The present invention relates to a valve control apparatus for an internal combustion engine, which is able to vary a lift-amount characteristic, a working angle (valve-open period) or the like of an intake valve or an exhaust valve functioning as an engine valve, in accordance with an operating state of the engine.
In the field of a valve control apparatus functioning to vary a valve lift amount or working angle of the engine valve through a rocker arm by controlling a rotation of control shaft, it is required that an operational control range of the valve lift amount or the like of the engine valve is enlarged by widely varying a swing fulcrum of the rocker arm.
United States Patent Application Publication No. 2009/0050086 (corresponding to Japanese Patent Application Publication No. 2009-47083) discloses a previously-proposed valve control apparatus. In this technique, the control shaft is integrally formed in a crank shape in order to secure a large distance between a rotation center of the control shaft and the swing fulcrum of the rocker arm.
However, in the technique disclosed in the above Application, since the control shaft is formed integrally in the crank shape, the rocker arm cannot be attached to the control shaft from an axial direction of the control shaft. Hence, a base end portion of the rocker arm is formed as pieces divided in a radial direction of the control shaft, and the divided pieces are firmly connected with each other by bolts at the time of assembly. Accordingly, a weight (inertia mass) of whole of the rocker arm is increased, and thereby, there is a risk that an operating performance of the rocker arm is worsened at the time of high-speed operation.
It is therefore an object of the present invention to provide a valve control apparatus devised to solve or ease the above problem.
According to one aspect of the present invention, there is provided a valve control apparatus for an internal combustion engine, comprising: a drive shaft configured to receive a rotational drive force; a control shaft including a control shaft main body configured to be rotationally controlled according to a state of the engine, wherein the control shaft main body is formed with a pair of insertion holes passing through the control shaft main body in a radial direction of the control shaft main body, and a control eccentric shaft located to have an eccentricity relative to a rotation center of the control shaft main body, wherein both ends of the control eccentric shaft are formed with a pair of fixing holes extending in a radial direction of the control eccentric shaft, wherein the pair of insertion holes respectively face the pair of fixing holes; a rocker arm swingably supported by the control eccentric shaft and configured to convert a rotational motion of the drive shaft to a swinging motion; and a swing cam configured to open and close a valve of the engine by swinging according to a swinging force transmitted from the swinging motion of the rocker arm, wherein the control eccentric shaft is fixed to the control shaft main body by bolts, wherein the bolts pass respectively through the pair of insertion holes and are screwed respectively into the pair of fixing holes.
According to another aspect of the present invention, there is provided a valve control apparatus for an internal combustion engine, comprising: a drive shaft configured to receive a rotational drive force; a control shaft including a control shaft main body configured to be rotationally controlled according to a state of the engine, wherein the control shaft main body is formed with a pair of fixing holes extending in a radial direction of the control shaft main body, and a control eccentric shaft located to have an eccentricity relative to a rotation center of the control shaft main body, wherein both ends of the control eccentric shaft are formed with a pair of insertion holes passing through the control eccentric shaft in a radial direction of the control eccentric shaft, wherein the pair of insertion holes respectively face the pair of fixing holes; a rocker arm swingably supported by the control eccentric shaft and configured to convert a rotational motion of the drive shaft to a swinging motion; and a swing cam configured to open and close a valve of the engine by swinging according to a swinging force transmitted from the swinging motion of the rocker arm, wherein the control eccentric shaft is fixed to the control shaft main body by bolts, wherein the bolts pass respectively through the pair of insertion holes and are screwed respectively into the pair of fixing holes.
According to still another aspect of the present invention, there is provided a valve control apparatus for an internal combustion engine, comprising: a drive shaft configured to receive a rotational drive force; a control shaft including a control shaft main body configured to be rotationally controlled according to a state of the engine, wherein the control shaft main body is formed with a pair of insertion holes passing through the control shaft main body in a radial direction of the control shaft main body, and a control eccentric shaft located to have an eccentricity relative to a rotation center of the control shaft main body, wherein both ends of the control eccentric shaft are formed with a pair of fixing holes extending in a radial direction of the control eccentric shaft, wherein the pair of insertion holes respectively face the pair of fixing holes; a rocker arm swingably supported by the control eccentric shaft and configured to convert a rotational motion of the drive shaft to a swinging motion; a swing cam configured to open and close a valve of the engine by swinging according to a swinging force transmitted from the swinging motion of the rocker arm; and a fixing member fixing the control eccentric shaft to the control shaft main body by means of an axial force of the fixing member which is applied through the insertion holes and the fixing holes.
