JP2019173668A - engine - Google Patents

Abstract

To suppress noise in a gear.SOLUTION: In an engine, in a storage space formed by a gear case 35 and a gear case cover 36, an idle gear 21, an idle shaft 14, a crank gear 22 and a cam gear 23 are arranged. In the idle shaft 14 for rotatably supporting the idle gear 21, on a shaft end surface opposing to the gear case cover 36, an injection opening part 70 is formed for injecting a lubrication oil. At the gear case cover 36, a lubrication oil guide part 51 having a first path 53 and a second path 54 connected to each other is provided. The first path 53 guides the lubrication oil from the injection opening part 70 to a first facing position F1 which substantially faces a meshing part E1 of the idle gear 21 and the crank gear 22 in the axial direction, and splashes the lubrication oil to the meshing part E1. The second path 54 guides the lubrication oil to a second facing position F2 which substantially faces a meshing part E2 of the idle gear 21 and the cam gear 23 in the axial direction, and splashes the lubrication oil to the meshing part E2.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an engine including a power transmission mechanism using a gear.

  Conventionally, in an engine, power is transmitted between a plurality of rotating shafts by a plurality of gears meshing with each other. Patent document 1 discloses this kind of engine gear mechanism.

  Patent Document 1 is a gear train composed of a crank gear, an idle gear, and the like, and is linked to a ball bearing that serves as a bearing for an idle gear or an idle gear that lubricates an outer peripheral tooth portion of the idle gear by a lubricating oil jetting and rebounding supply means. A bearing device is disclosed. More specifically, the lubricating oil jetting / repelling supply means includes an oil passage, a jet hole communicating with the oil passage, and a lubricating oil splashing member. The oil passage is formed by an axial through hole provided in the axial center portion of the spindle of the idle gear, and communicates with an oil passage formed in the cylinder block. The squirting hole is an axial through hole provided at the center of a retaining plate attached to the tip of the support shaft, and concentrically communicates with the oil passage. The lubricating oil rebound member is constituted by a gear case disposed opposite to the front wall of the cylinder block, and is a pair of recesses provided adjacent to both sides in the horizontal direction of the center set on the axis of the oil passage and the jet hole. It has a spherical surface.

  As a result, the lubricating oil supplied to the oil passage passes through the oil passage, and is ejected from the jet hole, and collides with a gear case that functions as a lubricating oil rebound member. And a ball bearing etc. can be lubricated by the jet flow rebounded by the lubricating oil rebound member.

Japanese Patent No. 4009567

  However, since the configuration of Patent Document 1 lubricates the gear by the jet rebounded obliquely while spreading along the spherical surface, it is difficult to sufficiently reach the lubricating oil between the tooth surfaces at the meshing portion of the gear, Since the lubrication of the meshing portion is substantially insufficient, the generation of noise may not be suppressed, and an improvement has been desired.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an engine that can satisfactorily suppress the generation of noise in the meshing portion of the gear.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above. Next, means for solving the problems and the effects thereof will be described.

  According to an aspect of the present invention, an engine having the following configuration is provided. That is, the engine includes a housing, a cover, a first gear, a support shaft, a second gear, and a third gear. The cover is fixed to the housing. The support shaft rotatably supports the first gear. The second gear meshes with the first gear. The third gear meshes with the first gear. The first gear, the support shaft, the second gear, and the third gear are disposed in an accommodation space formed by the housing and the cover. In the support shaft, an opening for ejecting lubricating oil is formed on a shaft end surface facing the cover. The cover is provided with a lubricant guide portion. The lubricating oil guide portion has a first path and a second path. The first path guides the lubricating oil supplied from the opening to a first facing position that substantially faces the meshing portion of the first gear and the second gear in the axial direction, and the first facing Lubricating oil is applied from the position toward the meshing portion of the first gear and the second gear. The second path guides the lubricating oil supplied from the opening to a second facing position that substantially faces the meshing portion of the first gear and the third gear in the axial direction, and the second facing Lubricating oil is applied from the position toward the meshing portion of the first gear and the second gear. The first route and the second route are connected to each other.

  As a result, the lubricating oil can be blown and hung along the axial direction from the facing position toward the meshing portion, so that the lubricating oil hung on the meshing portion can easily reach between the tooth surfaces, The meshing portion can be lubricated substantially satisfactorily. As a result, generation of noise at the meshing portion can be effectively suppressed.

  Further, the lubricating oil can be applied to the two meshing portions while being distributed by branching and flowing the lubricating oil into the first path and the second path. Therefore, it is possible to lubricate the plurality of meshing portions with a simple configuration.

  In the engine, it is preferable that a branching protrusion is provided in the lubricating oil guide portion at a location where the first path and the second path are connected.

