction of the vehicle is the fixed position of the bracket 60 and the support member 70.

  In the above embodiment, the fixing position of the dynamic damper 80 with respect to the support member 70 can be changed as appropriate. For example, as shown in FIG. 3, the first fixing portion 71, the connecting portion 72, and the first fixing portion of the support member 70 are located on the second boss 59 b side of the surge tank 56 with respect to the fixing position of the support member 70 with the bracket 60. The fixing position of the dynamic damper 80 can be appropriately changed within the range of the two fixing portions 73.

  In the above embodiment, the position of the dynamic damper 80 with respect to the surge tank 56 can be changed as appropriate. For example, when the rear end surface of the second boss 59b in the surge tank 56 is in front of the rear end of the upstream main body 57a, the dynamic damper 80 is not positioned behind the surge tank 56. Even in this case, it is only necessary that the vibration of the surge tank 56 in the vehicle longitudinal direction can be suppressed by the dynamic damper 80.

  In the above embodiment, the fixing configuration of the dynamic damper 80 with respect to the support member 70 can be changed as appropriate. For example, the front end surface of the dynamic damper 80 and the rear end surface of the second fixing portion 73 of the support member 70 may be bonded and fixed.

  -In the said embodiment, the fixing position of the lower end part of the bracket 60 can be changed suitably. For example, the lower end of the bracket 60 may be fixed to the cylinder block 10 in place of the second cylinder head 26 by changing the shape and dimensions of the bracket 60. In addition, the lower end portion of the bracket 60 may be fixed to the second cylinder head 26 and the cylinder block 10.

  In the above embodiment, the shapes of the intake manifold 51 and the surge tank 56 may be changed as appropriate. For example, the surge tank 56 may extend to surround the intake manifold 51 from the rear side and the right side of the vehicle. Specifically, the upstream side of the upstream side main body portion 57a in the surge tank 56 is the left side of the vehicle, the downstream side is the right side of the vehicle, and the downstream side body portion 57b in the surge tank 56 is positioned above the first head cover 31. It may be In this case, the lower end portion of the bracket 60 may be fixed to the first cylinder head 21.

  In the above embodiment, the intake manifold 51 and the surge tank 56 may be formed as separate members, and the surge tank 56 may be fixed to the intake manifold 51.

  In the above embodiment, the intake manifold 51 and the surge tank 56 may be made of metal. Also in this case, the material of the support member 70 may be a material whose rigidity is higher than the material of the surge tank 56.

  DESCRIPTION OF SYMBOLS 10 ... Cylinder block, 11 ... Cylinder, 11L ... Cylinder, 11R ... Cylinder, 12 ... Housing space, 21 ... 1st cylinder head, 22 ... Combustion chamber, 23 ... Intake port, 24 ... Exhaust port, 26 ... 2nd cylinder head 26a ... Screw hole, 27 ... Combustion chamber, 28 ... Intake port, 29 ... Exhaust port, 31 ... First head cover, 32 ... Second head cover, 33 ... Oil pan, 35 ... Connector, 36 ... First connection pipe, 37: second connection pipe, 41: piston, 42: connecting rod, 43: crankshaft, 43a: crank pin, 43b: crank arm, 43c: crank journal, 45: throttle valve mechanism, 46: exhaust pipe, 46a: fourth 1 exhaust pipe, 46b ... second exhaust pipe, 46c ... collective exhaust pipe, 51 ... intake manifold, 52 ... collective section, 53 ... branch pipe, 6 Surge tank 57 body body 57a upstream body body 57b downstream body body 58a first support plate 58b first boss 58c first rib 59a second support plate 59b ... second boss, 59c ... second rib, 60 ... bracket, 61 ... connection plate, 61a ... bolt hole, 61b ... bolt hole, 62 ... first connection plate, 63 ... second connection plate, 64 ... fixing plate, 64a ... bolt hole, 70 ... support member, 71 ... first fixing part, 71a ... bolt hole, 72 ... connection part, 73 ... second fixing part, 73a ... bolt hole, 80 ... dynamic damper, 81 ... bolt hole, 91 ... insert nut, 92 ... bolt, 93 ... bolt, 94 ... bolt, 95 ... nut, 96 ... bolt, 100 ... internal combustion engine.

Claims (4)

A cylinder block having a plurality of cylinders defined therein, a cylinder head fixed to an upper end surface of the cylinder block and having a plurality of intake ports connected to the plurality of cylinders, and the plurality of intake air An intake manifold connected to the port; a surge tank connected to the intake manifold and temporarily storing intake air; and a bracket connecting the surge tank to at least one of the cylinder block and the cylinder head; An internal combustion engine including a dynamic damper for suppressing the vibration of the surge tank,
A support member extends from the bracket, and the support member is fixed to the surge tank,
The material of the support member is a material having higher rigidity than the material of the surge tank,
When the direction of vibration that can be controlled by the dynamic damper is a damping direction, the bending rigidity of the support member in the damping direction is lower than the bending rigidity of the bracket in the damping direction,
The vehicle internal combustion engine, wherein the dynamic damper is fixed to the surge tank side with respect to a fixing position of the support member with the bracket. In a state where the internal combustion engine is mounted on a vehicle,
The damping direction of the dynamic damper is a direction capable of suppressing vibration in the front-rear direction of the vehicle,
The internal combustion engine for a vehicle according to claim 1, wherein a fixing position between the support member and the surge tank is located closer to a center of gravity of the surge tank in a vehicle width direction than a fixing position between the bracket and the surge tank. . In the vertical direction of the vehicle, the surge tank is located above the cylinder block,
The internal combustion engine for a vehicle according to claim 2, wherein the dynamic damper is positioned rearward of the surge tank in a longitudinal direction of the vehicle. The internal combustion engine for a vehicle according to any one of claims 1 to 3, wherein the dynamic damper is fixed at a fixed position between the support member and the surge tank.