The other objects and features of this invention will become understood from the following description with reference to the accompanying drawings.
Hereinafter, embodiments of valve control apparatus for an internal combustion engine according to the present invention will be described in detail, referring to the drawings. In the respective embodiments, the valve control apparatus is applied to intake sides of three cylinders in one cylinder bank of a V-type six-cylinder internal combustion engine.
[First Embodiment]
As shown in
As shown in
Each of the intake valves 3 and 3 is biased (urged) by a valve spring 10 in a direction that closes (blocks) an open end of the intake port 1. The valve spring 10 is resiliently attached between a bottom portion of an approximately-cylindrically-shaped bore formed in an upper end portion of the cylinder head 05 and a spring retainer 3a provided to an upper end portion of valve stem.
The drive cam 5 is provided on an outer circumference of the drive shaft 4. The drive shaft 4 is rotatably supported by five bearing portions (not shown) provided in an upper portion of the cylinder head 05. Moreover, a timing sprocket (not shown) is provided on one end portion of the drive shaft 4, and thereby, rotational force is transmitted from the crankshaft 02 of engine through the timing sprocket to the drive shaft 4. Thus, the drive shaft 4 is able to rotate in a clockwise direction (arrow direction) of
The drive cam 5 includes a cam main body 5a and a boss portion 5b. The cam main body 5a is formed approximately in a disc shape. The boss portion 5b is formed in a tubular shape, and is provided integrally with an (axially) outside portion of the cam main body 5a. The drive cam 5 is fixed to the drive shaft 4 by a fixing pin 11. The fixing pin 11 passes through a pin hole which was drilled in the boss portion 5b in a radial direction. Moreover, the drive cam 5 is disposed on one end side of the swing cams 7 and 7 relative to an axial direction of drive shaft 4. The boss portion 5b is located on an opposite side of the cam main body 5a from the swing cams 7 and 7. Hence, as shown in
As shown in
As shown in
A swinging direction of each swing cam 7 when opening the intake valve 3 (i.e., when the contact point between the cam surface 7c and the roller 14 moves toward the lift surface) is identical with a rotational direction of the drive shaft 4 (arrow direction in
Moreover, as shown in
Each roller 14 is arranged to protrude from an upper surface of the corresponding swing arm 6. Hence, a space (clearance) between the upper surface of swing arm 6 and the connecting portion 7d of swing cam 7 or between the upper surface of swing arm 6 and the another end portion 17b of link rod 17 is given relatively largely, as shown in
As shown in
As shown in
The tubular base portion 15a is formed with a support hole 15d passing completely through the tubular base portion 15a in the axial direction. The tubular base portion 15a is supported by causing the support hole 15d to be fitted over an after-mentioned outer circumference of the control eccentric shaft 26 through a minute clearance therebetween.
A tip portion of the first arm portion 15b is formed in a bifurcated manner. This bifurcated portion is rotatably connected through a connecting pin 12 with an after-mentioned protruding end 16b of the link arm 16. That is, the protruding end 16b of the link arm 16 is sandwiched between the bifurcated ends of first arm portion 15b, to be linked with the rocker arm 15. The connecting pin 12 is prevented from dropping out of (being detached from) a pin hole of the protruding end 16b, by a snap ring 12a or the like provided at one end portion of the connecting pin 12.
On the other hand, the second arm portion 15c includes a block portion 15f at a tip portion of second arm portion 15c. A lift adjusting mechanism 21 is provided to the block portion 15f. An after-mentioned one end portion 17a of the link rod 17 is linked rotatably with an after-mentioned pivotally-supporting pin 19 of the lift adjusting mechanism 21. Moreover, the block portion 15f is formed with an elongate hole (slot hole, not shown) passing completely through the block portion 15f in a lateral direction of the block portion 15f. That is, the elongate hole 15h is formed to pass from one side of block portion 15f to another side of block portion 15f in the axial direction of drive shaft 4. The pivotally-supporting pin 19 is capable of moving within the elongate hole in an upper-lower direction, i.e., moving along an elongate shape of the elongate hole, for adjustment.
The first arm portion 15b and the second arm portion 15c are provided to have angles different from each other in a swinging direction of the rocker arm 15. That is, there is some angle between an imaginary linkage center line of the first arm portion 15b and an imaginary linkage center line of the second arm portion 15c, in the swinging direction of rocker arm 15 (as viewed in the axial direction of drive shaft 4). Also, the first arm portion 15b and the second arm portion 15c are positioned to deviate from each other in the upper-lower direction. The tip portion of first arm portion 15b is more inclined toward the lower direction by a slight inclination angle than the tip portion of second arm portion 15c.
