VEHICLE ENGINE

Abstract

A vehicle engine includes: a cylinder head; a cam housing fixed to a top of the cylinder head; a cam cap fixed to a top of the cam housing; a camshaft rotatably supported between the cam housing and the cam cap, the camshaft supporting a cam; a rocker arm configured to be pushed by the cam; and a valve configured to operate by being pushed by the rocker arm; and an oil pipe that is formed integrally with the cam cap. Lubricant oil is supplied through the oil pipe to a contact point between the cam and the rocker arm.

Description

CROSS REFERENCE TO RELATED APPLICATION

This application claims priority from Japanese Patent Application No. 2009-236226 filed on Oct. 13, 2009. The entire content of this priority application is incorporated herein by reference.

TECHNICAL FIELD

The present invention relates to a vehicle engine.

BACKGROUND

A typical vehicle engine includes a cylinder head, a cam housing, a cam cap, camshafts, rocker arms, and valves. The cam housing is fixed to a top of the cylinder head. The cam cap is fixed to a top of the cam housing. The camshafts are rotatably supported between the cam housing and the cam cap. Each camshaft supports cams. The cams push the rocker arms, while the rocker arms push the valves so that the valves operate. One of such typical vehicle engines further includes a shower pipe wherethrough lubricant oil is supplied to contact points between the cams and the rocker arms.

The shower pipe is generally a separate part attached to the cam cap or to a head cover that covers the top of the cam cap. That is, a part separate from the cam cap or from the head cover is necessary as the shower pipe. The parts count of the vehicle engine is higher accordingly.

Thus, there is a need for a vehicle engine with a lower parts count.

SUMMARY

An aspect in accordance with the present invention is a vehicle engine including: a cylinder head; a cam housing fixed to a top of the cylinder head; a cam cap fixed to atop of the cam housing; a camshaft rotatably supported between the cam housing and the cam cap, the camshaft supporting a cam; a rocker arm configured to be pushed by the cam; a valve configured to operate by being pushed by the rocker arm; and an oil pipe configured to supply lubricant oil to a contact point between the cam and the rocker arm. The oil pipe is formed integrally with the cam cap.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view of a vehicle engine of a first embodiment, illustrating a state before the cam cap is mounted to the cam housing;

FIG. 2 is a sectional view of the vehicle engine of the first embodiment, illustrating a state after the cam cap is mounted to the cam housing;

FIG. 3 is a perspective view of the cam housing, a camshaft, and the cam cap of the first embodiment;

FIG. 4 is a sectional view of a vehicle engine of a second embodiment, illustrating a state before a cam cap is mounted to the cam housing;

FIG. 5 is a sectional view of the vehicle engine of the second embodiment, illustrating a state after the cam cap is mounted to the cam housing; and

FIG. 6 is a perspective view of the cam housing, a camshaft, and a cam cap of the second embodiment.

DETAILED DESCRIPTION

<First Embodiment>

A first embodiment in accordance with the present invention will be described with the drawings.

As illustrated in FIGS. 1 and 2, a vehicle engine 10 of this embodiment includes a cylinder head (not illustrated in the drawings), a cam housing 12, a cam cap 14, camshafts 16, rocker arms 20, and valves 22. The cam housing 12 is fixed to a top of the cylinder head. The cam cap 14 is fixed to a top of the cam housing 12. Each camshaft 16 is rotatably supported between the cam housing 12 and the cam cap 14. The camshaft 16 supports cams 18. The cams 18 push the rocker arms 20. The rocker arms 20 push the valves 22 so that the valves 22 operate. The vehicle engine 10 is a so-called DOHC engine, including the left and right camshafts 16 for operating the intake and exhaust valves 22, respectively.

The cam housing 12 is bolted on the top of the cylinder head. The cam housing 12 accommodates the rocker arms 20, the valves 22, lash adjusters 24, and valve springs 26. An end of each rocker arm 20 is supported from below by the corresponding lash adjuster 24, while the other end contacts a stem 22a of the corresponding valve 22 from above. As a crankshaft (not illustrated in the drawings) rotates, the camshafts 16 rotate so that the cams 18 push down rollers 20a of the rocker arms 20. Then, the rocker arms 20 swing up and down about top ends of the lash adjusters 24 while reciprocating the valves 22 up and down against the elastic forces of the valve springs 26. Thus, the camshafts 16, the cams 18, the rocker arms 20, the lash adjusters 24, and the valve springs 26 are accommodated in the cam housing 12 and configure a valve train for operating the valves 22.

The cam cap 14 is bolted on the top of the cam housing 12. The cam housing 12 and the cam cap 14 are made of metal such as aluminium alloy. The cam housing 12 and the cam cap 14 can be manufactured by, for example, die casting.

As illustrated in FIG. 3, the cam housing 12 includes a rectangular outer frame 12a and partitions 12b. The outer frame 12a defines a space, while the partitions 12b partition the space into a plurality of subspaces. Similar to this, the cam cap 14 includes a rectangular outer frame 14a and partitions 14b. The outer frame 14a defines a space, while the partitions 14b partition the space into a plurality of subspaces. Each of the subspaces defined by the partitions 12b, 14b accommodates the valve train components for operating the cylinder valves 22 of the vehicle engine 10.

Each camshaft 16 is a round bar made with metallic material such as JIS STKM (Carbon Steel Tubes for Machine Structural Purposes). The plurality of cams 18 are integrally provided on the circumference of the camshaft 16. The cams 18 are arranged in the axial direction of the camshaft 16.