  As a result, the lubricating oil supplied from the opening hits the diverting protrusion, so that the flow of the lubricating oil is divided into the first path and the second path, so that the lubricating oil can be simply supplied to the first path and the second path. A plurality of meshing portions can be lubricated by reliably distributing the structure.

  In the engine, in each of the first path and the second path, the entire path through which the supplied lubricant is guided to the first facing position or the second facing position is the interior space of the cover. Can be configured to be open.

  In this case, the lubricating oil guide portion can be simplified, and the manufacturing cost can be reduced.

  In the engine, in each of the first path and the second path, at least a part of the path through which the supplied lubricating oil is guided to the first facing position or the second facing position is defined by the cover. It can also be configured to be closed with respect to the interior space.

  In this case, most of the lubricating oil supplied to the lubricating oil guide portion can be reliably guided to the position facing the meshing portion in the axial direction. Therefore, lubricating oil can be used efficiently.

  The engine preferably has the following configuration. In other words, the lubricating oil guide portion is formed with an intake opening for taking the lubricating oil into the lubricating oil guide portion. A first discharge opening that ejects lubricating oil toward the meshing portion of the first gear and the second gear is formed in the first path. A second discharge opening that ejects lubricating oil toward the meshing portion of the first gear and the third gear is formed in the second path. The opening area of the first discharge opening and the opening area of the second discharge opening are both smaller than the opening area of the intake opening.

  Thereby, lubricating oil can be blown off vigorously from the first discharge opening and the second discharge opening, and the meshing portion can be well lubricated.

  The engine preferably has the following configuration. That is, a fan is disposed outside the cover. The wind generated by the rotation of the fan hits the cover.

  Thereby, the temperature of lubricating oil can be reduced favorably by performing forced air cooling with respect to the lubricating oil which passes the lubricating oil guide part provided in the cover. As a result, the viscosity of the lubricating oil is increased and the cushioning property is increased, so that the noise reduction effect of the meshing portion can be enhanced.

The schematic diagram which shows the whole structure of the valve mechanism and engine gear mechanism with which the engine which concerns on 1st Embodiment is provided. The perspective view of an engine gear mechanism. The cross-sectional perspective view which shows the structure of an idle shaft. The figure which looked at the gear case cover from the inner surface side. The enlarged view of the lubricating oil guide part provided in the inner wall of a gear case cover. FIG. 6 is a cross-sectional perspective view showing the AA cross section of FIG. 5. Sectional perspective view which shows the BB cross section of FIG. Sectional perspective view which shows CC cross section of FIG. The figure which shows the example of the shape of the gear for guide | inducing the lubricating oil apply | coated by the lubricating oil guide part between tooth surfaces. The enlarged view of the lubricating oil guide part in 2nd Embodiment. The schematic diagram which shows the DD cross section of FIG.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram showing an overall configuration of a valve mechanism 6 and an engine gear mechanism 10 provided in the engine 1 according to the first embodiment.

  An engine 1 shown in FIG. 1 is configured as a multi-cylinder diesel engine mounted on, for example, a vehicle or a ship. The engine 1 includes an engine gear mechanism 10 that transmits the rotation of the crankshaft 11 to the camshaft 12.

  The engine gear mechanism 10 is disposed on a side portion of the cylinder block 2 included in the engine 1. A fan 7 for cooling the engine 1 is disposed in the vicinity of the engine gear mechanism 10. The fan 7 rotates when the rotation of the crankshaft 11 is transmitted through a power transmission mechanism (not shown).

  A cylinder head 4 is fixed to the upper part of the cylinder block 2, and an oil pan 5 is attached to the lower part of the cylinder block 2.

  The engine gear mechanism 10 is used to drive the valve mechanism 6 of the engine 1. The valve mechanism 6 includes a cam 41, a tappet 42, a push rod 43, a rocker arm 44, and a valve 45. Note that FIG. 1 representatively shows only the configuration related to opening and closing of the intake port or exhaust port of one cylinder among the plurality of cylinders. Further, in FIG. 1, the engine gear mechanism 10 is shown in a perspective view with a chain line in order to easily show the configuration around the cam 41.

  The cam 41 is provided on the cam shaft 12 of the engine gear mechanism 10. The cam 41 rotates integrally with the cam shaft 12.

  The tappet 42 is supported so as to be able to reciprocate, and is configured to be able to contact the peripheral edge of the cam 41. The tappet 42 reciprocates according to the rotation of the cam 41.

  The push rod 43 is an elongated rod-like member, one end of which is connected to the tappet 42 and the other end is connected to the rocker arm 44. The push rod 43 transmits the force that the tappet 42 receives from the cam 41 to the rocker arm 44.