The link arm 16 includes an annular portion (circular tube portion) and the protruding end 16b. The annular portion has a relatively large diameter. The protruding end 16b is provided to protrude from a predetermined portion of outer circumferential surface of the annular portion. A fitting hole 16a is formed at a center portion of the annular portion. The fitting hole 16a is fitted over an outer circumferential surface of the drive cam 5 so that the drive cam 5 rotatably supports the link arm 16.
As shown in
Moreover, since only one link rod 17 is provided to each cylinder of the engine, a structure of the valve control apparatus can be simplified while lightening a weight of the apparatus.
The swing cam 7 swings to lift the intake valve 3 when the link rod 17 raises (pulls up) the connecting portion 7d. Since the cam nose portion 7b that receives an input from the roller 14 is located on the opposite side of a swinging center of swing cam 7 from the connecting portion 7d, a generation of fall (inclination) of the swing cam 7 can be suppressed.
As shown in
After an assembling of the respective structural elements, a length between the second arm portion 15c of rocker arm 15 and the one end portion 17a of link rod 17 (i.e., a location of connection point between the second arm portion 15c and the one end portion 17a) is adjusted by adjusting an up-down position of the pivotally-supporting pin 19 within the elongate hole (i.e., by adjusting a position of pin 19 set along the elongate shape of elongate hole) by use of the adjusting bolt 21a. Thereby, a fine adjustment for the lift amount of each intake valve 3 is carried out. After this fine adjustment, the position of pivotally-supporting pin 19 is fastened by tightening the lock bolt 22.
As shown in
As shown in
As shown in
Each first protruding portion 28 is formed in a cylindrical tube shape. The first protruding portions 28 and 28 are provided integrally with the control shaft main body 25 to have a predetermined interval (distance) between the both first protruding portions 28 and 28 in the axial direction of control shaft main body 25. A protrusion length L of one of these first protruding portions 28 and 28 is equal to a protrusion length L of another of these first protruding portions 28 and 28. Each of top surfaces (tip surfaces) 28a and 28a of the first protruding portions 28 and 28 is formed to be flat perpendicularly to a protruding direction of first protruding portion 28. The protrusion length L of first protruding portion 28 mainly determines an eccentric amount a between the shaft center P of the control shaft main body 25 and a shaft center P1 of the control eccentric shaft 26, i.e., determines an eccentricity of the control eccentric shaft 26 relative to a rotation center of the control shaft main body 25. This protrusion length L is freely designed according to specifications and size of vehicle and the like.
Moreover, the control shaft main body 25 is formed with a pair of bolt insertion holes 25a and 25a each of which completely passes through the control shaft main body 25 along a diameter of the control shaft main body 25 (in the radial direction of control shaft main body 25). The pair of bolt insertion holes 25a and 25a are provided at locations corresponding to the locations of first protruding portions 28 and 28. Each bolt insertion hole 25a is formed to pass through the control shaft main body 25 in the radial direction and to continuously pass through the first protruding portion 28 along a shaft center of the first protruding portion 28. The shaft portions 29b and 29b of pair of bolts 29 and 29 are respectively inserted into the bolt insertion holes 25a and 25a, and pass through the bolt insertion holes 25a and 25a.
The control shaft main body 25 is formed with a pair of first cutout surfaces 25b and 25b, at hole edges of the bolt insertion holes 25a and 25a which are located on a side of the head portion 29a. Each first cutout surface 25b has a flat rectangular bottom surface perpendicular to an axis of the bolt insertion hole 25a, and is formed in a concave groove shape in a cross section taken parallel to the axial direction of control shaft main body 25 and the axial direction of shaft portion 29b. Each first cutout surface 25b functions as a seat surface on which the seat portion 29c of bolt 29 is seated.
