JP5293208B2 - Engine valve mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make compatible the supply of a lubricating oil to the sliding portion between a drive cam 112 and a link arm 12 and the maintenance of the contact area of the sliding portion. <P>SOLUTION: The lubricating oil in the main oil passage 31 of a drive shaft 11 is supplied to the drive portion between the drive cam 112 and the link arm 12 fitted to the outer peripheral surface of the drive cam 112 so as to be rotated relative to each other through an oil hole 28 provided to a fixing pin 18 for affixing the drive cam 112 to the drive shaft 11. The drive cam 112 comprises a drive shaft through hole 24 and a linear first through hole 25 orthogonal to the drive shaft through hole 24. The first through hole 25 comprises a first hole section 26 into which the fixing pin 18 is press-fitted and a second hole section 27 having a smaller diameter than the first hole section 26. Consequently, the supply of the lubricating oil to the sliding portion between the drive cam 112 and the link arm 12 and the maintenance of the contact area of the sliding portion can be made compatible. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a valve operating mechanism for an engine capable of varying a valve lift amount.

  Patent Document 1 discloses a control shaft that rotates in conjunction with a crankshaft of an engine and that is eccentric to the axis of the drive shaft and is fixed to the outer periphery of the drive shaft and is substantially parallel to the drive shaft. A control shaft provided on the outer periphery, a swing cam that is externally fitted to the outer periphery of the drive shaft to drive the intake and exhaust valves, and a link arm that is externally fitted to the outer periphery of the eccentric cam so as to be relatively rotatable. A link mechanism that mechanically links the eccentric cam and the swing cam via a control cam, and by rotating the control shaft within a predetermined angular range, the attitude of the link mechanism There is disclosed a variable valve operating apparatus for an internal combustion engine that changes the valve lift characteristic of the intake and exhaust valves by changing the valve.

  In this Patent Document 1, the eccentric cam has a substantially constant axial width, and its outer peripheral surface forms a cam surface that is in sliding contact with the bearing portion on the link arm side. Are provided with pin holes into which fixing pins for fixing the two are fitted, respectively, along the direction orthogonal to the axis, and an opening portion of the pin hole of the eccentric cam is formed on the cam surface of the eccentric cam. The lubricating oil is supplied to the cam surface of the eccentric cam, in other words, the sliding portion between the eccentric cam and the link arm from the main oil passage inside the drive shaft through the opening of the pin hole. Yes.

  And in this patent document 1, the pin hole which fits into the said fixing pin was formed in the bag hole (stop hole) by which the one end was closed inside the said eccentric cam, and the one formed in the said eccentric cam. Are disclosed.

JP 2001-234721 A

  However, if the pin hole to be fitted to the fixed pin is a bag hole type, only one pin hole opening is formed at the sliding portion between the eccentric cam and the link arm. On the other side, there is a possibility that sufficient lubricating oil cannot be supplied, and there is a risk of causing seizure or the like due to poor lubrication.

  Further, in the case where the pin hole that fits into the fixed pin passes through the eccentric cam, both ends of the pin hole are open at the sliding portion between the eccentric cam and the link arm. Although the above-mentioned pin hole has a better lubrication performance than the bag hole type, the sliding portion between the eccentric cam and the link arm is increased as the pin hole increases compared to the pin hole type. There is a possibility that the sliding width decreases and the PV value (P: contact pressure, V: sliding speed) increases.

  That is, in the case where the pin hole that fits into the fixed pin passes through the eccentric cam, the PV value increases as compared to the pin hole having a bag hole type, so the eccentric cam and the link arm The amount of heat generated in the sliding portion of the sliding portion will increase relatively, and if this amount of heat exceeds the cooling capacity by the lubricating oil supplied from the pin hole, the temperature of the sliding portion gradually increases, Eventually, burn-in may occur.

  Accordingly, the present invention provides a drive shaft having a main oil passage formed therein, a drive cam fixed to the drive shaft by a fixing pin, and a link arm fitted to the outer peripheral surface of the drive cam so as to be relatively rotatable. A rotatable control shaft provided in parallel with the drive shaft and having a main shaft portion and an eccentric cam portion; and a swing arm rotatably mounted on the eccentric cam portion and swung by the link arm; A link rod linked to the swing arm, and a swing cam rotatably supported by the drive shaft and connected to the swing arm via the link rod to press the valve. In a valve operating mechanism of an engine that supplies lubricating oil in a main oil passage of the drive shaft to a sliding portion between the drive cam and a link arm through an oil hole provided in the fixed pin, the drive cam includes The drive shaft penetrates A dynamic shaft through hole and a linear first through hole orthogonal to the drive shaft through hole are formed. The first through hole includes a first hole portion into which the fixing pin is press-fitted, and the first through hole. And a second hole portion having a hole diameter smaller than the hole diameter of the one hole portion.

  Thereby, it is possible to achieve both the supply of lubricating oil to the sliding portion between the drive cam and the link arm and the securing of the contact area of the sliding portion.

The explanatory view showing typically the valve mechanism of the engine concerning the present invention. The front view of the link arm which comprises the valve mechanism of the engine which concerns on this invention. It is a perspective view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the drive cam in 1st Embodiment of this invention. It is a front view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The front view of the drive cam in 1st Embodiment of this invention. It is a perspective view of the fixed pin which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the fixed pin in 1st Embodiment of this invention. Explanatory drawing which shows the relationship between the drive cam which comprises the valve mechanism of the engine which concerns on this invention, and a fixed pin. Compare the valve operating mechanism in which the link arm and link rod are connected to the swing arm with the control shaft in between, and the valve operating mechanism in which the link arm and link rod are connected to the swing arm on the same side of the control shaft. (A-1) is a side view showing the state of the link when the valve is opened in the valve mechanism in which the link arm and the link rod are connected to the swing arm across the control shaft. (A-2) is a front view of the valve mechanism shown in (A-1). (B-1) is a motion in which the link arm and the link rod are connected to the swing arm on the same side with respect to the control shaft. The side view which shows the state of the link when opening a valve in a valve mechanism, (B-2) is a front view of the valve mechanism shown in (B-1). It is explanatory drawing which showed typically the contact load which acts on the outer peripheral surface of the drive cam which comprises the valve mechanism of the engine which concerns on this invention, (a) is explanatory drawing when an engine speed is low speed, (b) ) Is an explanatory diagram when the engine speed is high. It is a perspective view of the drive cam which comprises the valve mechanism of the engine which concerns on this invention, Comprising: The perspective view of the drive cam in 2nd Embodiment of this invention. It is a side view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The side view of the drive cam in 2nd Embodiment of this invention. It is a perspective view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the drive cam in 3rd Embodiment of this invention. It is a front view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The front view of the drive cam in 3rd Embodiment of this invention. Explanatory drawing which shows the place where a contact load generate | occur | produces strongly when not considering the deformation | transformation of a link arm when the load of a tension | tensile_strength acts on a link arm. Explanatory drawing which shows the place where a contact load generate | occur | produces strongly when the deformation | transformation of a link arm is considered when the load of a tensile direction acts on a link arm. Explanatory drawing which shows the place where a contact load generate | occur | produces strongly when not considering the deformation | transformation of a link arm when the load of a compression direction acts on a link arm. It is a front view of the drive cam which comprises the valve mechanism of the engine which concerns on this invention, Comprising: The front view of the drive cam in 4th Embodiment of this invention. It is a perspective view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the drive cam in 5th Embodiment of this invention. It is a front view of the drive cam which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The front view of the drive cam in 5th Embodiment of this invention. It is a perspective view of the fixed pin which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the fixed pin in 6th Embodiment of this invention. It is a perspective view of the fixed pin which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the fixed pin in 7th Embodiment of this invention. It is a perspective view of the fixed pin which comprises the valve operating mechanism of the engine which concerns on this invention, Comprising: The perspective view of the fixed pin in 8th Embodiment of this invention.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is an explanatory view schematically showing a valve mechanism 10 for an engine according to the present invention.

