This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2004-140022, filed on May 10, 2004, the entire contents of which are incorporated herein by reference.
The present invention relates to a collar for receiving a shaft for a variable valve lift mechanism in a multiple-cylinder internal combustion engine.
Japanese Laid-Open Patent Publication No. 2001-263015 describes a variable valve actuation mechanism for an internal combustion engine. The variable valve actuation mechanism includes a variable valve lift mechanism, which is arranged for each cylinder to adjust the lift amount of intake and exhaust valves. A support pipe (rocker shaft) extends through the center of the variable valve lift mechanism. A control shaft is arranged in the support pipe. The variable valve lift mechanism is pivoted in a state supported by the support pipe. The lift amount of the valve is adjusted by moving the control shaft in the axial direction.
The support pipes are supported by a plurality of supports arranged on a cylinder head between the variable valve lift mechanisms. The supports position the variable valve lift mechanisms in the axial direction. The valve lift mechanisms are positioned in the axial direction with high accuracy so that the movement of the control shaft adjusts the valve lift amount to be the same in every cylinder.
In an internal combustion engine, the cylinder block, cylinder head, and cam carrier are formed from a light alloy or a light metal, such as aluminum, to reduce weight. However, shafts included in the variable valve actuation mechanism, such as the control shaft, are not formed from a light alloy or a light metal and formed from a steel material, such as cast steel or cast iron, to meet the high strength requirements.
The coefficient of thermal expansion differs greatly between light alloy and steel. Thus, when comparing a state in which the engine is cool and a state in which the engine is warm, the control shaft becomes shorter and changes the interval between the supports located closer to the cylinder head and cam carrier. This produces a difference in the relative positions of the control shaft and the variable valve lift mechanism between cylinders close to the basal end of the control shaft and cylinders close to the distal end of the control shaft. Accordingly, the lift amount differs between cylinders. Such difference causes difficulties for adjusting the combustion state of each cylinder with high accuracy. This may generate vibrations or deteriorate emission and cause an undesirable engine operation state.
The rocker shaft, which supports the variable valve lift mechanism, is arranged at the outer side of the control shaft. When the rocker shaft, which receives the control shaft, has a large diameter, the variable valve lift mechanism that receives the rocker shaft is enlarged. This enlarges and increases the weight of the variable valve actuation mechanism, which would contradict the demand for a smaller and lighter internal combustion engine.
It is an object of the present invention to provide a variable valve actuation mechanism that substantially equally adjusts the valve lift amount in each cylinder. Another object of the present invention is to provide a compact and light variable valve actuation mechanism. A further aspect of the present invention is to provide a collar for such a variable valve actuation mechanism.
One aspect of the present invention is a collar for receiving a shaft of a multiple cylinder engine. The shaft supports a plurality of variable valve lift mechanisms respectively arranged in correspondence with a plurality of cylinders. Each variable valve lift mechanism has an end face, and the engine includes a plurality of supports for supporting the shaft. The collar includes a sleeve extending in an axial direction and end portions formed integrally with the sleeve. In use, a plurality of said collars are fastened to the shaft, with the sleeve of each collar being arranged between the shaft and a corresponding one of the supports so that at least one of the end portions directly or indirectly contacts or engages the end face of one of the variable valve lift mechanisms to determine the positions of the variable valve lift mechanisms.
Another aspect of the present invention is a variable valve actuation mechanism for use in a multiple cylinder engine. The variable valve actuation mechanism includes a plurality of variable valve lift mechanisms respectively arranged in association with the cylinders of the engine. Each variable valve lift mechanism includes an end face. A control shaft extends through the variable valve lift mechanisms in an axial direction. An actuator moves the control shaft in the axial direction and drives the variable valve lift mechanisms. A plurality of collars are arranged alternately with the variable valve lift mechanisms for determining the positions of the variable valve lift mechanisms with respect to one another in the axial direction. Each collar includes a sleeve extending in the axial direction and end portions formed integrally with the sleeve. At least one of the end portions directly or indirectly contacts the end face of one of the variable valve lift mechanisms.