The control eccentric shaft 26 rotatably supports the tubular base portion 15a of rocker arm 15. The control eccentric shaft 26 is formed in a rod shape having its axial length approximately equal to a length (distance) between the pair of first protruding portions 28 and 28. Both end portions of the control eccentric shaft 26 are formed with a pair of female threaded holes 26a and 26a each of which passes completely through the control eccentric shaft 26 in the radial direction of control eccentric shaft 26. Each of the pair of female threaded holes 26a and 26a is a fixing hole into which the male threaded portion of the tip portion of shaft portion 29b of bolt 29 is screwed. The control eccentric shaft 26 is formed with a pair of second cutout surfaces 26b and 26b. Each of the pair of second cutout surfaces 26b and 26b is formed at an outer circumferential surface of one hole-edge side of the female threaded hole 26a. Each second cutout surface 26b has a flat rectangular bottom surface perpendicular to an axis of the female threaded hole 26a, and is formed in a concave groove shape in a cross section taken parallel to the axial direction of control eccentric shaft 26 and the axial direction of shaft portion 29b of bolt 19. Each second cutout surface 26b is in contact with the top surface 28a of first protruding portion 28. According to this embodiment, each female threaded hole 26a does not necessarily need to pass completely through the control eccentric shaft 26.
Moreover, a tip portion of each first protruding portion 28, i.e., a tip portion of each bolt insertion hole 25a is formed with a cylindrical groove having a diameter approximately equal to a diameter of a cylindrical groove formed at a tip portion of each female threaded hole 26a of control eccentric shaft 26 which is located on the side of first protruding portion 28. The cylindrical groove of first protruding portion 28 and the cylindrical groove of control eccentric shaft 26 are formed to be continuous with each other while facing each other. A collar 30 which is a tubular positioning member is disposed inside the cylindrical grooves of the first protruding portion 28 and the control eccentric shaft 26. That is, a pair of collars 30 and 30 are provided respectively to both end portions of the control eccentric shaft 26. As shown in
Moreover, an annular passage 34 is formed between an outer circumferential surface of the shaft portion 29b of bolt 29 and an inner circumferential surface of bolt insertion hole 25a of one of the pair of first protruding portions 28 and 28 and also between the outer circumferential surface of shaft portion 29b and an inner circumferential surface of the collar 30. This annular passage 34 communicates with the oil supplying hole 27. That is, the annular passage 34 is a second lubricating-oil passage which communicates with the first lubricating-oil passage (oil supplying hole 27) and which is open to the outer circumferential surface of control shaft main body 25. An oil passage hole 35 communicating with the annular passage 34 is formed inside the control eccentric shaft 26, as shown in
An upstream end of the oil supplying hole 27 communicates with a main oil gallery (not shown) for supplying lubricating oil to sliding portions of the engine and the like. An upstream end of the annular passage 34 is open to the oil supplying hole 27, and a downstream end of the annular passage 34 is open to an upstream end of the oil passage hole 35.
The oil passage hole 35 includes an axial hole 35a and a branch hole 35b. The axial hole 35a is formed inside the control eccentric shaft 26 to extend in the axial direction of control eccentric shaft 26. The branch hole 35b branches off or arises from a downstream end of the axial hole 35a, and extends from the downstream end of axial hole 35a in a radial direction of the control eccentric shaft 26. An edge of upstream end of the axial hole 35a is blocked (closed) by a ball plug 36. On the other hand, both ends of the branch hole 35b are open to an annular groove 15e. This annular groove 15e is formed in an inner circumferential surface of the support hole 15d of tubular base portion 15a.
As shown in
The electric motor 32 is constructed by a proportional DC motor. This electric motor 32 is driven by control signals that are outputted from an electronic controller 37 configured to detect the operating state of engine. The electronic controller 37 detects the current operating state of engine, e.g., by calculations using detection signals derived from a crank angle sensor for sensing an engine rotational speed, an air flow meter for sensing an amount of intake air, a water-temperature sensor for sensing a water temperature of the engine or the like. Moreover, the electronic controller 37 receives signals from a potentiometer for sensing a rotational position of the control shaft 24, and the like. Thereby, the electronic controller 37 controls the electric motor 32 by way of feedback control. Since the rotation of actuator 31 is driven by such an electric motor 32, a prompt responsivity in change can be obtained irrespective of oil temperature of engine and the like.
The actuator 31 controls the control eccentric shaft 26 through the control shaft main body 25, to cause the control eccentric shaft 26 to rotate in forward and reverse directions. By this rotational position of the control eccentric shaft 26, the valve lift amount (i.e., the lift-amount characteristic and working angle) of intake valve 3 is controlled through the transmission mechanism 8 and the like, from a minute lift to a maximum lift.
Operations of the valve control apparatus according to the first embodiment will now be explained.