  The valve operating mechanism 10 of the first embodiment includes two valves (for example, intake valves) (not shown) per cylinder, and can change the valve lift amount of the valves according to the operating state of the engine. . More specifically, in the valve operating mechanism 10 of the first embodiment, the valve lift amount becomes smaller in the low speed and low load range than in the high speed and high load range, and the valve lift operating angle, that is, the valve opening of the valve operation. The period can be changed so that the valve lift amount becomes larger and the valve lift operating angle, that is, the valve opening period becomes larger in the high speed and high load range than in the low speed and low load range. It can be changed. That is, in the valve mechanism 10, the valve lift operation angle increases as the valve lift amount of the valve operation increases, and the valve lift operation angle decreases as the valve lift amount of the valve operation decreases.

  The valve mechanism 10 includes a drive shaft 11 rotatably supported on the cylinder head along the longitudinal direction of the engine (cylinder row direction), a drive cam 112 provided on the drive shaft 11, and an outer peripheral surface of the drive cam 112. A link arm 12 fitted in a relatively rotatable manner, and a control shaft 13 provided in parallel to the drive shaft 11 and having a main shaft portion 131, an eccentric cam portion 132, and a web plate 133 and capable of rotating in at least a predetermined angle range. The swinging arm 14 is rotatably mounted on the eccentric cam portion 132 of the control shaft 13 and is swung by the link arm 12, and is rotatably supported by the drive shaft 11. An oscillating cam 16 that is connected via a rod 15 and that oscillates along with the oscillating arm 14 and presses a valve (not shown), Oscillating cam 16 in response to a drive shaft 11 which rotates in synchronization with rotation is to open or close the valve operating swings. The drive shaft 11 and the control shaft 13 are rotatably supported by a bearing (not shown).

  The drive shaft 11 is rotated by torque transmitted from an engine crankshaft (not shown), and is composed of a cylindrical drive shaft main body 111 and a drive cam 112. A main oil passage 31 is formed in the drive shaft main body 111. The drive cam 112 is connected and fixed to the drive shaft main body 111 by a cylindrical fixing pin 18 (see FIGS. 3 to 6 described later), and rotates integrally with the drive shaft main body 111. The drive cam 112 is an eccentric rotation cam deviated from the axis of the drive shaft main body 111. The drive cam 112 has a cam body 112a and a boss portion 112b, and the cam body 112a and the boss portion 112b are integrally formed. The axis of the cam body 112a is set to be offset from the axis of the drive shaft main body 111 by a predetermined amount in the radial direction. A connection structure between the drive cam 112 and the drive shaft main body 111 by the fixing pin 18 will be described later.

  The control shaft 13 has a crank shape in which the shaft center of the eccentric cam portion 132 is offset with respect to the shaft center of the main shaft portion 131, and the main shaft portion 131 and the eccentric cam portion 132 are connected via a thin plate-like web plate 133. Yes. The control shaft 13 is controlled to rotate within a predetermined rotation angle range by an actuator (not shown). The actuator controls the rotation of the control shaft 13 based on the current operating state of the engine detected from detection signals from various sensors such as a crank angle sensor, an air flow meter, and a water temperature sensor. When the control shaft 13 is rotationally controlled, the eccentric position of the eccentric cam portion 132 is adjusted, and the swing center of the swing arm 14 is changed. And according to the rotation angle position of the control shaft 13, the lift and the operating angle of the valve are continuously expanded and reduced simultaneously.

  As shown in FIGS. 1 and 2, the link arm 12 includes a large end portion 12 a that is fitted to the outer peripheral surface of the drive cam 112 so as to be relatively rotatable, and a pin portion 21 of the swing arm 14 as a first rotation fulcrum. And a small end portion 12b fitted to the outer periphery thereof so as to be relatively rotatable, and is disposed adjacent to the swing arm 14.

  The swing arm 14 is generally composed of a cap 141 and an arm body 142 having a columnar pin portion 21 linked to the link arm 12, and is an arm positioned closer to the drive shaft 11 than the cap 141 and the cap 141. The eccentric cam portion 132 is sandwiched between the body 142 and is rotatably supported. In other words, the swing arm 14 includes the control shaft support portion 143 that rotatably supports the eccentric cam portion 132 of the control shaft 13, and the columnar pin portion 21 that is linked to the link arm 12. The control shaft support portion 143 includes a cap side control shaft support portion 36 formed on the cap 141 and an arm body side control shaft support portion 37 formed on the arm body 142. More specifically, the swing arm 14 has a control shaft support portion 143 formed on one end side and a pin portion 21 formed on the other end side. The cap 141 and the arm body 142 are coupled by a bolt 38.

  The link rod 15 is rotatably connected to the arm body 142 of the swing arm 14 via a pin 22 whose one end is a second rotation fulcrum, and the swing cam 16 is connected via a pin 23 whose other end is a rotation fulcrum. It is connected to be rotatable. In other words, one end of the link rod 15 is connected to the other end side of the swing arm 14 via the pin 22. That is, the link rod 15 is linked to the swing arm 14 via the pin 22 located on the same side as the pin portion 21 of the swing arm 14 with respect to the control shaft 13. Here, the pin 22 is further away from the shaft center of the eccentric cam portion 132 than the pin portion 21.