  The rocker arm 44 is disposed inside the head cover 3 attached to the upper part of the cylinder head 4 and is supported so as to be rotatable about a support shaft 47. One end of the rocker arm 44 is connected to the push rod 43, and the other end is connected to the valve 45. The rocker arm 44 rotates when pushed by the push rod 43 and pushes the valve 45 to displace it.

  The valve 45 functions as a valve body of the valve operating mechanism 6. A combustion chamber (not shown) is formed in the cylinder head 4 and the like of the engine 1, and the valve 45 opens and closes a port (specifically, an intake port or an exhaust port) connected to the combustion chamber.

  A valve spring 46 is attached to the valve 45, and this valve spring 46 urges the valve 45 upward (in other words, the direction of closing the port). In a state where it is not pushed by the rocker arm 44, the valve 45 closes the port by a valve spring 46. When the valve 45 is pushed downward by the rocker arm 44, the valve 45 opens the port.

  The configuration of the valve mechanism 6 described above is an example, and appropriate changes can be made. For example, the valve mechanism 6 may be provided with a swing arm instead of the rocker arm 44. Further, the rocker arm 44 and the swing arm may be combined. The push rod 43 may be disposed so as not to be connected to the tappet 42 but to be close to the tappet 42.

  Next, the engine gear mechanism 10 will be described with reference to FIG. FIG. 2 is a perspective view of the engine gear mechanism 10.

  As shown in FIG. 2, the engine gear mechanism 10 includes a gear case (housing) 35 that houses a plurality of gears. The gear case 35 is fixed to the cylinder block 2.

  The gear case 35 is made of, for example, a casting. The gear case 35 is formed with a recess 35a that is open on one side. A gear case cover (cover) 36 is attached so as to cover the open side of the recess 35a. The gear case 35 and the gear case cover 36 form an accommodation space that can accommodate a plurality of gears. In FIG. 2, the gear case cover 36 is perspectively shown by a chain line in order to easily show the inside of the accommodation space.

  The engine gear mechanism 10 includes an idle gear (first gear) 21, a crank gear (second gear) 22, a cam gear (third gear) 23, and a lubricating oil pump gear 24. The idle gear 21, the crank gear 22, the cam gear 23, and the lubricating oil pump gear 24 are all configured as spur gears and are arranged in the accommodation space.

  The idle gear 21 is rotatably supported via an idle shaft (support shaft) 14. In the portion corresponding to the idle shaft 14, an opening (not shown) is formed in the gear case 35. The idle shaft 14 is disposed so as to pass through the opening and is fixed to the cylinder block 2. The idle gear 21 meshes with both the crank gear 22 and the cam gear 23.

  The crank gear 22 is fixed to the end of the crankshaft 11 disposed in parallel with the idle shaft 14. The crank gear 22 rotates integrally with the crankshaft 11. The crank gear 22 is disposed in the vicinity of the idle gear 21 and meshes with the idle gear 21.

  The cam gear 23 is fixed to the end portion of the cam shaft 12 disposed in parallel with the crankshaft 11. The cam gear 23 rotates integrally with the cam shaft 12. The cam gear 23 is disposed in the vicinity of the idle gear 21 and meshes with the idle gear 21.

  The lubricant pump gear 24 is disposed in the vicinity of the crank gear 22. The lubricating oil pump gear 24 functions as a drive input gear provided in the lubricating oil pump 18. The lubricant pump gear 24 meshes with the crank gear 22.

  Thus, a gear train including the crank gear 22, the idle gear 21, and the cam gear 23 is formed in the gear case 35 in the order from the driving side to the driven side. With this gear train, the rotation of the crankshaft 11 can be reduced by half and transmitted to the camshaft 12 to realize the opening and closing of the valve 45 synchronized with the rotation of the crankshaft 11.

  A gear train including the crank gear 22 and the lubricating oil pump gear 24 is formed in the gear case 35. Thereby, the lubricating oil pump 18 can be driven based on the rotation of the crankshaft 11.

  When the lubricating oil pump 18 is driven, the lubricating oil stored in the oil pan 5 is sucked, and the lubricating oil is circulated in the engine 1 through an unillustrated oil gallery which is an oil passage formed in the engine 1. Let As a result, the lubricating oil can be supplied to each sliding portion of the engine, the meshing portion of the gear, and the like.

  Next, a configuration for injecting lubricating oil from the idle shaft 14 will be described in detail. FIG. 3 is a cross-sectional perspective view showing the configuration of the idle shaft 14.

  The idle shaft 14 shown in FIG. 3 is arranged in the above-described accommodation space, like the idle gear 21, the crank gear 22 and the cam gear 23.

