The present invention relates to an oil supply structure for a timing chain system provided to an engine or the like.
As described in the following Patent Document 1, there has been known, as a means for fixing an oil jet without using bolts, a configuration in which a pressing part extending along an output shaft of an engine is provided to a timing chain cover so as to press a portion opposite to a cylinder block-side end of the oil jet.
Furthermore, the following Patent Document 2 describes a configuration in which an oil jet is arranged in the vicinity of a meshing point between a crankshaft sprocket wheel and a timing chain, and an end of the oil jet that is remote from a cylinder block is supported on a timing chain cover.
PATENT DOCUMENT 1: Japanese Unexamined Patent Publication No. 2004-346895 (see FIG. 13)
PATENT DOCUMENT 2: Japanese Unexamined Patent Publication No.2000-282829 (see FIG. 1)
In the invention described in Patent Document 1, the end portion of the oil jet that is adjacent to the cylinder block (hereinafter, also simply referred to as a block) is attached to an engine body. Consequently, a vibration generated when the engine is in operation may be transmitted to the timing chain cover via the oil jet, and the timing chain cover may emit a radiation sound.
As a method for reducing the emission of the radiation sound, it is conceivable to rigidly fasten, to the block with a bolt or the like, a vibration source (i.e., the peripheral portion of the pressing part in Patent Document 1) that transmits a vibration to the timing chain cover.
However, if the oil jet is intended to be arranged close to the timing chain in order to reliably supply the oil injected from the oil jet to the timing chain, it is difficult to provide a boss hole for bolt fastening in the proximity of the oil jet due to the positional relation between the timing chain and the sprocket wheel.
On the other hand, on the assumption that the invention of Patent Document 2 is applied to the so-called rear chain system in which a timing chain system is arranged adjacent to the transmission, a flywheel fastening plate is arranged at a position on an output shaft of the engine, the position being closer to the transmission than the sprocket wheel is, and facing the cover surface of the timing chain cover. In such a case, the cover surface is provided with a plate support that supports the flywheel fastening plate in a rotatable manner, and hence, it is impossible to elongate the outer shape of the oil jet so that the oil jet is supported on the timing chain cover, as described in Patent Document 2.
Here, in the invention described in Patent Document 1, if the pressing part is intended to be elongated from the timing chain cover, the pressing part needs to be formed from a radially outer side of a plate support, undesirably resulting in not only complication of the shape of the pressing part, but also an increase in the overall length of the engine body.
The present invention has been made to overcome the above-mentioned conventional drawbacks. It is an object of the present invention to enable an oil jet to be supported without using a bolt while reducing emission of a radiation sound from a timing chain cover. It is also an object of the present invention to achieve an oil supply structure for a timing chain system that is capable of supporting the oil jet, while avoiding dependence on a structure in a vicinity of the timing chain and the oil jet, and an increase in an overall length of an engine body.
To achieve the above object, the present invention provides a configuration in which: a timing chain cover is arranged in a spaced apart manner from a side, of an engine body, where a timing chain is arranged; a pressing part is arranged at a predetermined distance from the timing chain cover; and an end portion, of an oil jet, which is remote from a cylinder block is pressed by the pressing part.
Specifically, the present invention is directed to an oil supply structure for a timing chain system, and takes the following measures.
That is, a first aspect of the present invention is directed to an oil supply structure for a timing chain system including: a timing chain configured to be driven by an output shaft of an engine body; and an oil jet configured to supply oil to the timing chain. The engine body is provided with a timing chain cover covering a side, of the engine body, where the timing chain is arranged, the timing chain cover being spaced apart from the side of the engine body. The oil jet is a hollow member extending in an output shaft direction in which the output shaft of the engine body extends, the oil jet including therein an oil passage. One end portion of the oil jet in the output shaft direction of the engine body is supported in a support hole formed in the engine body, whereas an other end portion of the oil jet in the output shaft direction of the engine body extends toward the timing chain cover to an extent that the other end portion of the oil jet does not come into contact with the timing chain cover. A pressing part spaced apart from the timing chain cover in the output shaft direction is arranged between the other end portion of the oil jet and the timing chain cover in the output shaft direction, and the pressing part is in contact with the other end portion of the oil jet.
As can be seen, the timing chain cover covers an engine while being arranged in a spaced apart manner from the side where the timing chain is arranged, and at the same time, the pressing part spaced apart from the timing chain cover in the output shaft direction is arranged between the outer end portion of the oil jet and the timing chain cover, the pressing part being in contact with the outer end portion of the oil jet. Consequently, a vibration generated when the engine is in operation can be prevented from being transmitted to the timing chain cover via the oil jet, thereby reducing emission of a radiation sound from the timing chain cover. Furthermore, the pressing part is in contact with the other end portion (outer end portion) of the oil jet, and hence, the number of working processes of the assembly of the engine is not increased.