For example, at the time of low-speed operation of the engine (in a low-speed operation region of engine) such as at the time of engine idling, the electric motor 32 is driven (rotated) by control signals derived from the electronic controller 37. This rotational torque of the electric motor 32 rotates the control shaft 24 up to a predetermined rotational position in a counterclockwise direction by the ball screw mechanism 33, for example as shown in
When the rocker arm 15 is raised upwardly by the link arm 16 in response to the rotation of drive cam 5 from the state shown by
Thus, in this operating region of engine (low-speed and low-load region), the valve lift amount (lift-amount characteristic) of each intake valve 3 is sufficiently small. Therefore, an opening timing of each intake valve 3 is delayed so that a valve overlap between the intake valve 3 and an exhaust valve is avoided. Hence, an improvement of combustion and the like can be obtained to attain an enhancement of fuel economy and a stable rotation of the engine.
Next, when the state of engine changes to a low-and-middle-speed and middle-load region, the control shaft 24 is rotated further in the counterclockwise direction from the state shown in
Thereby, whole of the transmission mechanism 8 including the rocker arm 15 and the link arm 16 is tilted around the drive shaft 4 in the clockwise direction. Hence, also each swing cam 7 rotates relatively in the clockwise direction (lift direction).
Accordingly, at the time of peak lift which is produced because of the rotation of drive cam 5, a lift of the swing cam 7 is transmitted to the roller 14 of swing arm 6 so that the intake valve 3 is lifted. At this time, both of the lift amount and working angle of intake valve 3 are larger than those of the low-speed operation region. That is, middle lift and middle working angle of each intake valve 3 are achieved.
Thus, in this operating region of engine, the valve lift amount (characteristic) and the working angle of each intake valve 3 are relatively large. Therefore, the improvement of fuel economy and an enhancement of engine torque can be achieved.
Next, when the state of engine changes to a high-speed and high-load region, the control shaft 24 is rotated further in the counterclockwise direction, by the ball screw mechanism 33 driven by the electric motor 32 controlled by the electronic controller 37. Thereby, as shown in
Thereby, whole of the transmission mechanism 8 including the rocker arm 15 and the link arm 16 is further tilted around the drive shaft 4 in the clockwise direction. Hence, also each swing cam 7 rotates further in the clockwise direction (lift direction). Accordingly, at the time of peak lift which is produced by the rotation of drive cam 5, a lift of the swing cam 7 is transmitted to the roller 14 of swing arm 6 so that the intake valve 3 is lifted. At this time, both of the lift amount and working angle of intake so valve 3 are larger than those of the low-and-middle-speed and middle-load region. That is, maximum lift and maximum working angle of each intake valve 3 are achieved.
Thus, in this operating region of engine, the is valve lift amount (characteristic) and the working angle of each intake valve 3 are maximized. Therefore, the valve overlap between the intake valve 3 and the exhaust valve is increased, and a closing timing of each intake valve 3 is sufficiently delayed. As a result, an intake-air charging efficiency is enhanced so that a sufficient output power of engine can be secured.
According to this first embodiment, the control eccentric shaft 26 can be attached and fixed to the respective protruding portions 28 and 28 of control shaft main body 25 in the radial direction, by using the bolts 29 and 29. Accordingly, a process (installation work) for this attachment is very easy. Hence, whole structure of the valve control apparatus can be simplified so that a manufacturing operation becomes simple. Therefore, a cost reduction can be achieved.
Moreover, according to the first embodiment, as mentioned above, the control shaft 24 can be formed in a crank shape which produces the large eccentric amount α, by attaching the control eccentric shaft 26 to the control shaft main body 25. Accordingly, it is not necessary to form (assemble) the rocker arm 15 from some divided pieces given for the rocker arm, as disclosed in the technique other than the present application. Hence, in this embodiment, an increase of weight of the valve control apparatus is suppressed to achieve a reduction in size and weight. Thus, since the sufficient weight reduction of the valve control apparatus can be attained, a drivability (operability) of the engine becomes preferable in the high-speed region of engine. Furthermore, since the size reduction can be attained, a mounting performance of apparatus to an inside of engine compartment becomes preferable to improve a flexibility of layout.
Moreover, according to the first embodiment, the head portion 29a of each bolt 29 is in contact with the first cutout surface 25b of control shaft main body 25 under the state where the head portion 29a has been fitted into the concave groove shaped by forming the first cutout surface 25b. Accordingly, an amount by which the head portion 29a protrudes from (an outer circumferential surface of) the control shaft main body 25 is small. Hence, also from this point of view, the downsizing of valve control apparatus can be enhanced so that the mounting performance of apparatus to the engine compartment is greatly improved. Since the seat portion 29c of head portion 29a abuts on a part of the first cutout surface 25b which is formed as the bottom of concave groove, the downsizing of valve control apparatus can be further enhanced.