  As shown in FIG. 3, the idle shaft 14 includes a shaft body 31 and a retaining portion 32.

  The shaft body 31 is formed in a substantially cylindrical shape. The shaft body 31 is inserted into a cylindrical shaft hole formed in the idle gear 21 so as to penetrate therethrough in the axial direction. As a result, the idle gear 21 can be supported rotatably with respect to the idle shaft 14. When the idle gear 21 rotates, the inner peripheral surface of the shaft hole of the idle gear 21 slides with respect to the outer peripheral surface of the shaft main body 31.

  The retaining portion 32 is formed integrally with an end portion on the side far from the gear case 35 in the axial direction of the shaft body 31. The retaining portion 32 is formed in a flange shape, and the diameter thereof is larger than the inner diameter of the shaft hole of the idle gear 21. Thereby, it is possible to prevent the idle gear 21 from coming off the idle shaft 14.

  An oil supply path 65 for lubricating the configuration around the idle shaft 14 is formed inside the idle shaft 14. The oil supply path 65 includes a first supply path 66, a second supply path 67, and a third supply path 68.

  The first supply path 66 is formed in a linear shape along the central axis of the idle shaft 14. The first supply path 66 is connected to an unillustrated oil gallery through which lubricating oil is pumped by driving the lubricating oil pump 18 via an unillustrated path.

  The second supply path 67 is formed in a linear shape elongated in the radial direction of the idle shaft 14. The radially inner end of the second supply path 67 is connected to the end of the first supply path 66. A radially outer end of the second supply path 67 forms a sliding surface lubrication opening 69 on the outer peripheral surface of the shaft body 31.

  The third supply path 68 is elongated in a straight line parallel to the central axis of the idle shaft 14. The third supply path 68 is formed so as to connect the middle part of the second supply path 67 and the shaft end surface of the idle shaft 14 on the side far from the gear case 35. The third supply path 68 forms an injection opening (opening) 70 on the shaft end surface of the idle shaft 14.

  With this configuration, when the lubricating oil pump 18 is driven, the lubricating oil passes through the first supply path 66 and the second supply path 67 inside the idle shaft 14 and passes through the sliding surface lubrication opening 69 to the idle shaft 14. Sent to outside. Therefore, the sliding surface between the idle shaft 14 and the idle gear 21 can be lubricated.

  Further, the lubricating oil passes through the first supply path 66, the second supply path 67, and the third supply path 68, and is sent out from the injection opening 70 to the outside of the idle shaft 14. Therefore, the lubricating oil can be injected from the end surface on the one side in the axial direction of the idle shaft 14 toward the gear case cover 36 in a direction parallel to the rotational axis of the idle gear 21.

  Next, the configuration of the gear case cover 36 will be described with reference to FIG. FIG. 4 is a view of the gear case cover 36 as viewed from the inner surface side. FIG. 5 is an enlarged view of the lubricating oil guide 51 provided on the inner wall of the gear case cover 36. 6 is a cross-sectional perspective view showing the AA cross section of FIG. FIG. 7 is a cross-sectional perspective view showing a BB cross section of FIG. 5. 8 is a cross-sectional perspective view showing a CC cross section of FIG.

  The gear case cover 36 shown in FIGS. 2 and 4 is made of, for example, a casting. As shown in FIG. 4, the gear case cover 36 has a recess 36 a that is open on one side. The recess 36 a can also be referred to as an internal space of the gear case cover 36. By fixing the gear case cover 36 to the gear case 35, the recess 36a of the gear case cover 36 and the recess 35a of the gear case 35 are connected to each other, and the above-described accommodation space is formed.

  On the inner wall of the recess 36a of the gear case cover 36, there is provided a lubricating oil guide portion 51 for supplying lubricating oil to the meshing portions E1 and E2 between the idle gear 21 and other gears. The lubricating oil guide portion 51 is disposed at a position corresponding to the idle shaft 14 and the idle gear 21 in the direction of the rotation axis of the idle gear 21.

  The lubricating oil guide part 51 consists of a path that can guide the lubricating oil along. This path is formed by an elongated oil groove through which lubricating oil flows, and this oil groove opens the side close to the idle shaft 14 and the idle gear 21 (in other words, the gear case 35 side). The lubricating oil can enter and exit the lubricating oil guide 51 through the open portion of the lubricating oil guide 51.

  The structure of the lubricating oil guide 51 will be specifically described. When viewed in a direction parallel to the rotational axis of the idle gear 21, the lubricating oil guide 51 has rotated the V shape as shown in FIG. It has a shape like this. The position of the bent portion of the lubricant guide 51 is determined so that the lubricant injected from the injection opening 70 of the idle shaft 14 enters the inside thereof. In the following description, the portion where the lubricating oil from the injection opening 70 is taken in the lubricating oil guide portion 51 may be referred to as the taking-in portion 52.