In addition, the other end portion of the oil jet is in contact with, and supported on, the pressing part arranged in a spaced apart manner from the timing chain cover in the output shaft direction. Thus, the oil jet can be supported without depending on a structure in the vicinity of the timing chain and the oil jet, and without increasing the overall length of the engine body.
A second aspect of present invention is an embodiment of in the first aspect. In the second aspect, the engine body has a chain guide configured to guide traveling of the timing chain, and the pressing part is formed integrally with the chain guide.
With this configuration, in which the pressing part is formed integrally with the chain guide, additional parts for forming the pressing part are no longer necessary.
A third aspect of the present invention is an embodiment of the second aspect. In the third aspect, as viewed from above the engine body, one end, of the pressing part, which is adjacent to the chain guide is more spaced apart from the engine body than an other end of the pressing part is.
With this configuration, in which one end of the pressing part that is adjacent to the chain guide is more spaced apart from the engine body than the other end of the pressing part is, the pressing part is in contact with the other end portion of the oil jet, while being displaced relative to the other end portion of the oil jet in the direction away from the engine body (in an outward direction). As a result, a pressing force that acts on the oil jet in the axial direction of the oil jet is easily generated, enabling the oil jet to be supported appropriately.
A fourth aspect of the present invention is an embodiment of the second or third aspect. In the fourth aspect, the pressing part is comprised of a plate member.
With this configuration, in which the pressing part is comprised of a plate member that laterally presses the other end portion of the oil jet, the pressing part acts as a leaf spring. That is, the pressing part uses the action of leaf spring to press the other end portion of the oil jet with a suitable force.
A fifth aspect of the present invention is an embodiment of the fourth aspect. In the fifth aspect, as viewed from above the engine body, the other end of the pressing part is displaced toward the timing chain cover in the output shaft direction relative to the one end of the pressing part.
With this configuration, the pressing part is in contact with the other end portion of the oil jet at an angle corresponding to the displacement toward the timing chain cover side in the output shaft direction. As a result, a pressing force that acts on the oil jet in the axial direction of the oil jet is easily generated, enabling the oil jet to be supported appropriately.
A sixth aspect of the present invention is an embodiment of the second aspect. In the sixth aspect, the chain guide has a bolt hole via which the chain guide is fastened to the engine body, the bolt hole is arranged in a portion of the chain guide, the portion is close to the other end portion of the oil jet, and the pressing part extends from a part close to the bolt hole.
With this configuration, the action of leaf spring can be obtained further effectively particularly when the pressing part is comprised of a plate member.
A seventh aspect of the present invention is an embodiment of the second aspect. In the seventh aspect, the pressing part has a width substantially equal to a width of the other end portion of the oil jet.
With this configuration, the pressing part can be formed in a compact shape. Even when the area surrounded by the timing chain is narrow, the pressing part having such a compact shape can be arranged outside an area where the timing chain flutters.
An eighth aspect of the present invention is an embodiment of the first aspect. In the eighth aspect, the timing chain meshes with a first sprocket wheel arranged on the output shaft, and the oil jet is arranged in a vicinity of a meshing point between the timing chain and the first sprocket wheel.
This configuration, in which the distance from the oil jet to the first sprocket wheel and the timing chain can be reduced, makes it possible to lower the hydraulic pressure of an oil pump. As a result, improvement of the fuel consumption of the engine can be achieved.
A ninth aspect of the present invention is an embodiment of the first aspect. In the ninth aspect, the timing chain system is arranged on a transmission attaching side provided on one end of the engine body in the output shaft direction, the side of the engine body where the timing chain is arranged has a first sprocket wheel arranged on one end of the output shaft, and a flywheel fastening plate arranged on the output shaft and being closer to a transmission than the first sprocket wheel is, the first sprocket wheel and the flywheel fastening plate being located between the engine body and the timing chain cover in the output shaft direction, and the oil jet is arranged to overlap with the flywheel fastening plate as viewed in the output shaft direction.
With this configuration, the present invention is also applicable to the so-called rear chain system in which the timing chain system is arranged on a side adjacent to the transmission.
A tenth aspect of the present invention is an embodiment of the ninth aspect. In the tenth aspect, a second sprocket wheel coaxial with the first sprocket wheel is arranged between the first sprocket wheel and the flywheel fastening plate, and in the output shaft direction of the engine body, the other end portion of the oil jet is located closer to the engine body than the second sprocket wheel is.
With this configuration, the other end portion of the oil jet that is located outward is not positioned above the second sprocket wheel remote from the engine body, but positioned above the first sprocket wheel close to the engine body. Thus, the oil jet can be formed to have a small length. As a result, the durability of the oil jet pressed by the pressing part and the engine body can be ensured.