Moreover, according to the first embodiment, the lubricating oil supplied to the oil supplying hole 27 is forcibly supplied through the annular passage 34 and the oil passage hole 35 to the annular groove 15e. Accordingly, a sufficient lubrication can be performed for a sliding portion between the outer circumferential surface of control eccentric shaft 26 and the support hole 15d of tubular base portion 15a of rocker arm 15. As a result, the rocker arm 15 can be smoothly swung at all times.
Moreover, according to the first embodiment, a means for performing the lubrication between the control eccentric shaft 26 and the tubular base portion 15a is formed by using inside portions of the protruding portion 28 and the control eccentric shaft 26. Accordingly, a simplification of the lubricating means can be achieved. Also from this point of view, the manufacturing operation becomes easy.
Moreover, according to the first embodiment, the control eccentric shaft 26 is tightened and fixed to the control shaft main body 25 by the pair of bolts 29 and 29 under the state where the top surfaces 28a and 28a of protruding portions 28 and 28 of control shaft main body 25 respectively abut on the pair of second cutout surfaces 26b and 26b of control eccentric shaft 26. Hence, a press-contact force between each second cutout surface 26b and the corresponding top surface 28a is strong, so that a sufficient adhesiveness (i.e., sufficient sealing performance) can be obtained. Therefore, a leakage of lubricating oil from a portion between the annular passage 34 and the oil passage hole 35 can be sufficiently suppressed.
Moreover, according to the first embodiment, the seat portions 29c and 29c of the pair of bolts 29 and 29 are stably seated on (mounted in contact with) the first cutout surfaces 25b and 25b of control shaft main body 25. Accordingly, an axial force of each bolt 29 can be enhanced, so that an mounting strength of the control eccentric shaft 26 can be high.
Moreover, according to the first embodiment, the positioning for the control eccentric shaft 26 relative to the protruding portions 28 and 28 is easy because of the usage of pair of collars 30 and 30. Hence, an mounting operation of the control eccentric shaft 26 is easy.
[Second Embodiment]
The both boss portions 38 and 38 are located on an radially opposite side of the control shaft main body 25 from the protruding portions 28 and 28, namely are provided along diameter lines of control shaft main body 25 which pass through the protruding portions 28 and 28. That is, each of the boss portions 38 and 38 is provided along the center axis of the protruding portion 28. Each of the boss portions 38 and 38 is formed integrally with the control shaft main body 25, and is formed in an approximately cylindrical shape in the same manner as the protruding portion 28. Moreover, each of the boss portions 38 and 38 is formed with the bolt insertion hole 25a which passes completely through the boss portion 38 in an axial direction of the boss portion 38 (=the axial direction of bolt insertion hole 25a), in the same manner as the protruding portion 28. An top surface (outer end surface) 38a of each boss portion 38 is formed to be a flat surface perpendicular to the axial direction of bolt insertion hole 25a. The seat portion 29c of each bolt 29 is seated on this top surface 38a.
In the second embodiment, each of the pair of bolts 29 and 29 is longer than that of the first embodiment, by an axial length of the boss portion 38.
Therefore, according to the second embodiment, the respective boss portions 38 and 38 are provided instead of the first cutout surfaces 25b and 25b. Accordingly, a rigidity of the control shaft main body 25 is sufficiently enhanced as compared with the structure of the first embodiment.
Hence, a torsional deformation and a bending deformation of the control shaft main body 25 are suppressed during the rotation of control shaft main body 25. Moreover, since a tightening force of each bolt 29 can be enlarged, the axial force of each bolt 29 is increased to further enhance the mounting strength and the sealing performance of the control eccentric shaft 26. The other advantageous effects are same as the first embodiment.
[Third Embodiment]
The pair of boss portions 38 and 38 are provided to the control shaft main body 25 in the same manner as the second embodiment. A female threaded hole 38b is formed in each boss portion 38 and in a portion of the control shaft main body 25 which is located on the boss portion 38, in an axial direction of the boss portion 38 (i.e., perpendicularly to the axial direction of control shaft main body 25). Each female threaded hole 38b is formed to be continuous with the bolt insertion hole 25a, and passes completely through the boss portion 38. This female threaded hole 38b functions as a fixing hole for the bolt 29. Moreover, the bolt insertion hole 25a is formed in each protruding portion 28 in the axial direction of the protruding portion 28, to pass completely through the protruding portion 28. It is noted that the respective female threaded holes 38b and 38b do not necessarily need to pass completely through the boss portions 38 and 38.