  The lubricant guide portion 51 includes a first path 53 and a second path 54. The first path 53 and the second path 54 are connected to each other at the portion of the take-in portion 52 while forming a bent connection portion.

  The first path 53 is formed as an elongated linear path that connects the take-in portion 52, the meshing portion E1 of the idle gear 21 and the crank gear 22 and the first facing position F1 facing in the axial direction. Yes.

  The second path 54 is formed as an elongated linear path that connects the take-in part 52, the meshing part E2 of the idle gear 21 and the cam gear 23, and the second facing position F2 facing in the axial direction. .

  Each of the first path 53 and the second path 54 is formed by a linear groove having a substantially V-shaped cross section. In the first path 53 and the second path 54, the lubricating oil flows from the intake part 52 to the facing positions F1 and F2 that face the meshing parts E1 and E2 in the axial direction.

  As shown in FIG. 4, both the first path 53 and the second path 54 are oriented such that the downstream end is lower than the upstream end in the direction in which the lubricating oil flows. Thereby, the lubricating oil can be smoothly guided along the first path 53 and the second path 54 by utilizing the weight of the lubricating oil.

  Further, in both the first path 53 and the second path 54, the width of the groove is gradually reduced from the upstream end toward the downstream end. As a result, the flow of the lubricating oil applied to the meshing portions E1 and E2 from the downstream end of each path can be reduced, and more concentrated lubrication for the meshing portions E1 and E2 can be realized. Can do.

  As shown in FIG. 5, a diversion projection 55 is provided inside the lubricant guide 51. The diversion projection 55 is disposed in the vicinity of the take-in portion 52 and on the inner peripheral side of the portion where the first path 53 and the second path 54 are connected in a bent shape. As shown in FIG. 6, two diversion guide surfaces 55 a arranged in an inclined manner are arranged on the surface of the diversion projection 55. The diverting projection 55 is arranged so that the lubricating oil from the injection opening 70 hits the vicinity of the boundary between the two diverting guide surfaces 55a. The directions of the two diversion guide surfaces 55a are different from each other. Each diversion guide surface 55 a is smoothly connected to the inner wall surface of the corresponding first path 53 or second path 54.

  The flow of the lubricating oil supplied to the lubricating oil guide part 51 via the intake part 52 is divided at the boundary between the two branch guide surfaces 55 a of the branching protrusion 55. A part of the lubricating oil flows in the first path 53 and the rest flows in the second path 54. By changing the position of the diversion projection 55, the shape of the diversion guide surface 55a, and the like, the ratio of the lubricating oil distributed to the two paths can be adjusted.

  In each of the first path 53 and the second path 54, discharge inclined surfaces 57 and 58 are formed at the downstream end in the direction in which the lubricating oil flows. The discharge inclined surfaces 57 and 58 are formed to reduce the depth as they approach the downstream side in the direction in which the lubricating oil flows. Thereby, the direction of the lubricating oil passing through each of the first path 53 and the second path 54 is changed by hitting the discharge inclined surfaces 57 and 58 and is applied toward the meshing portions E1 and E2.

  The discharge inclined surfaces 57 and 58 are disposed so as to substantially face the meshing portions E1 and E2 in the axial direction, and the direction of the lubricating oil flowing along the elongated path of the lubricating oil guide portion 51 is made substantially vertical. Bend. Therefore, the lubricating oil can be applied from a position relatively close to the meshing portions E1 and E2, and the lubrication can be reliably performed. In addition, the direction of the lubricating oil applied to the meshing portions E1 and E2 can be substantially aligned with the axial direction of the idle gear 21. Since the idle gear 21, the crank gear 22 and the cam gear 23 are all configured as spur gears, the lubricating oil can be expedited by blowing the lubricating oil in the direction along the tooth traces of the meshing portions E1 and E2 as described above. And it can guide | smooth smoothly between tooth surfaces and can improve a substantial lubricating effect.

  Both of the first path 53 and the second path 54 are open to the recess 36 a of the gear case cover 36 in the entire path from the intake portion 52 to the discharge inclined surfaces 57 and 58. Therefore, it is easy to manufacture the gear case cover 36 including the lubricant guide portion 51 by, for example, casting.