According to the present invention, an oil supply structure for a timing chain system can be achieved, the oil supply structure being capable of supporting the oil jet without using a bolt while reducing emission of a radiation sound from the timing chain cover and, at the same time, being capable of supporting the oil jet without depending on the structure in the vicinity of the timing chain, the oil jet, and the like, and without increasing the overall length of the engine body.
Embodiments of the present invention will be described in detail below with reference to drawings. Note that the embodiments described below are merely preferred examples in nature, and are not intended to limit the scope, application, or uses of the present invention.
(First Embodiment)
The first embodiment of the present invention will be described with reference to the drawings.
As illustrated in
A cylinder head 3 coupled to the upper side of the cylinder block 2 is provided with an inlet camshaft 14 and an exhaust camshaft 15 that extend parallel to each other in the axial direction of the crankshaft 10. An inlet cam sprocket wheel 16 and an exhaust cam sprocket wheel 17 are attached to an end of the inlet camshaft 14 and an end of the exhaust camshaft 15, respectively. At least one of the inlet cam sprocket wheel 16 or the exhaust cam sprocket wheel 17 may be provided with a variable valve timing (VVT) mechanism.
The cylinder block 2 is provided, in a side portion thereof, with a fuel pump drive shaft 18, a fuel pump sprocket wheel 19 attached to a portion, of the fuel pump drive shaft 18, which is adjacent to the cylinder block 2, and a cam chain sprocket wheel 20 attached to a portion, of the fuel pump drive shaft 18, which is located outside with respect to the fuel pump sprocket wheel 19.
The timing chain 30 is wrapped around the crankshaft sprocket wheel 11 and the fuel pump sprocket wheel 19. Furthermore, a cam chain 32 is wrapped around the inlet cam sprocket wheel 16, the exhaust cam sprocket wheel 17, and the cam chain sprocket wheel 20.
A lower cylinder block 4 is coupled to the lower side of the cylinder block 2. An oil pump drive shaft 21, and an oil pump sprocket wheel 22 attached to the oil pump drive shaft 21 are arranged below the lower cylinder block 4.
A timing chain guide 33 that guides the traveling of the timing chain 30 in a tension-side span between the crankshaft 10 and the fuel pump drive shaft 18 is attached to the cylinder block 2. The timing chain guide 33 has, at its end close to a bolt 43 located adjacent to the crankshaft 10, a pressing part 33a extending from the end to the vicinity of a meshing point between the timing chain 30 and the crankshaft sprocket wheel 11. An oil jet 50 is provided adjacent to the back side (the side adjacent to the engine body) of the pressing part 33a. The oil jet 50 includes therein an oil passage, and injects a lubricant (oil) to the meshing point between the timing chain 30 and the crankshaft sprocket wheel 11. An end portion, of the oil jet 50, which is located adjacent to the cylinder block 2, is fitted in a hole (support hole) which is formed in the cylinder block 2 and in which an oil passage extends. The pressing part 33a of the timing chain guide 33 is in contact with an outer end portion of the oil jet 50 (the end remote from the cylinder block 2) so as to support the oil jet 50. Therefore, the end portion of the oil jet 50 that is located outside in the output shaft direction of the engine 1 is out of contact with a timing chain cover 42 (see
In a loose-side span of the timing chain 30 between the crankshaft 10 and the fuel pump drive shaft 18, a timing chain tensioner (hydraulic auto-tensioner) 35 that gives a tension to a loose side of the timing chain 30 via a timing chain tensioner arm 34 is held on the cylinder block 2.
Likewise, a cam chain guide 36 that guides the traveling of the cam chain 32 in a tension-side span between the fuel pump drive shaft 18 and the inlet camshaft 14 is held on the cylinder block 2. Furthermore, in a loose-side span of the cam chain 32 between the fuel pump drive shaft 18 and the exhaust camshaft 15, a cam chain tensioner (hydraulic auto-tensioner) 38 that gives a tension to a loose side of the cam chain 32 via a cam chain tensioner arm 37 is held on the cylinder block 2.
An oil pump chain guide 39 that guides the traveling of the oil pump chain 31 in a tension-side span between the crankshaft 10 and the oil pump drive shaft 21 is held on the lower cylinder block 4. Furthermore, in a loose-side span of the oil pump chain 31 between the crankshaft 10 and the oil pump drive shaft 21, an oil pump chain tensioner arm 40 that gives a tension to a loose side of the oil pump chain 31 is held on the lower cylinder block 4.