On the other hand, bolt insertion holes 26c and 26c are formed in both end portions of the control eccentric shaft 26 in the diameter direction (radial direction) of control eccentric shaft 26, instead of the female threaded holes 26a and 26a of the first embodiment. Each of the bolt insertion holes 26c and 26c passes completely through the control eccentric shaft 26. Each of the both end so portions of control eccentric shaft 26 includes a third cutout surface 26d formed in an opposite side of the control eccentric shaft 26 from the control shaft main body 25 (i.e., in a lower side of the end portion of control eccentric shaft 26 in
According to the third embodiment, the control eccentric shaft 26 is attached to the control shaft main body 25 by passing the pair of bolts 29 and 29 from the side of drive shaft 4 through the bolt insertion holes 26c and 26c of control eccentric shaft 26 and then by screwing the bolts 29 and 29 into the female threaded holes 38b and 38b of control shaft main body 25. Accordingly, the head portion 29a of each bolt 29 does not largely project from the control shaft main body 25. As a result, a sufficient axial force of each bolt 29 can be obtained while attaining a downsizing of the valve control apparatus in the radial direction. The other advantageous effects are same as the first embodiment.
[Fourth Embodiment]
A third protruding portion 39 is further provided integrally with the control shaft main body 25, at a center portion between the pair of protruding portions 28 and 28 of control shaft main body 25. As shown in
An outer diameter of the third protruding portion 39 is slightly smaller than those of the protruding portions 28 and 28. The third protruding portion 39 is formed with an oil hole 40 which passes completely through the third protruding portion 39 in the radial direction of control shaft main body 25 (i.e., in an axial direction of third protruding portion 39). The oil hole 40 functions as the second lubricating-oil passage which communicates with the first lubricating-oil passage (oil supplying hole 27). Moreover, a top surface (tip surface) 39a of the third protruding portion 39 is formed as a flat surface perpendicular to the axial direction of third protruding portion 39.
On the other hand, a fitting groove 26e is formed in the outer circumferential surface of the control eccentric shaft 26, and is located at an approximately center of the control eccentric shaft 26 relative to the axial direction of control eccentric shaft 26. The fitting groove 26e has a flat bottom surface which is in contact with the third protruding portion 39. That is, the top surface 39a of third protruding portion 39 is in press-contact with the bottom surface of fitting groove 26e by the tightening force of bolts 29 and 29. The control eccentric shaft 26 is formed to have a relatively long length in conformity with the relatively long span between the protruding portions 28 and 28. The control eccentric shaft 26 is formed with an oil passage hole 41 located in an approximately center portion of the control eccentric shaft 26 relative to the axial direction of control eccentric shaft 26. The oil passage hole 41 functions as the third lubricating-oil passage.
The oil passage hole 41 includes a large-diameter hole 41a and branch holes 41b and 41c. The large-diameter hole 41a is located at a center of the control eccentric shaft 26 relative to the axial direction of control eccentric shaft 26, and is formed to be drilled into the control eccentric shaft 26 in the radial direction of control eccentric shaft 26. The branch holes 41b and 41c are formed to branch off (arise) from a downstream end of the large-diameter hole 41a, and extend from the downstream end of large-diameter hole 41a in an inverted-V shape in a cross section taken by a plane including the shaft center of control shaft main body 25. The large-diameter hole 41a is formed to have a short length in the axial direction of control eccentric shaft 26, and communicates with the oil hole 40 to be continuous with the oil hole 40. On the other hand, upstream ends of the branch holes 41b and 41c are respectively open to axial both sides of the large-diameter hole 41a, and downstream ends 41d and 41e of the branch holes 41b and 41c are respectively open to inner circumferential surfaces of the bifurcated portions of tubular base portion 15a of rocker arm 15. The other structures in the fourth embodiment are similar as the first embodiment. Hence, the structures similar as the first embodiment are given the same reference signs as the first embodiment, and explanations thereof will be omitted for the purpose of simplification of the disclosure.
According to the fourth embodiment, a lubricating oil supplied from the oil supplying hole 27 to the oil hole 40 is supplied to the large-diameter hole 41a. Then, the lubricating oil is supplied from the large-diameter hole 41a to the branch holes 41b and 41c by split flow, and then, is forcibly delivered to a portion (gap) between the outer circumferential surface of control eccentric shaft 26 and the inner circumferential surfaces of the bifurcated portions of tubular base portion 15a. Accordingly, a lubricating property between the control eccentric shaft 26 and the tubular base portion 15a is favorable. Therefore, the rocker arm 15 can perform a smooth swing motion at all times.