  The swing cam 16 is a pair of members fixed to the pipe 17, and the pipe 17 is inserted through the drive shaft 11 and swingable about the drive shaft 11. The valve is opened and closed by the rotation of the swing cam 16.

  3 and 4 show the drive cam 112 in the first embodiment of the present invention. The drive cam 112 is formed with a drive shaft through hole 24 through which the drive shaft main body 111 passes and a linear first through hole 25 orthogonal to the drive shaft through hole 24. The axis of the drive shaft through hole 24 is offset with respect to the axis of the drive cam 112.

  The first through hole 25 has one end opened to the outer peripheral surface of the drive cam 112, the other end opened to the inner peripheral surface of the drive shaft through hole 24, and the first hole portion 26 into which the fixing pin 18 is press-fitted. One end is opened on the outer peripheral surface of the drive cam 112, the other end is opened on the inner peripheral surface of the drive shaft through hole 24 so as to face the other end of the first hole portion 26, and the hole diameter is larger than the hole diameter of the first hole portion 26. The second hole portion 27 having a small hole diameter is roughly configured. The axial center of the first hole portion 26 and the axial center of the second hole portion 27 are formed so as to coincide with each other. Although not shown, a hole continuous with the first hole 26 is formed in the drive shaft main body 111, and the fixing pin 18 press-fitted into the first hole 26 is press-fitted, so that the drive cam 112 is connected and fixed to the drive body 111.

  The first hole portion 26 is formed such that one end thereof opens on the side of the outer peripheral surface of the drive cam 112 where the contact load increases when the valve lift decreases (downward positive acceleration side), and the second hole portion 27. Is formed so that one end is opened on the side of the outer peripheral surface of the drive cam 112 where the contact load increases when the valve lift increases (upward positive acceleration side). In other words, as shown in FIG. 4, among the outer peripheral surfaces of the drive cam 112 divided into two on the left and right in FIG. 4 by a straight line L passing through the center of the drive cam 112 and the center of the drive shaft main body 111, FIG. The first hole 26 is formed on the outer peripheral surface of the drive cam 112 on the left side (downward positive acceleration side) in FIG. 4, and the second hole portion 27 is formed on the outer peripheral surface of the drive cam 112 on the right side (upward positive acceleration side) in FIG. Has been.

  As shown in FIG. 5, the fixed pin 18 includes an oil hole 28 that supplies lubricating oil in the main oil passage 31 of the drive shaft 11 to a sliding portion between the drive cam 11 and the link arm 12.

  The oil hole 28 includes a first oil hole portion 29 provided in the center of the fixing pin 18 along the longitudinal direction of the fixing pin, one end opened to the outer peripheral surface of the fixing pin 18, and the other end of the first oil hole portion 29. The second oil hole portion 30 is provided on the inner peripheral surface and provided so as to be orthogonal to the first oil hole portion 29. The two second oil holes 30 are formed in the fixing pin 18 so as to be orthogonal to each other.

  As shown in FIG. 6, the first oil hole portion 29 is formed so that its hole diameter is smaller than the hole diameter of the second hole portion 27.

  Here, the valve mechanism 10 of the first embodiment includes a pin portion 21 that serves as a rotation fulcrum of the swing arm 14 relative to the link arm 14 and a pin 22 that serves as a rotation fulcrum of the link rod 15 relative to the swing arm 14. Since it is set to be located on the same side of the swing arm 14 with respect to the control shaft 13, that is, on the other end side of the swing arm 14, the swing arm 14 is pulled down by the drive cam 112 to operate the valve. The link arm 12 is lifted, and a load in the pulling direction acts on the link arm 12.

  This will be described in detail with reference to FIG. FIG. 7 (A-1) shows a link of the variable valve mechanism of the type (normal link) in which the pin portion 21 and the pin 22 are located on the opposite side across the control shaft 13 when the valve is opened. It is a side view which shows a state, and FIG. 7 (A-2) is a front view of the variable valve mechanism of a normal link. FIG. 7B-1 shows a variable motion of a type (down link) in which the pin portion 21 and the pin 22 are located on the same side with respect to the control shaft 13 as in the variable valve mechanism of the first embodiment described above. FIG. 7B is a side view showing a link state when the valve is opened in the valve mechanism, and FIG. 7B-2 is a front view of the variable valve mechanism of the pull-down link. In FIG. 7A-1, FIG. 7A-2, FIG. 7B-1, and FIG. 7B-2, for convenience of explanation, the same components as those in the first embodiment are described. Are denoted by the same reference numerals, and redundant description will be omitted.

  In the variable valve mechanism of the type in which the pin portion 21 and the pin 22 are located on the opposite sides across the control shaft 13 as shown in FIG. 7A-1 and FIG. When the valve opens, the load acts as follows. That is, when the drive shaft 11 rotates and the cam body 112 a rises, the position of the pin portion 21 also rises via the link arm 12. Then, the position of the pin 22 is lowered via the swing arm 14. Then, the swing cam 16 is pushed down via the link rod 15 and the valve is opened. When the valve is thus opened, as shown in FIG. 7A-1, a load acts on the link arm 12 in the compression direction, and an upward load acts on both ends of the swing arm 14. . Since a load in the same direction acts on both ends of the swing arm 14, the moment Mx1 generated in the swing arm 14 is a moment that tilts the swing arm 14, as shown in FIG. 7A-2. As does not work.

  On the other hand, a variable valve mechanism of a type in which the pin portion 21 and the pin 22 are located on the same side with respect to the control shaft 13 as shown in FIGS. 7B-1 and 7B-2. In, the load acts as follows when the valve is opened. That is, when the drive shaft 11 rotates and the cam body 112a is lowered, the position of the pin portion 21 is also lowered via the link arm 12. Then, the position of the pin 22 is also lowered via the swing arm 14. Then, the swing cam 16 is pushed down via the link rod 15 and the valve is opened. When the valve is opened as described above, a load acts on the link arm 12 in the pulling direction as shown in FIG. 7 (B-1), and the swing arm as shown in FIG. 7 (B-2). A downward load acts on one end portion along the control axis direction of the control shaft 14, but an upward load acts on the other end portion along the control axis direction of the swing arm 14. Since loads in opposite directions act on both ends of the swing arm 14 along the control axis direction, a large tilt moment Mx2 that tilts the swing arm 14 is generated as shown in FIG. Will occur.

  Here, as shown in FIG. 2 described above, the link arm 12 has a high rigidity in the compression direction and a low rigidity in the tensile direction due to its shape. That is, in the “valve link” variable valve mechanism such as the valve mechanism 10 in the first embodiment described above, when a large load is applied to the link arm 12, the variable valve mechanism of the “normal link” is compared with that. The link arm 12 is greatly deformed.