A further aspect of the present invention is a variable valve actuation mechanism for use in a multiple cylinder engine. The variable valve actuation mechanism includes a plurality of variable valve lift mechanisms respectively arranged in association with the cylinders of the engine. Each variable valve lift mechanism includes an end face. A control shaft extends through the variable valve lift mechanisms in an axial direction. An actuator moves the control shaft in the axial direction and drives the variable valve lift mechanisms. A plurality of collars are arranged alternately with the variable valve lift mechanisms for determining the positions of the variable valve lift mechanisms with respect to one another in the axial direction. Each collar includes a sleeve extending in the axial direction and end portions formed integrally with the sleeve. At least one of the end portions engages the end face of an adjacent one of the variable valve lift mechanisms and includes a shaft projection functioning as part of a pivot shaft of the variable valve lift mechanisms.
Another aspect of the present invention is a variable valve actuation mechanism for use in a multiple cylinder engine. The variable valve actuation mechanism includes a plurality of variable valve lift mechanisms respectively arranged in association with the cylinders of the engine. Each variable valve lift mechanism includes an end face. A control shaft extends through the variable valve lift mechanisms in an axial direction. An actuator moves the control shaft in the axial direction and drives the variable valve lift mechanisms. A plurality of collars are arranged alternately with the variable valve lift mechanisms for determining the positions of the variable valve lift mechanisms with respect to one another in the axial direction. Each collar includes a sleeve extending in the axial direction and end portions formed integrally with the sleeve. At least one of the end portions directly or indirectly contacts the end face of an adjacent one of the variable valve lift mechanisms to determine the positional relationship between the variable valve lift mechanisms in the axial direction, and includes a shaft projection for engaging the end face of the one of the variable valve lift mechanisms to function as part of a pivot shaft of the variable valve lift mechanism.
A further aspect of the present invention is a variable valve actuation mechanism for use in a multiple cylinder engine. The variable valve actuation mechanism includes a plurality of variable valve lift mechanisms respectively arranged in association with the cylinders of the engine. Each variable valve lift mechanism has an end face. A control shaft extends through the variable valve lift mechanisms in an axial direction. A hollow shaft receives the control shaft. The hollow shaft is formed from a metal material having a first coefficient of thermal expansion. An actuator moves the control shaft in the axial direction and drives the variable valve lift mechanisms. A plurality of collars are fastened to the hollow shaft and arranged alternately with the variable valve lift mechanisms for determining the positions of the variable valve lift mechanisms with respect to one another in the axial direction. A plurality of supports respectively support the collars. Each collar includes a sleeve extending in the axial direction and end portions formed integrally with the sleeve. The sleeve and the at least one end portion is formed from a material having a coefficient of thermal expansion that is equal to or approximate to the first coefficient of thermal expansion. Each collar is supported by the corresponding support such that a clearance is formed between the end face of an adjacent one of the variable valve lift mechanisms and the corresponding support. The contact shaft and the support holding the collar such as to restrict the sleeve from becoming eccentric while enabling movement of the collar in the axial direction.
Another aspect of the present invention is a variable valve actuation mechanism for use in a multiple cylinder engine. The variable valve actuation mechanism includes a plurality of variable valve lift mechanisms respectively arranged in association with the cylinders of the engine. Each variable valve lift mechanism has an end face. A control shaft extends in an axial direction. The variable valve lift mechanisms are fastened to a hollow shaft, which receives the control shaft. An actuator moves the control shaft in the axial direction and drives the variable valve lift mechanisms. A plurality of supports support the variable valve lift mechanisms via the hollow shaft. The variable valve lift mechanisms are fastened to the hollow shaft in a state in which movement in the axial direction is restricted in order to determine the positions of the variable valve lift mechanisms with respect to one another in the axial direction.
Other aspects and advantages of the present invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
The engine 2 includes a cylinder block 4, pistons 6, and a cylinder head 8 mounted on the cylinder block 4. The cylinder block 4 and the cylinder head 8 are formed from an aluminum alloy material.
A plurality of (four) cylinders 2a are defined in the cylinder block 4. A combustion chamber 10 is defined in each cylinder 2a between the cylinder block 4, the corresponding piston 6, and the cylinder head 8. Two intake valves 12 and two exhaust valves 16 are arranged in each cylinder 2a. The intake valves 12 and the exhaust valves 16 respectively open and close associated intake ports 14 and exhaust ports 18.
Each intake port 14 is connected to a surge tank via an intake passage formed in an intake manifold. Each cylinder 2a is supplied with air from the surge tank. A fuel injector is arranged in each intake passage to inject fuel into the intake port 14 of the corresponding cylinder 2a. In this manner, fuel is supplied to a position upstream from the intake valve 12. Fuel may be directly supplied into each combustion chamber 10 as in an in-cylinder injection type gasoline engine.