Moreover, according to the fourth embodiment, the top surface 39a of third protruding portion 39 is tightly in intimate contact with the bottom surface of fitting groove 26e of control eccentric shaft 26. Accordingly, its sealing performance is enhanced, so that a leakage of lubricating oil between the oil hole 40 and the large-diameter hole 41a can be suppressed.
Moreover, according to the fourth embodiment, the axial length of tubular base portion 15a is relatively long together with the control eccentric shaft 26. Accordingly, a strength balance between the rocker arm 15 and the control eccentric shaft 26 is improved. In addition, a fall (inclination) of the rocker arm 15 in the axial direction of control eccentric shaft 26 can be suppressed during the swing of rocker arm 15. The other advantageous effects are same as the first embodiment.
Although the present invention has been described above with reference to the first and fourth embodiments of the present invention, the present invention is not limited to the embodiments described above. Modifications and variations of the embodiments described above will occur to those skilled in the art in light of the above teachings.
For example, the valve control apparatus according to the present invention is also applicable to an exhaust-valve side of engine. Moreover, the speed reducer according to the present invention is not limited to the ball screw mechanism 33 described above.
Moreover, in the above embodiments, the bolt 29 is described as a fixing member (fixing means) for fixing the control eccentric shaft 26 to the control shaft main body 25 by means of the axial force of the fixing member which is applied through the insertion holes and the fixing holes. However, the fixing member for fixing the control eccentric shaft 26 to the control shaft main body 25 according to the present invention is not limited to the bolt. For example, a rivet may be used as the fixing member.
Some technical structures obtainable from the above embodiments according to the present invention will now be listed as follows.
Accordingly, as an advantageous effect, for example, the rocker arm (15) becomes able to be easily attached to the control shaft (24) without increasing the weight of rocker arm (15).
According to this structure, since the control eccentric shaft (26) is coupled and fixed to the control shaft main body (25) by the fastening force of bolts (29), a hole edge of opening end of the second lubricating-oil passage (34, 40) is brought into intimate contact with a hole edge of opening end of the third lubricating-oil passage (35, 41b, 41c) facing the opening end of second lubricating-oil passage (34, 40), by the axial force of bolts (29). Therefore, a sealing property between the both opening ends facing and abutting on each other is favorable so that a leakage of lubricating oil can be sufficiently suppressed.
According to this structure, the control eccentric shaft (26) is supported under the state where the both end portions of control eccentric shaft (26) are respectively in contact with the tip edges (top surfaces) of the first protruding portions (28). Therefore, the eccentric amount (eccentricity) of control eccentric shaft (26) relative to the control shaft main body (25) can be arbitrarily set by setting a protruding amount of each first protruding portion (28).
According to this structure, the first cutout surface (25b) of control shaft main body (25) can be used as a seat surface for the head portion (29a) of bolt (29).
According to this structure, when the control eccentric shaft (26) is fixed to the control shaft main body (25) by the bolts (29), the tip edge of each first protruding portion (28) becomes in contact with the corresponding flat second cutout surface (26b) under a press attachment by the axial force of bolts (29). Therefore, a good sealing property is ensured between the tip edges of first protruding portions (28) and the second cutout surfaces (26b).
According to this structure, since the base end portion (15a) of rocker arm (15) is formed in the bifurcated shape, the strength of the base end portion (15a) is enhanced while enlarging the axial length of whole of the base end portion (15a). Therefore, the fall (inclination) of the rocker arm (15) in the axial direction can be suppressed during the swinging motion of rocker arm (15).
According to this structure, when the control eccentric shaft (26) is attached to the control shaft main body (25), a part of the positioning member (30) is inserted and set into, e.g., the insertion hole (25a) of control shaft main body (25) with force in advance, and then, the fixing hole (26a) of control eccentric shaft (26) is engaged with a protruding end of the positioning member (30) so as to be connected with the control shaft main body (25). Therefore, the positioning for the control eccentric shaft (26) becomes easy so that the assembling operation becomes easy.
This application is based on prior Japanese Patent Application No. 2009-284628 filed on Dec. 16, 2009. The entire contents of this Japanese Patent Application are hereby incorporated by reference.
The scope of the present invention is defined with reference to the following claims.
Number | Date | Country | Kind |
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2009-284628 | Dec 2009 | JP | national |
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Japanese Office Action dated Feb. 7, 2012 (three (3) pages). |
Number | Date | Country | |
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20110139102 A1 | Jun 2011 | US |