  FIG. 8 is an explanatory view schematically showing a contact load acting on the outer peripheral surface (sliding surface) of the drive cam 112. FIG. 8 (a) is a diagram when the engine speed is low, and FIG. Indicates when the engine speed is high. 8A and 8B, the upper part is a schematic diagram showing the drive cam 112 in FIG. 4 with the outer peripheral surface (sliding surface) being expanded, and the middle part is the first described above. The explanatory view schematically showing the contact load between the link arm 12 of the valve mechanism 10 (down link) and the drive cam 112 in the embodiment, and the lower part shows that the valve mechanism 10 in the first embodiment described above is “ It is explanatory drawing which showed typically the contact load of the link arm 12 and the drive cam 112 in the case of "normal link". 8A and 8B, the vertical axis indicates the contact load between the link arm 12 and the drive cam 112, and the horizontal axis indicates the drive cam 112 shown in FIG. Shows the position on the outer peripheral surface when the outer peripheral surface (sliding surface) is flattened (as shown in FIG. 4, 0 °, 90 °, 180 °, 270 ° counterclockwise) Yes.

  Two shaded portions (shaded portions) in FIG. 8 indicate positions of openings (holes) of the first hole portion 26 and the second hole portion 27 provided on the outer peripheral surface of the drive cam 112. Since the sliding width is reduced in the shaded portion, it is desirable that a large contact load is not generated.

  The following is a list of what can be seen from FIG.

1) When the engine speed is low (Fig. 8a)
In both the variable valve mechanism of the “down link” and the variable valve mechanism of the “normal link”, there is almost no contact load generated in the vicinity of the openings of the first hole portion 26 and the second hole portion 27. This is because the main factor of the force generated in the link mechanism at low speed is the valve spring load. For this reason, the waveform of the contact load is very similar to the valve lift waveform. In this case, since the opening of the 1st hole part 26 and the 2nd hole part 27 should just not overlap in the range of about 90-270 degrees, the magnitude | size of the opening of the 1st hole part 26 and the 2nd hole part 27 is set. There is not much need to devise.

2) When the engine speed is high (Fig. 8b)
A contact load is generated near the opening of the first hole 26 and the second hole 27 in both the variable valve mechanism of the “down link” and the variable valve mechanism of the “normal link”. This is because the main factor of the force generated in the link mechanism shifts to valve acceleration at high speed. Actually, the contact load in the vicinity of 180 ° at which the lift is maximum is almost zero, and a load peak appears on both sides, that is, in the vicinity where the valve acceleration is maximum (first peak). In addition, since the behavior of the components within the clearance becomes intense at high speed, a contact load is also generated during a period during which the valve is lifted (second and third peaks).
Comparing the magnitude of contact load between the second peak generated on the positive positive acceleration side and the third peak generated on the positive positive acceleration side, the variable valve mechanism of the “down link” and the variable movement of the “normal link” Both valve mechanisms are larger on the former side. Therefore, it can be said that it is desirable to reduce the oil hole on the upstream positive acceleration side and increase the oil hole on the downstream positive acceleration side regardless of the type of link. That is, both the variable valve mechanism of the “down link” and the variable valve mechanism of the “normal link” reduce the oil hole on the positive positive acceleration side and increase the oil hole on the positive positive acceleration side, thereby increasing the drive cam 112. It is possible to achieve both the supply of the lubricating oil to the sliding portion between the link arm 12 and the securing of the contact area of the sliding portion.
Further, the contact load on the side of the outer peripheral surface of the drive cam 112 where the contact load increases when the valve lift decreases is the side of the outer surface of the drive cam 112 where the contact load increases when the valve lift increases. Since it is relatively smaller than the contact load, in the variable valve mechanism of the “down link” like the valve mechanism 10 of the first embodiment described above, the oil hole on the up positive acceleration side is made small, and the down positive acceleration side If the oil hole is made larger, it becomes more advantageous to achieve both the supply of the lubricating oil to the sliding portion between the drive cam 112 and the link arm 12 and the securing of the contact area of the sliding portion.

  In short, the first rotation fulcrum that links the link arm 12 and the swing arm 14 and the second rotation fulcrum that links the swing arm 14 and the link rod 15 are on the same side with respect to the control shaft 13. If it is located, as shown in FIG. 8, the contact load (third peak) on the side of the outer peripheral surface of the drive cam 112 where the contact load increases when the valve lift decreases is the drive cam 112. Of the outer circumferential surface of the driving cam 112 becomes smaller than the contact load (second peak) on the side where the contact load increases when the valve lift increases. Among them, the second hole portion 27 having a small hole diameter is provided on the side where the contact load increases when the valve lift increases on the outer peripheral surface of the drive cam 112. Drive cam 112 and link arm The supply of lubricating oil to the sliding portion between the 2, is further advantageous in achieve both securing a contact area of the sliding portion.

  Moreover, in this 1st Embodiment, since the hole diameter of the 1st oil hole part 29 is formed so that it may become smaller than the hole diameter of the 2nd hole part 27, if a jig | tool is inserted from the 2nd hole part side. Thus, the press-fitted fixing pin 18 can be easily removed, and the maintainability can be improved.

  And since the hole diameter of the 2nd oil hole part 30 is formed smaller than the hole diameter of the 1st oil hole part 29, it is a structure advantageous when increasing the rigidity of the fixing pin 18. FIG.

  Further, since the two second oil holes 30 provided in the fixing pin 18 are formed so as to be orthogonal to each other, one end side of the two second oil holes 30 even if the fixing pins 18 are randomly press-fitted. It is possible to avoid a situation in which both of the openings are not directed in the axial direction of the drive shaft 11, and the lubricating oil is introduced into the fixed pin 18 from the main oil passage 31 of the drive shaft 10 through the second oil hole 30. Can be introduced more smoothly, and the occurrence of sliding troubles such as seizure at the sliding portion between the drive cam 112 and the link arm 12 can be further suppressed.

  Note that the number of the second oil holes 30 provided in the fixing pin 18 is not limited to two. If at least two or more second oil holes 30 are provided, the second oil holes 30 are provided. Since it becomes easy to avoid the situation that all of the openings on one end side of the portion 30 do not face the axial direction of the drive shaft 11, even if the fixing pins are randomly press-fitted, the oil supply performance is prevented from being impaired. Can do. That is, if at least two or more second oil holes 30 are provided in the fixing pin 18, the press-fit workability of the fix pin 18 can be improved, and the work time during the press-fit work can be shortened. Then, since the lubricating oil is introduced into the fixed pin 18 from the main oil passage 31 of the drive shaft 11 via the plurality of second oil hole portions 30, the sliding portion between the drive cam 112 and the link arm 12 is introduced. Sufficient lubricating oil to be supplied can be secured, and occurrence of sliding trouble such as seizure at the sliding portion can be suppressed.