The lift amount of the intake valve 12 is varied to adjust the intake air amount. The engine 2 of the first embodiment does not include a throttle valve that would be arranged in an intake passage upstream from the surge tank in a normal engine. However, the engine 2 of the first embodiment may include an auxiliary throttle valve. When an auxiliary throttle valve is employed, the auxiliary throttle valve is, for example, fully opened when the engine 2 is started and fully closed when the engine 2 is stopped. The open amount of the auxiliary throttle valve may be adjusted to control the intake air amount when lift amount adjustment of the intake valves 12 with valve lift mechanisms 120 is disabled.
Referring to
Referring to
A variable valve timing mechanism 140 is arranged at the front end of the intake camshaft 45. The intake camshaft 45 rotates in cooperation with the rotation of a crankshaft 49 of the engine 2 by means of a timing sprocket of the variable valve timing mechanism 140 and a timing chain 47.
An exhaust camshaft 46 is rotated in cooperation with rotation produced by the engine 2. Exhaust cams 46a arranged on the exhaust camshaft 46 open and close corresponding exhaust valves 16 with a constant lift amount by means of roller rocker arms 54. Each exhaust port 18 is connected to an exhaust manifold. Exhaust passes through a purification catalyst converter before being discharged.
The intake camshaft 45, the exhaust camshaft 46, the slide actuator 100, the variable valve lift mechanisms 120, and the variable valve timing mechanism 140 are incorporated as a single unit in the cam carrier 150.
The cam carrier 150 includes a front wall 154, a rear wall 156, and two side walls 158 and 160. In the internal space defined by the walls 154, 156, 158, and 160, four parallel bearings 162 extends so as to connect the side walls 158 and 160. The walls 154 to 160 and the bearing 162 are formed integrally. The front wall 154 also functions as a bearing. The cam carrier 150 is formed from the same aluminum alloy material as the cylinder block 4 and the cylinder head 8.
The bearings 162 and the front wall 154 support the intake camshaft 45 and the exhaust camshaft 46 in a manner that they are parallel to each other and rotatable. The four variable valve lift mechanisms 120, which are respectively arranged in correspondence with the cylinders 2a, three intermediate collars 164, and two end collars 166, are arranged between the intake camshaft 45 and the side wall 158. The three intermediate collars 164 are arranged between the four variable valve lift mechanisms 120. The two end collars 166 are arranged at the outer sides of the two outer variable valve lift mechanisms 120. A rocker shaft 130, which commonly extends through the four variable valve lift mechanisms 120, supports the collars 164 and 166.
Referring to
Referring to
The variable valve lift mechanisms 120 will now be discussed with reference to FIGS. 6 to 9.
Each variable valve lift mechanism 120 includes an input sleeve 122 (input portion), a first rocking cam 124 (output portion) arranged rearward from the input sleeve 122, a second rocking cam 126 (output portion) arranged frontward from the input sleeve 122, and a slider gear 128 arranged in the input sleeve 122.
The input sleeve 122 includes a housing 122a defining a cylindrical hollow space. A helical spline 122b (
The first rocking cam 124 includes a housing 124a that defines a cylindrical internal space. A helical spline 124b (
The second rocking cam 126 includes a housing 126a that defines a cylindrical internal space. A helical spline 126b (
Referring to
FIGS. 10 to 12 show the slider gear 128 retained in the housings 122a, 124a, and 126a. The slider gear 128 includes an input helical spline 128a, a first output helical spline 128c, and a second helical spline 128e. Each groove of the input helical spline 126b extends helically about the axis of the slider gear 128 in the direction of a right-hand thread. A small diameter portion 128b is formed between the input helical spline 128a and the first output helical spline 128c. A further small diameter portion 128d is formed between the input helical spline 128a and the second output helical spline 128e. Each groove of the first output helical spline 128c and the second output helical spline 128e extend helically about the axis of the slider gear 128 in the direction of a left-hand thread. The diameter of the first output helical spline 128c and the diameter of the second output helical spline 128e are smaller than that of the input helical spline 128a.
Referring to
The rocker shaft 130 is hollow and includes an interior space 130b. Four elongated holes 130a are formed in the outer surface of the rocker shaft 130 at positions corresponding to the variable valve lift mechanisms 120.
The control shaft 132 includes support holes 132b respectively located at positions corresponding to the variable valve lift mechanisms 120. Each support hole 132b receives the basal portion of a control pin 132a. Each control pin 132a, which is supported by the corresponding support hole 132b, extends perpendicular to the axis of the control shaft 132.