The engine 1 illustrated in
(Configurations of Pressing Part of Timing Chain Guide, and Oil Jet)
As illustrated in
As illustrated in
On the other hand,
Furthermore, as illustrated in
Furthermore, the pressing part 33a is formed to have a width substantially equal to the width of the second end portion 50c of the oil jet 50. Consequently, the pressing part 33a can be formed in a compact shape. As a result, even when the area surrounded by the timing chain 30 and the crankshaft sprocket wheel 11 is narrow, the pressing part 33a can be arranged outside an area where the timing chain 30 flutters. Note that the tops of the bolts 43 of the timing chain guide 33 according to this embodiment are kept out of contact with the timing chain cover 42.
Furthermore, in this embodiment, the crankshaft 10 is provided with the crankshaft sprocket wheel 11 as the first sprocket wheel located adjacent to the engine 1, and the oil pump chain sprocket wheel 12 as the second sprocket wheel located outside with respect to the crankshaft sprocket wheel 11. The oil jet 50 according to this embodiment is arranged in the vicinity of the meshing point of the crankshaft sprocket wheel 11 that is located inward (adjacent to the engine 1). This arrangement reduces the distance from the oil jet 50 to the crankshaft sprocket wheel 11 and the timing chain 30. As a result, oil can be supplied to where the oil is needed more reliably in this embodiment than in a case where the distance from the oil jet 50 to the crankshaft sprocket wheel 11 and the timing chain 30 is long. Consequently, an amount of oil to be supplied to the oil jet 50 can be relatively reduced, thereby lowering the hydraulic pressure of the oil pump.
In addition, as illustrated in
As described above, according to this embodiment, the oil supply structure for the timing chain 30 can be achieved, the oil supply structure being capable of supporting the oil jet 50 without using a bolt or the like, that is, without a dedicated boss hole formed in the cylinder block 2, while reducing emission of a radiation sound from the timing chain cover 42 due to the oil jet 50.
(Second Embodiment)
An oil supply structure for a timing chain system according to a second embodiment of the present invention is described with reference to the drawing.
As illustrated in
With the pressing part 33b configured in this manner, although the oil jet 50 cannot be arranged in the vicinity of the meshing point between the crankshaft sprocket wheel 11 and the timing chain 30, a pressing part 33a which would project from the timing chain guide 33A is no longer necessary, thereby achieving simple specifications and easy manufacturing of the timing chain guide 33A.
With the timing chain guide 33A having this configuration, just like the first embodiment, an oil supply structure for the timing chain 30 can be achieved, the oil supply structure being capable of supporting the oil jet 50 without using a bolt or the like, while reducing emission of a radiation sound from the timing chain cover 42 due to the oil jet 50.
(Other Embodiments)
The oil supply structure for the timing chain system according to each of the first and second embodiments includes the timing chain 30 on the transmission-facing side of the engine for vehicle. However, the present invention is also applicable to an oil supply system for a timing chain of the so-called front chain system, in which the timing chain 30 is arranged on a side remote from a transmission, i.e., on the front side of the engine.
The oil supply structure for the timing chain system according to the present invention is useful as an oil supply structure capable of reducing a radiation sound generated due to the supporting structure of an oil jet and, at the same time, capable of supporting easily the oil jet without depending on the structure of surrounding components such as the timing chain and the oil jet and without increasing the overall length of an engine body.
1 Engine (Engine Body)
2 Cylinder Block
3 Cylinder Head
10 Crankshaft
11 Crankshaft Sprocket Wheel (First Sprocket Wheel)
12 Oil Pump Chain Sprocket Wheel (Second Sprocket Wheel)
13 Flywheel Fastening Plate
18 Fuel Pump Drive Shaft
19 Fuel Pump Sprocket Wheel
20 Cam Chain Sprocket Wheel
21 Oil Pump Drive Shaft
22 Oil Pump Sprocket Wheel
30 Timing Chain
31 Oil Pump Chain
32 Cam Chain
33 Timing Chain Guide
33
a Pressing Part
33A Timing Chain Guide
33
b Pressing Part
33
c Sliding Part
34 Timing Chain Tensioner Arm
35 Timing Chain Tensioner
42 Timing Chain Cover
42
a Plate Support
43 Bolt
50 Oil Jet
50
a Opening
50
b First End Portion (One End Portion)
50
c Second End Portion (Other End Portion)
50
d Oil Injection Opening
50
e Anti-Rotation Projection
50
f Anti-Rotation Holder
Number | Date | Country | Kind |
---|---|---|---|
JP2016-229049 | Nov 2016 | JP | national |
JP2016-229050 | Nov 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/037529 | 10/17/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2018/096842 | 5/31/2018 | WO | A |
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20170037956 | Mishima | Feb 2017 | A1 |
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10021220 | Oct 2001 | DE |
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Number | Date | Country | |
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20200063615 A1 | Feb 2020 | US |