  In addition, the control shaft 13 in the first embodiment described above has a crank shape in which the shaft center of the eccentric cam portion 132 is offset with respect to the shaft center of the main shaft portion 131. The present invention is also applicable to a valve mechanism that does not have a crank shape.

  Hereinafter, other embodiments of the present invention will be described. In addition, about the component same as 1st Embodiment mentioned above, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  A second embodiment of the present invention will be described with reference to FIGS. The second embodiment has substantially the same configuration as the first embodiment described above, but the outer circumferential surface of the drive cam 112 has a width smaller than the hole diameter of the second hole portion 27 and the circumferential direction of the drive cam 112. Is formed so as to be continuous with the opening on the one end side of the second hole portion 27. Specifically, the oil groove 41 is formed on the outer peripheral surface of the drive cam 112 so as to straddle the opening on the one end side of the second hole portion 27 along the circumferential direction of the drive cam 112.

  If the diameter of the second hole 27 is smaller than the diameter of the first hole 26 provided in the drive cam 112, there is a problem that the oil supply period on the second hole 27 side is shortened. Therefore, by forming an oil groove 41 along the circumferential direction of the drive cam 112 on the second hole 27 side, the oil supply period for the sliding portion between the drive cam 112 on the second hole 27 side and the link arm 12 is increased. It can be relatively long.

  In addition, by making the width of the oil groove 41 smaller than the hole diameter of the second hole portion 27, the sliding width of the sliding portion between the drive cam 112 and the link arm 12 on the second hole portion 27 side is reduced. The oil supply period can be made relatively long while suppressing the above.

  A third embodiment of the present invention will be described with reference to FIGS. 11 and 12. The third embodiment has substantially the same configuration as the first embodiment described above, but the drive cam 112 is formed with a second through hole 45 communicating with the main oil passage 31 of the drive shaft 11.

  One end of the second through hole 45 opens in the outer peripheral surface of the drive cam 112 farthest from the center of the drive shaft through hole 24 and the other end of the second through hole 45 opens in the inner periphery of the drive shaft through hole 24. Is formed.

  The first rotation fulcrum that links the link arm 12 and the swing arm 14 and the second rotation fulcrum that links the swing arm 14 and the link rod 15 are located on the same side with respect to the control shaft 13. In this case, as described above, the swing cam 14 is pulled down by the drive cam 112 to lift the valve, and a load in the pulling direction acts on the link arm 12.

  When the deformation of the link arm 12 is not taken into consideration, the contact load between the link arm 12 and the drive cam 112 is strongly generated at a position indicated by hatching in FIG. However, actually, as shown in FIG. 14, the link arm 12 is elastically deformed, and so-called close-in (a phenomenon in which the diameter is reduced and the wire is wound around the shaft) occurs. As a result, the portion with the highest contact load passes through the center of the drive shaft 11 and the center of the drive cam 112, and slightly deviates left and right (side) from the straight line passing through the center of the link link arm 12.

  Therefore, by providing the second through-hole 45 so that one end is opened to the outer peripheral surface of the drive cam 112 farthest from the center of the drive shaft 11, the amount of oil supplied to the sliding portion between the drive cam 112 and the link arm 12 By increasing, the cooling performance and lubrication performance of the sliding portion can be improved.

  However, the second through hole 45 should be regarded as an auxiliary one, and it is still preferable to ensure a sufficient sliding width. Therefore, the diameter of the second through hole 45, that is, the outer peripheral surface of the drive cam 112. It is better not to make the diameter of the opening on the one end side opened to be too large.

  In the variable valve mechanism of the type (normal link) in which the pin portion 21 and the pin 22 are located on opposite sides of the control shaft 13, as described above, the swing cam 14 is pushed up by the drive cam 112. The valve is lifted, and a load in the compression direction acts on the link arm 12. Therefore, in such a “normal link” variable valve mechanism, when the deformation of the link arm 12 is not taken into consideration, the contact load between the link arm 12 and the drive cam 112 is strongly generated at the position indicated by the oblique lines in FIG. However, since the rigidity of the link arm 12 in the compression direction is high, the above-described close-in does not occur at all. Therefore, it is not preferable to combine the second through-hole 45 in the third embodiment described above in the “normal link” variable valve mechanism. This is because the contact portion has almost no clearance, and the effect of refueling from the second through hole 45 cannot be expected.

  A fourth embodiment of the present invention will be described with reference to FIG. The fourth embodiment has substantially the same configuration as the first embodiment described above, but the axis of the first through hole 25 penetratingly formed in the drive cam 112 is offset with respect to the center of the drive shaft 11. Is formed. Specifically, the axial centers of both the first hole portion 26 and the second hole portion 27 of the first through hole 25 are on the upper side in FIG. 16 with respect to the center of the drive shaft 11, in other words, the center of the drive cam 112. It is formed to be offset to the side. Note that the axis of the first hole 26 and the axis of the second hole 27 coincide with each other.

  In such 4th Embodiment, the length of the fixing pin 18 press-fit in the 1st hole part 26 can be shortened relatively, and the rigidity of the fixing pin 18 can be improved. Since the axis of the first through hole 25 is offset toward the center of the drive cam 112 with respect to the center of the drive shaft 11, the thickness of the drive cam 112 around the drive shaft through hole 24 is relatively As a result, the stress in the vicinity of the drive shaft through hole 24 of the drive cam 112 can be relaxed. In addition, what is necessary is just to determine the offset amount of the axis line of the 1st through-hole 25, and the center of the drive shaft 11 from the generation | occurrence | production state of the contact load shown, for example in FIG.

  Further, in the fourth embodiment, the shaft centers of both the first hole portion 26 and the second hole portion 27 of the first through hole 25 are formed to be offset with respect to the center of the drive shaft 11, Even if only the first hole 26 is formed to be offset with respect to the center of the drive shaft 11, the length of the fixing pin 18 can be relatively shortened.

  A fifth embodiment of the present invention will be described with reference to FIGS. The fifth embodiment has substantially the same configuration as the first embodiment described above, but the second hole portion 27 formed in the drive cam 112 is stepped so that the drive shaft through hole side has a relatively large diameter. It is formed in a hole shape. The end surface of the fixing pin 18 can be brought into contact with the stepped portion 51 of the second hole portion 27.