Each camshaft 16 is rotatably supported between the cam housing 12 and the cam cap 14. Specifically, the camshaft 16 is rotatably supported between bearing recesses 28 and bearing recesses 30. Each of the bearing recesses 28, 30 is generally semicircular in cross section. The bearing recesses 28 are formed in the top face of the cam housing 12. The bearing recesses 30 are formed in the bottom face of the cam cap 14 (see FIG. 1).

Two oil pipes 32 are integral parts of the cam cap 14. Through the oil pipes 32, lubricant oil (hereinafter simply referred to as “oil”) is supplied to the contact points between the cams 18 and the rollers 20a of the rocker arms 20. The oil pipes 32 can be formed integrally with the cam cap 14 in, for example, a die-casting process for manufacturing the cam cap 14. The oil pipes 32 extend substantially parallel to the axial direction of the camshafts 16 and through the thicknesses of the partitions 14b. The oil pipe 32 has a center hole 34 running through the axis thereof. The center hole 34 is bored with a tool such as a drill. The center hole 34 is an oil flow path.

The oil pipe 32 has a plurality of oil holes 36 arranged at predetermined intervals in the axial direction of the oil pipe 32. Each oil hole 36 is approximately from 1 mm to 2 mm in diameter. The oil hole 36 runs through the thickness of the pipe wall of the oil pipe 32, obliquely downward from the center hole 34.

An oil pump pumps up oil from an oil pan. The oil is then forced through an oil gallery (not illustrated in the drawings) in the cam housing 12 and in the cam cap 14 to the oil pipes 32, and then is injected from the oil holes 36 toward the cams 18 and the rocker arms 20. Thus, oil is supplied to the contact points between the cams 18 and the rocker arms 20.

In a state where the cam cap 14 is mounted to the cam housing 12 as illustrated in FIG. 2, the oil pipes 32 are located above the cams 18. Accordingly, even in the event of lower oil pressure in the oil pipes 32 due to oil pump trouble etc., the oil in the oil pipes 32 can fall by its own weight from the oil holes 36. Oil can thus be continuously supplied to the contact points between the cams 18 and the rocker arms 20.

As described above, the vehicle engine 10 of this embodiment includes the oil pipes 32 that are provided integrally with the cam cap 14. Therefore, no member separate from the cam cap 14 or from the head cover is necessary as the oil pipes 32. The parts count of the vehicle engine 10 can be lower accordingly.

<Second Embodiment>

A second embodiment in accordance with the present invention will be described with reference to the drawings.

A vehicle engine 50 of this embodiment differs from the engine 10 of the first embodiment in the configuration of the cam cap and the oil pipe. The other configurations are similar to the first embodiment. Accordingly, the components similar to those of the first embodiment will be designated with the same reference characters, while the description will be omitted.

As illustrated in FIGS. 4 through 6, the vehicle engine 50 includes a plurality of plate-like bodies 54 that configure a cam cap 52. The plate-like bodies 54 are bolted on a top of the cam housing 12. The plate-like bodies 54 partition the plurality of cams 18 into groups of two cams 18. The plate-like bodies 54 are made by metallic material such as aluminium alloy. The plate-like bodies 54 can be manufactured by, for example, die casting.

Each camshaft 16 is rotatably supported between the cam housing 12 and the cam cap 52. Specifically, the camshaft 16 is rotatably supported between the bearing recesses 28 and bearing recesses 58. Each of the bearing recesses 28, 58 is generally semicircular in cross section. The bearing recesses 28 are formed in the top face of the cam housing 12. The bearing recesses 58 are formed in the bottom faces of the plate-like bodies 54.

Oil pipes 60 are integral parts of the respective plate-like bodies 54. The oil pipes 60 are disposed on the top face of the respective plate-like bodies 54. Through the oil pipes 60, oil is supplied to the contact points between the cams 18 and the rollers 20a of the rocker arms 20. The oil pipe 60 can be formed integrally with the plate-like bodies 54 in, for example, a die-casting process for manufacturing the plate-like bodies 54. The oil pipes 60 extend substantially parallel to the axial direction of the camshafts 16. The oil pipe 60 has a center hole 62 running through the axis thereof. The center hole 62 is bored with a tool such as a drill. The center hole 62 is an oil flow path. The center hole 62 is open-ended in the two ends of the oil pipe 60.

The oil pump pumps up oil from an oil pan. The oil is then forced through the oil gallery (not illustrated in the drawings) in the cam housing 12 and in the cam cap 52 to the oil pipes 60, and then falls from both ends of the oil pipes 60 toward the cams 18 and the rocker arms 20. Thus, oil is supplied to the contact points between the cams 18 and the rocker arms 20.

In the state where the cam cap 52 is mounted to the cam housing 12 as illustrated in FIG. 5, the oil pipes 60 are located above the cams 18. Accordingly, even in the event of lower oil pressure in the oil pipes 60 due to oil pump trouble, the oil in the oil pipes 60 can fall by its own weight from the both ends of the oil pipes 60. Oil can thus be continuously supplied to the contact points between the cams 18 and the rocker arms 20.

As described above, the vehicle engine 50 of this embodiment includes the oil pipes 60 that are provided integrally with the cam cap 52. Therefore, no member separate from the cam cap 52 or from the head cover is necessary as the oil pipes 60. The parts count of the vehicle engine 50 can be lower accordingly.

Claims

1. A vehicle engine comprising: a cylinder head;a cam housing fixed to a top of the cylinder head;a cam cap fixed to a top of the cam housing;a camshaft rotatably supported between the cam housing and the cam cap, the camshaft supporting a cam;a rocker arm configured to be pushed by the cam; anda valve configured to operate by being pushed by the rocker arm;the vehicle engine being characterized by: an oil pipe that is formed integrally with the cam cap,wherein lubricant oil is supplied through the oil pipe to a contact point between the cam and the rocker arm.