  Next, the shape of the gear for satisfactorily exerting the lubricating function of the lubricating oil applied substantially in the axial direction to the meshing portion will be described with reference to FIG. FIG. 9 is a diagram showing an example of the shape of a gear for guiding the lubricating oil applied by the lubricating oil guide portion 51 between the tooth surfaces. The two gears 81 and 82 shown in FIG. 9 can be applied to the relationship between the idle gear 21 and the crank gear 22 or the idle gear 21 and the cam gear 23 described above.

  In the example shown in FIGS. 9A and 9B, a conical inclined surface 86 is formed on the surface of the gears 81 and 82 on one side in the axial direction (the side facing the lubricating oil guide portion 51). ing. As shown in FIG. 9B, the inclined surface 86 is formed over a wide range from the inner side to the top of the tooth of the gears 81 and 82. By the guide of the inclined surface 86, the lubricating oil adhering to the surface on one side in the axial direction of the gears 81 and 82 can be easily guided between the tooth surfaces of the gears 81 and 82.

  In the example shown in FIG. 9C and FIG. 9D, the inclined surface 87 is formed so as to connect the surface on one side in the axial direction of the gears 81 and 82 and the bottom of the tooth located between the teeth. Has been. Providing this inclined surface 87 also makes it easier for the lubricating oil to be guided between the tooth surfaces, as in the examples of FIGS. 9 (a) and 9 (b).

  In the example shown in FIGS. 9 (e) and 9 (f), a ring-shaped groove 88 along the circumferential direction is formed on a surface on one side in the axial direction of the gears 81 and 82 at a position corresponding to the tooth bottom. Yes. In this example, the groove 88 is formed in a semicircular cross section, but may be a groove having a V-shaped cross section, for example. In this configuration, since the lubricating oil can be held to some extent in the groove 88, the lubricating oil can be stably guided between the tooth surfaces from the tooth bottom.

  As described above, the engine 1 of this embodiment includes the gear case 35, the gear case cover 36, the idle gear 21, the idle shaft 14, the crank gear 22, and the cam gear 23. The gear case cover 36 is fixed to the gear case 35. The idle shaft 14 rotatably supports the idle gear 21. The crank gear 22 meshes with the idle gear 21. The crank gear 22 meshes with the cam gear 23. The idle gear 21, the idle shaft 14, the crank gear 22, and the cam gear 23 are disposed in an accommodation space formed by the gear case 35 and the gear case cover 36. In the idle shaft 14, an injection opening 70 that ejects lubricating oil is formed on the shaft end surface facing the gear case cover 36. The gear case cover 36 is provided with a lubricant guide portion 51. The lubricant guide 51 has a first path 53 and a second path 54. The first path 53 guides the lubricating oil supplied from the injection opening 70 to the first facing position F1 that substantially faces the meshing portion E1 of the idle gear 21 and the crank gear 22 in the axial direction, and Lubricating oil is applied from the facing position F1 toward the meshing portion E1. The second path 54 guides the lubricating oil supplied from the injection opening 70 to the second facing position F2 that substantially faces the meshing portion E2 of the idle gear 21 and the cam gear 23 in the axial direction, and the second facing surface. Lubricating oil is applied from the position F2 toward the meshing portion E2. The first path 53 and the second path 54 are connected to each other.

  As a result, the lubricating oil can be blown and applied substantially along the axial direction from the facing positions F1 and F2 toward the meshing portions E1 and E2, so that the lubricating oil applied to the meshing portions E1 and E2 can be used as a tooth. It becomes easy to reach between the surfaces, and the meshing portions E1 and E2 can be lubricated substantially satisfactorily. As a result, generation of noise at the meshing portions E1 and E2 can be effectively suppressed.

  Furthermore, the lubricating oil can be applied to the two meshing portions E1 and E2 while being distributed, by branching and flowing the lubricating oil into the first path 53 and the second path 54. Therefore, it is possible to lubricate the plurality of meshing portions E1 and E2 with a simple configuration.

  Further, in the engine 1 of the present embodiment, the lubricating oil guide portion 51 is provided with a flow dividing projection portion 55 at a location where the first path 53 and the second path 54 are connected.

  As a result, the lubricating oil supplied from the injection opening 70 hits the diverting projection 55, whereby the flow of the lubricating oil is divided into the first path 53 and the second path 54. As a result, it is possible to reliably distribute the lubricating oil to the first path 53 and the second path 54 with a simple configuration and lubricate the plurality of meshing portions E1 and E2.

  Further, in the engine 1 of the present embodiment, in each of the first path 53 and the second path 54, all of the paths through which the supplied lubricating oil is guided to the first facing position F1 or the second facing position F2, The gear case cover 36 is open to the internal space.

  Thereby, the lubricating oil guide part 51 can be simplified and manufacturing cost can be reduced.