  Accordingly, if the stepped portion 51 of the second hole portion 27 is used as a seating surface of the fixing pin 18, management of the press-fitting allowance of the fixing pin 18 is facilitated, and the press-fitting workability of the fixing pin 18 can be improved. .

  A sixth embodiment of the present invention will be described with reference to FIG. The sixth embodiment has substantially the same configuration as the first embodiment described above, but the two second oil holes 30 provided in the fixing pin 18 are offset from each other in the longitudinal direction of the fixing pin 18. Is formed.

  Accordingly, the rigidity of the fixing pin 18 can be increased as compared with the case where the two second oil hole portions 30 are not offset from each other in the longitudinal direction of the fixing pin 18.

  A seventh embodiment of the present invention will be described with reference to FIG. The seventh embodiment has substantially the same configuration as that of the first embodiment described above, but only one second oil hole 30 is formed in the fixing pin 18. The fixing pin 18 is provided with a key 55 that defines the direction when the fixing pin 18 is press-fitted into the first hole portion 26. The key 55 is fitted in a key groove (not shown) formed in the fixing pin 18 and is separate from the fixing pin 18. In addition, a key groove (not shown) that fits with the key 55 is formed in the first hole portion 26 of the drive cam 112.

  The key groove formed in the key 55 and the fixing pin 18 and the key groove formed in the first hole portion 26 are formed in the second oil hole portion 30 when the fixing pin 18 is press-fitted into the first hole portion 26. Each opening is set so that the opening on one end side faces the axial direction of the drive shaft 11.

  Accordingly, the lubricating oil can be smoothly introduced from the main oil passage 31 of the drive shaft 11 into the first oil hole portion 29 of the fixing pin 18 without providing the plurality of second oil hole portions 30 in the fixing pin 18. It becomes possible. That is, by providing the plurality of second oil hole portions 30, it is possible to suppress the occurrence of sliding trouble such as seizure in the sliding portion between the drive cam 112 and the link arm 12 without impairing the rigidity of the fixing pin 18. .

  In addition, in this 7th Embodiment, although the fixing pin 18 and the key 55 are separate bodies, you may form so that the fixing pin 18 and the key 55 may be united.

  The eighth embodiment of the present invention will be described with reference to FIG. The eighth embodiment has substantially the same configuration as the first embodiment described above, but only one second oil hole 30 is formed in the fixing pin 18. Of the end surfaces of the fixing pin 18, when the fixing pin 18 is press-fitted into the first hole 26 when the fixing pin 18 is press-fitted into the first hole 26, A recess 61 is provided to define the orientation of the.

  The concave portion 61 is fitted with a convex portion (not shown) provided on the press-fitting jig side, and by combining the concave portion 61 of the fixing pin 18 and the convex portion of the press-fitting jig, When the fixing pin 18 is press-fitted into the first hole portion 26, the opening on one end side of the second oil hole portion 30 is set to face the axial direction of the drive shaft 11.

  Accordingly, the lubricating oil can be smoothly introduced from the main oil passage 31 of the drive shaft 11 into the first oil hole portion 29 of the fixing pin 18 without providing the plurality of second oil hole portions 30 in the fixing pin 18. It becomes possible. That is, by providing the plurality of second oil hole portions 30, it is possible to suppress the occurrence of sliding trouble such as seizure in the sliding portion between the drive cam 112 and the link arm 12 without impairing the rigidity of the fixing pin 18. .

  In the eighth embodiment, the concave portion 61 is formed on the fixing pin 18 and the convex portion is formed on the press-fitting jig side. However, the convex portion is formed on the fixing pin 18 and the fixing pin is provided on the press-fitting jig side. It is also possible to form a recess that fits into the 18 protrusions. However, since the number of fixed pins manufactured is generally larger than that of a press-fitting jig, the concave portion 61 is provided in the fixed pin 18 and the concave portion of the fixed pin 18 is provided on the press-fitting jig side as in the eighth embodiment. It is more reasonable to provide a convex part that fits into 61.

  In addition, although each embodiment mentioned above presupposes the valve mechanism (variable valve mechanism of a pulling-down link) in which the pin part 21 and the pin 22 are located in the same side with respect to the control shaft 13, this invention, The present invention can also be applied to a valve mechanism (ordinary link variable valve mechanism) in which the pin portion 21 and the pin 22 are located on opposite sides of the control shaft 13.

  The technical ideas of the present invention that can be grasped from the above-described embodiments will be listed together with their effects.

  (1) A main oil passage is formed inside, a drive shaft that rotates in synchronization with engine rotation, a drive cam that is fixed to the drive shaft by a fixing pin, and an outer peripheral surface of the drive cam that is relatively rotatable. A combined link arm, a rotatable control shaft provided in parallel with the drive shaft and having a main shaft portion and an eccentric cam portion, and rotatably mounted on the eccentric cam portion of the control shaft; and A swing arm swung by the link arm via a rotation fulcrum, a link rod linked to the swing arm via a second rotation fulcrum, and rotatably supported by the drive shaft; An engine that is connected to the swing arm via a link rod and swings along with the swing arm to press the valve, thereby making the valve lift amount of the valve variable. The valve operating mechanism The lubricating oil in the main oil passage of the dynamic shaft is supplied to the sliding portion between the drive cam and the link arm through an oil hole provided in the fixed pin, and the engine is operated to lubricate the sliding portion. In the valve mechanism, the drive cam is formed with a drive shaft through hole through which the drive shaft passes, and a linear first through hole orthogonal to the drive shaft through hole, and the first through hole has one end Is opened to the outer peripheral surface of the drive cam, the other end is opened to the inner peripheral surface of the drive shaft through-hole, and the one end is the outer peripheral surface of the drive cam. A second hole portion having an opening on the inner peripheral surface of the drive shaft through-hole so that the other end faces the other end of the first hole portion, and having a hole diameter smaller than the hole diameter of the first hole portion, Have Thereby, it is possible to achieve both the supply of lubricating oil to the sliding portion between the drive cam and the link arm and the securing of the contact area of the sliding portion.

  (2) In the valve mechanism of the engine according to (1), the first hole portion of the first through hole has a contact load that increases when a valve lift of the outer peripheral surface of the drive cam decreases. One end is formed on the side. As shown in FIG. 8, the contact load on the side where the contact load increases when the valve lift decreases on the outer peripheral surface of the drive cam is the contact load when the valve lift increases on the outer peripheral surface of the drive cam. Is relatively smaller than the contact load on the increase side, so that it is further necessary to achieve both the supply of lubricating oil to the sliding portion of the drive cam and the link arm and the securing of the contact area of the sliding portion. Will be advantageous.

  (3) In the valve operating mechanism of the engine according to (1) or (2), the first rotation fulcrum and the second rotation fulcrum are located on the same side with respect to the control shaft. The first rotation fulcrum that links the link arm and the swing arm and the second rotation fulcrum that links the swing arm and the link rod are on the same side with respect to the control shaft. 8, the contact load on the side where the contact load increases when the valve lift decreases in the outer peripheral surface of the drive cam, as shown in FIG. As the contact load increases, the contact load becomes smaller compared to the contact load on the side, so that the supply of lubricating oil to the sliding portion between the drive cam and the link arm, and the securing of the contact area of the sliding portion, It is even more advantageous in achieving both.

  (4) In the engine valve operating mechanism according to (3), a second through hole communicating with the main oil passage of the drive shaft is formed in the drive cam, and the second through hole has one end. An opening is formed on the outer peripheral surface of the drive cam farthest from the center of the drive shaft through hole, and the other end is opened on the inner periphery of the drive shaft through hole. When the first rotation fulcrum and the second rotation fulcrum are located on the same side with respect to the control shaft, the drive cam pulls down the swing arm to lift the valve. Thus, a load in the pulling direction acts on the link arm. When the deformation of the link arm is not taken into consideration, the contact load between the link arm and the drive cam is strongly generated at a position indicated by hatching in FIG. However, actually, as shown in FIG. 14, the link arm is elastically deformed, and so-called close-in (a phenomenon in which the diameter is reduced and the shaft is wound around the shaft) occurs. As a result, the portion with the highest contact load passes through the center of the drive shaft and the center of the drive cam and slightly deviates left and right (side) from the straight line passing through the center of the link link arm. Therefore, by providing a second through hole so that one end opens on the outer peripheral surface of the drive cam farthest from the center of the drive shaft, the amount of oil supplied to the sliding portion between the drive cam and the link arm can be reduced. By increasing the cooling performance, the cooling performance and lubrication performance of the sliding portion can be improved.

  (5) In the engine valve operating mechanism according to any one of (1) to (4), an outer peripheral surface of the drive cam has a width smaller than a hole diameter of the second hole portion, An oil groove extending in the circumferential direction is formed to be continuous with the opening on one end side of the second hole portion. Accordingly, the oil supply period for the sliding portion between the drive cam and the link arm can be relatively increased on the second hole side having a smaller diameter than the first hole. Further, by reducing the width of the oil groove to be smaller than the diameter of the second hole, the sliding width of the sliding portion between the drive cam and the link arm on the second hole side is reduced. The oil supply period can be made relatively long while suppressing the above.

In a valve operating mechanism for an engine according to any one of (6) above (1) to (5), the first through-hole is less with the axis of the first hole also has, with respect to the center of the drive shaft It is formed to be offset. Thereby, the length of the fixing pin can be relatively shortened, and the rigidity of the fixing pin can be improved. Further, since the thickness around the drive shaft through hole of the drive cam relatively increases, the stress in the vicinity of the drive shaft through hole of the drive cam can be relaxed.

  (7) In the valve operating mechanism for an engine according to any one of (1) to (6), the second hole portion is formed in a stepped hole shape in which the drive shaft through hole side has a relatively large diameter. The end face of the fixing pin can be brought into contact with the stepped portion of the second hole. Accordingly, if the stepped portion of the second hole portion is used as the seating surface of the fixing pin, it is easy to manage the press-fitting allowance of the fixing pin, and the press-in workability of the fixing pin can be improved.

  (8) In the valve operating mechanism of the engine according to any one of (1) to (7), the oil hole provided in the fixing pin includes a first oil hole portion along a longitudinal direction of the fixing pin. A second oil hole portion having one end opened on the outer peripheral surface of the fixing pin and the other end opened on the inner peripheral surface of the first oil hole portion, and the hole diameter of the first oil hole portion is It is formed to be smaller than the hole diameter of the second hole portion. Thereby, if the jig is inserted from the second hole side, the press-fitted fixing pin can be easily removed, and the maintainability can be improved.

  (9) In the valve mechanism of the engine according to (8), at least two or more of the second oil hole portions are formed in the fixing pin, and each of the second oil hole portions is the first oil. It is formed so as to be orthogonal to the hole. If the direction of the fixing pin is poor when the fixing pin is press-fitted, the opening on the one end side of the second oil hole portion that opens to the outer peripheral surface of the fixing pin does not face the axial direction of the drive shaft, and the oil supply performance is impaired. Although there is a possibility, even if it press-fits the said fixing pin at random by forming at least 2 or more of the said 2nd oil hole part, it can suppress that oil supply performance is impaired. That is, by forming at least two or more second oil holes in the fixed pin, the press-fit workability of the fixed pin is improved, and the work time during the press-fit work can be shortened. Further, since the lubricating oil is introduced into the fixed pin from the main oil passage of the drive shaft through a plurality of second oil holes, the lubricating oil is supplied to the sliding portion between the drive cam and the link arm. Therefore, it is possible to secure sufficient lubricating oil, and to prevent the occurrence of sliding trouble such as seizure in the sliding portion.

  (10) In the valve operating mechanism for an engine according to (9), the hole diameter of the second oil hole is smaller than the hole diameter of the first oil hole. As a result, the rigidity of the fixing pin can be increased.

  (11) In the valve operating mechanism of the engine according to (9) or (10), two second oil holes provided in the fixing pin are formed to be orthogonal to each other. As a result, even if the fixing pins are randomly press-fitted, it is possible to avoid that both the openings on one end side of the two second oil hole portions do not face the axial direction of the drive shaft. The lubricating oil can be introduced more smoothly from the main oil passage of the drive shaft through the second oil hole, and sliding such as seizure at the sliding portion between the drive cam and the link arm can be achieved. Trouble occurrence can be further suppressed.

  (12) In the valve operating mechanism for an engine according to any one of (9) to (11), the second oil holes of the fixed pin are formed to be offset from each other in the longitudinal direction of the fixed pin. . Thereby, the rigidity of the fixing pin can be further increased.

  (13) In the valve operating mechanism of the engine according to any one of (1) to (8), the fixing pin is formed with one second oil hole, and the second oil hole is An opening on one end side of the second oil hole is driven when the fixing pin is press-fitted into the first hole. A key that defines the direction when press-fitting into the first hole or a key groove that fits into the key is formed so as to face the axial direction of the shaft. Accordingly, it is possible to smoothly introduce the lubricating oil from the main oil passage of the drive shaft into the first oil hole portion of the fixed pin without providing a plurality of second oil hole portions in the fixed pin. That is, it is possible to suppress the occurrence of sliding trouble such as seizure at the sliding portion between the drive cam and the link arm without impairing the rigidity of the fixing pin.