  Next, a second embodiment will be described. FIG. 10 is an enlarged view of the lubricant guide portion 51x in the second embodiment. FIG. 11 is a schematic diagram showing a DD cross section of FIG. 10. In the description of the present embodiment, the same or similar members as those of the above-described embodiment may be denoted by the same reference numerals in the drawings, and description thereof may be omitted.

  In the engine of the second embodiment, as shown in FIG. 10, the lubricating oil guide portion 51 x is closed with respect to the recess 36 a of the gear case cover 36 except for the ends of the first path 53 and the second path 54. ing.

  This closed portion can be integrally formed when the gear case cover 36 (in other words, the lubricating oil guide portion 51x) is formed. However, a concave portion with one side opened is formed on the inner wall of the gear case cover 36 (similar to the first embodiment), and the above-mentioned closed portion is realized by covering and fixing the open portion with another member. You can also.

  In the connection portion of the first path 53 and the second path 54, a circular intake opening 52x is formed on the inner wall of the recess 36a of the gear case cover 36. This take-in opening 52x is arranged at substantially the same position as the take-in portion 52 of the first embodiment described above. Lubricating oil injected from the injection opening 70 enters the first path 53 and the second path 54 through the intake opening 52x.

  In the direction in which the lubricating oil flows, a first discharge opening 59 and a second discharge opening 60 are formed at the downstream ends of the first path 53 and the second path 54, respectively. The first discharge opening 59 is disposed at the first facing position F1, and the second discharge opening 60 is disposed at the second facing position F2. The lubricating oil that has passed through the first path 53 is applied to the meshing part E1 through the first discharge opening 59. The lubricating oil that has passed through the second path 54 is applied to the meshing portion E <b> 2 through the second discharge opening 60.

  In the present embodiment, the longitudinal intermediate portions of the first path 53 and the second path 54 are partitioned with respect to the recess 36 a of the gear case cover 36. For this reason, the lubricating oil supplied from the intake opening 52x to the lubricating oil guide 51x is in the middle of the gear case cover 36 from the first path 53 or the second path 54 on the way to the discharge openings 59 and 60. There is no escape. Therefore, the lubricating oil can be applied efficiently (concentrated) from the discharge openings 59 and 60 toward the meshing portions E1 and E2.

  The thickness of the lubricating oil flow applied to the meshing portions E1 and E2 is determined by the size of the discharge openings 59 and 60. By making the opening area of the discharge openings 59 and 60 smaller than the opening area of the intake opening 52x, for example, the lubricating oil is injected from the discharge openings 59 and 60 toward the meshing parts E1 and E2. Speed can be increased. Thereby, for example, even when the discharge openings 59 and 60 and the meshing portions E1 and E2 are separated from each other, the lubricating oil can be blown vigorously and the meshing portions E1 and E2 can be well lubricated. .

  The fan 7 for cooling the engine 1 is disposed in the vicinity of the gear case cover 36 as shown in FIG. As the fan 7 rotates, wind is generated, and this wind hits the gear case cover 36. As a result, the heat of the lubricating oil that has entered the lubricating oil guide portion 51 can be released to the outside through the wall portion of the gear case cover 36. Accordingly, the temperature of the lubricating oil can be lowered and the lubricating oil can be supplied to the meshing portions E1 and E2 with a certain degree of viscosity. Noise can be effectively suppressed.

  In the first embodiment described above, the lubricating oil cooling effect by forced air cooling of the gear case cover 36 can be obtained. However, in the present embodiment, the middle portion of the path through which the lubricating oil passes from the intake opening 52x to the discharge openings 59 and 60 is closed with respect to the recess 36a of the gear case cover 36. Accordingly, in the process of passing the lubricating oil through the path, heat exchange is performed by contacting the inner wall of the path over a wide area, so that the lubricating oil can be cooled better.

  As described above, in the engine of the present embodiment, in each of the first path 53 and the second path 54, the supplied lubricating oil is guided to the first facing position F1 or the second facing position F2. Is closed with respect to the recess 36 a of the gear case cover 36.

  Thereby, most of the lubricating oil supplied to the lubricating oil guide portion 51x can be reliably guided to the facing positions F1 and F2 that face the meshing portions E1 and E2 in the axial direction. Therefore, lubricating oil can be used efficiently.

  Further, in the engine of the present embodiment, the intake opening 52x is formed in the lubricant guide portion 51x. Lubricating oil is taken into the lubricating oil guide 51x through the taking-in opening 52x. The first path 53 is formed with a first discharge opening 59 that ejects lubricating oil toward the meshing portion E1 between the idle gear 21 and the crank gear 22. The second path 54 is formed with a second discharge opening 60 that ejects the lubricating oil toward the meshing portion E2 between the idle gear 21 and the cam gear 23. The opening area of the first discharge opening 59 and the opening area of the second discharge opening 60 are both smaller than the opening area of the intake opening 52x.