  (14) In the valve operating mechanism of the engine according to any one of (1) to (8), the fixing pin is formed with one second oil hole, and the second oil hole is The press-fitting treatment is formed on an end surface of the fixing pin that is formed to be orthogonal to the first oil hole portion, and is in contact with the press-fitting jig when the fixing pin is press-fitted into the first hole portion. Concave portions or convex portions that are fitted with convex portions or concave portions provided on the tool side are formed, and these convex portions and concave portions are formed in the second oil hole when the fixing pin is press-fitted into the first hole portion. When the opening on one end side of the part faces the axial direction of the drive shaft, they are set so as to be fitted to each other. Accordingly, it is possible to smoothly introduce the lubricating oil from the main oil passage of the drive shaft into the first oil hole portion of the fixed pin without providing a plurality of second oil hole portions in the fixed pin. That is, it is possible to suppress the occurrence of sliding trouble such as seizure at the sliding portion between the drive cam and the link arm without impairing the rigidity of the fixing pin.

DESCRIPTION OF SYMBOLS 10 ... Valve operating mechanism 11 ... Drive shaft 111 ... Drive shaft main body 112 ... Drive cam 12 ... Link arm 13 ... Control shaft 131 ... Main shaft part 132 ... Eccentric cam part 14 ... Swing arm 141 ... Cap 142 ... Arm body 143 ... Control Shaft support portion 15 ... Link rod 16 ... Oscillating cam 18 ... Fixing pin 21 ... Pin portion 31 ... Main oil passage

Claims (14)

A main oil passage is formed inside, a drive shaft that rotates in synchronization with engine rotation, a drive cam that is fixed to the drive shaft by a fixing pin, and a link that is fitted to the outer peripheral surface of the drive cam so as to be relatively rotatable. An arm, a rotatable control shaft provided in parallel with the drive shaft, and having a main shaft portion and an eccentric cam portion; and rotatably mounted on the eccentric cam portion of the control shaft, and having a first rotation fulcrum A swing arm that is swung by the link arm via the link arm, a link rod that is linked to the swing arm via a second rotation fulcrum, and the drive shaft that is rotatably supported by the swing arm. And an oscillating cam connected to the arm via a link rod and pressing the valve by oscillating along with the oscillating arm, wherein the valve lift amount of the valve is variable. Mechanism,
The engine is configured to supply lubricating oil in the main oil passage of the drive shaft to a sliding portion between the driving cam and the link arm through an oil hole provided in the fixed pin, and lubricate the sliding portion. In the valve mechanism,
The drive cam is formed with a drive shaft through hole through which the drive shaft passes, and a linear first through hole orthogonal to the drive shaft through hole,
The first through hole has one end opened on the outer peripheral surface of the drive cam, the other end opened on the inner peripheral surface of the drive shaft through hole, and the first pin into which the fixing pin is press-fitted. One end opens to the outer peripheral surface of the drive cam, the other end opens to the inner peripheral surface of the drive shaft through hole so as to face the other end of the first hole, and the hole diameter is larger than the hole diameter of the first hole. And a second hole portion having a small diameter.   The first hole portion of the first through hole is formed such that one end thereof is opened on a side where a contact load increases when a valve lift decreases in an outer peripheral surface of the drive cam. Item 4. A valve operating mechanism for an engine according to Item 1.   The valve operating mechanism for an engine according to claim 1 or 2, wherein the first rotation fulcrum and the second rotation fulcrum are located on the same side with respect to the control shaft. The drive cam is formed with a second through hole communicating with the main oil passage of the drive shaft,
The second through hole has one end opened on the outer peripheral surface of the drive cam farthest from the center of the drive shaft through hole, and the other end opened on the inner periphery of the drive shaft through hole. Item 4. A valve mechanism for an engine according to Item 3.   An oil groove having a width smaller than the hole diameter of the second hole portion and extending in the circumferential direction of the drive cam is formed on the outer peripheral surface of the drive cam so as to be continuous with the opening on one end side of the second hole portion. The valve operating mechanism for an engine according to any one of claims 1 to 4, wherein: The first through-hole is less with the axis of the first hole also has an engine according to claim 1, characterized in that it is formed so as to offset the center of the drive shaft Valve mechanism.   The second hole is formed in a stepped hole shape having a relatively large diameter on the drive shaft through hole side so that the end surface of the fixing pin can come into contact with the stepped portion of the second hole. The valve mechanism for an engine according to any one of claims 1 to 6, wherein the valve mechanism is configured.   The oil hole provided in the fixing pin has a first oil hole portion along the longitudinal direction of the fixing pin, one end opened on the outer peripheral surface of the fixing pin, and the other end an inner periphery of the first oil hole portion. And a second oil hole opening in the surface, the hole diameter of the first oil hole being smaller than the hole diameter of the second hole. 8. The valve operating mechanism for an engine according to any one of 7 above. At least two or more of the second oil holes are formed in the fixing pin,
9. The valve operating mechanism for an engine according to claim 8, wherein each of the second oil holes is formed so as to be orthogonal to the first oil hole.   10. The valve operating mechanism for an engine according to claim 9, wherein a hole diameter of the second oil hole portion is smaller than a hole diameter of the first oil hole portion.   11. The valve mechanism for an engine according to claim 9, wherein two second oil holes provided in the fixing pin are formed so as to be orthogonal to each other. The engine valve mechanism according to any one of claims 9 to 11, wherein the second oil hole portions of the fixing pin are formed to be offset from each other in the longitudinal direction of the fixing pin. The fixing pin is formed with one second oil hole,
The second oil hole is formed to be orthogonal to the first oil hole,
Further, the fixing pin is press-fitted into the first hole so that when the fixing pin is press-fitted into the first hole, the opening on the one end side of the second oil hole faces the axial direction of the drive shaft. 9. A valve mechanism for an engine according to any one of claims 1 to 8, wherein a key for defining a direction at the time of operation or a key groove fitted to the key is formed. The fixing pin is formed with one second oil hole,
The second oil hole is formed to be orthogonal to the first oil hole,
Further, of the end face of the fixing pin, the end face that comes into contact with the press-fitting jig when the fixing pin is press-fitted into the first hole is a concave part that fits with a convex part or a concave part provided on the press-fitting jig side. Alternatively, convex portions are formed, and these convex portions and concave portions are formed when the opening on one end side of the second oil hole portion faces the axial direction of the drive shaft when the fixing pin is press-fitted into the first hole portion. The valve operating mechanism for an engine according to any one of claims 1 to 8, wherein the valve operating mechanism is set so as to be fitted to each other.

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