  Thereby, lubricating oil can be blown off vigorously from the discharge openings 59 and 60, and the meshing portions E1 and E2 can be well lubricated.

  In the engine of the present embodiment, the fan 7 is disposed outside the gear case cover 36. Wind generated by the rotation of the fan 7 strikes the gear case cover 36.

  Accordingly, the temperature of the lubricating oil can be satisfactorily reduced by performing forced air cooling on the lubricating oil passing through the lubricating oil guide portion 51x provided on the cover. As a result, the viscosity of the lubricating oil is increased and the cushioning property is increased, so that the noise reduction effect of the meshing portions E1 and E2 can be enhanced.

  The preferred embodiment of the present invention has been described above, but the above configuration can be modified as follows, for example.

  The lubricating oil guide portions 51 and 51x may be configured by parts other than the gear case cover 36.

  The lubricating oil guide portions 51 and 51x can be changed to a configuration in which three or more routes are branched instead of a configuration in which two routes are branched from one place.

  A plurality of injection openings 70 may be formed in the idle shaft 14. In this case, a plurality of lubricating oil guide portions 51 and 51x can be provided corresponding to the number of injection openings.

  The example of the shape of the gears 81 and 82 shown in FIG. 9 may be applied to, for example, the idle gear 21 and the crank gear 22 of the second embodiment.

  The first path 53 and the second path 54 may be formed in a curved shape instead of being formed in a linear shape.

  The gear case 35 may be integrally formed with the cylinder block 2.

  The meshing portion to be lubricated is not limited to the meshing portion E1 between the idle gear 21 and the crank gear 22 or the meshing portion E2 between the idle gear 21 and the cam gear 23, and lubricates other meshing portions. Therefore, the configuration of the present invention can be applied.

  The present invention can also be used for an engine different from a diesel engine, such as a gasoline engine or a gas engine. The present invention can also be used for, for example, a helical gear other than a spur gear.

1 Engine 7 Fan 14 Idle shaft (support shaft)
21 idle gear (first gear)
22 Crank gear (second gear)
23 Cam gear (3rd gear)
35 Gear case (housing)
36 Gear case cover (cover)
51 Lubricating oil guide part 53 1st path | route 54 2nd path | route 55 Splitting projection part 70 Injection | emission opening part (opening part)
E1, E2 meshing part F1, F2 facing position

Claims (6)

A housing;
A cover fixed to the housing;
The first gear,
A support shaft rotatably supporting the first gear;
A second gear meshing with the first gear;
A third gear meshing with the first gear;
With
The first gear, the support shaft, the second gear, and the third gear are arranged in an accommodation space formed by the housing and the cover,
In the support shaft, an opening for ejecting lubricating oil is formed on a shaft end surface facing the cover,
The cover is provided with a lubricant guide portion,
The lubricant guide portion is
The lubricating oil supplied from the opening is guided to a first facing position that substantially faces the meshing portion of the first gear and the second gear in the axial direction, and from the first facing position to the first gear. And a first path for applying lubricating oil toward the meshing portion of the second gear,
The lubricating oil supplied from the opening is guided to a second facing position that substantially faces the meshing portion of the first gear and the third gear in the axial direction, and from the second facing position to the first gear. And a second path for applying lubricating oil toward the meshing portion of the second gear,
Have
The engine, wherein the first path and the second path are connected to each other. The engine according to claim 1,
The engine, wherein the lubricant guide portion is provided with a diverting protrusion at a location where the first path and the second path are connected. The engine according to claim 1 or 2,
In each of the first path and the second path, all of the paths through which the supplied lubricating oil is guided to the first facing position or the second facing position are opened to the internal space of the cover. An engine characterized by The engine according to claim 1 or 2,
In each of the first path and the second path, at least a part of the path where the supplied lubricating oil is guided to the first facing position or the second facing position is closed with respect to the internal space of the cover. Engine characterized by being. The engine according to claim 4,
The lubricating oil guide portion is formed with an intake opening for taking the lubricating oil into the lubricating oil guide portion.
The first path is formed with a first discharge opening that ejects lubricating oil toward the meshing portion of the first gear and the second gear,
The second path is formed with a second discharge opening that ejects lubricating oil toward the meshing portion of the first gear and the third gear,
The engine characterized in that the opening area of the first discharge opening and the opening area of the second discharge opening are both smaller than the opening area of the intake opening. The engine according to any one of claims 1 to 5,
A fan is disposed outside the cover;
An engine characterized in that wind generated by rotation of the fan strikes the cover.

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