When the control shaft 132 is received in the rocker shaft 130, each control pin 132a projects from the corresponding elongated hole 130a of the rocker shaft 130. Referring to
The rocker shaft 130, the control shaft 132, and the control pin 132a are formed from a steel material and have high strength.
Referring to
The assembly of the variable valve lift mechanisms 120, the rocker shaft 130, the control shaft 132, and the collars 164 and 166 will now be described.
The control shaft 132 is first inserted through the rocker shaft 130. Referring to
Among the five cam caps 152, the distal end of a bolt 170 for fastening the cam cap 152 located near the slide actuator 100 is inserted through the pin hole 166c of the corresponding collar 166 and into the pin hole 130c of the rocker shaft 130. Accordingly, the collar 166 located near the slide actuator 100 is fixed to the rocker shaft 130 by the bolt 170 when fastening the cam cap 152. In this manner, as shown in the state of
During the assembly, shim plates 172, which are formed from a steel material, are arranged between the variable valve lift mechanisms 120 and the collars 164 and 166 if necessary to adjust the position of each variable valve lift mechanism 120. In this case, the flanges 164b and 166b of the collars 164 and 166 indirectly contact the end faces of the adjacent variable valve lift mechanisms 120.
The shaft assembly shown in
As shown in
The slide actuator 100 drives a ball screw mechanism 210 (
Referring to
The input helical spline 128a of the slider gear 128 meshes with the helical spline 122b of the input sleeve 122. The first output helical spline 128c meshes with the helical spline 124b of the first rocking cam 124. The second output helical spline 128e meshes with the helical spline 126b of the second rocking cam 126. The input splines 122b and 128a differ from the splines 124b, 128c, 126b, and 128e in the helical direction (helical angle) relative to the control shaft 132.
Referring to
When the slide actuator 100 axially moves the control shaft 132, the slider gear 128 axially moves in the internal space of the corresponding variable valve lift mechanism 120. The helical splines 128a, 122b, 128c, 124b, 128e, and 126b function to relatively rotate the input sleeve 122 and the rocking cams 124 and 126. In this embodiment, the input sleeve 122 rotates in a direction opposite to that of the rocking cams 124 and 126. The rotation angle of the input sleeve 122 and the rocking cams 124 and 126 are determined in accordance with the movement of the slider gear 128. Accordingly, adjustment of the movement amount of the control shaft 132 changes the positions (angle along the circumferential direction of the rocker shaft 130) of the rollers 122f relative to the noses 124d and 126d. This adjusts the lift amount of the intake valves 12.
The control shaft 132 axially moves between the state of
In the example of
In the first embodiment, the rocker shaft 130 functions as a shaft (hollow shaft). The front wall 154 and the bearings 162 of the cam carrier 150 function as supports. The flanges 164b and 166b formed on the ends of the sleeves 164a and 166a function to position the variable valve lift mechanisms 120. The shaft assembly (
The first embodiment has the advantages described below.
The ends of the collars 164 and 166, or the flanges 164b and 166b, directly contact the end faces of the rocking cams 124 and 126 or indirectly contact the end faces of the rocking cams 124 and 126 by means of the shim plates 172 in the variable valve lift mechanisms 120. This contact determines the distance (positional relationship) between the variable valve lift mechanisms 120 in the axial direction. The flanges 164b and 166b are spaced from the front wall 154, the bearings 162, and the cam caps 152 by clearance C. Accordingly, changes in the interval of the supports (front wall 154 and bearings 162) in the cam carrier 150 does not affect the positional relationship between the variable valve lift mechanisms 120. Even if a difference in coefficient of thermal expansion exists between the cam carrier 150 and the control shaft 132, the coefficient of thermal expansion of the cam carrier 150 does not affect the positional relationship of the variable valve lift mechanisms 120.
The coefficient of thermal expansion of the collars 164 and 166, the input sleeves 122, and the rocking cams 124 and 126 affect the positional relationship of the variable valve lift mechanisms 120. However, the collars 164 and 166, the input sleeves 122, and the rocking cams 124 and 126 are formed from a steel material having a coefficient of thermal expansion that is the same or approximate to that of the material the control shaft 132 is formed from. Accordingly, even if temperature changes affect the collars 164 and 166, the input sleeves 122, and the rocking cams 124 and 126, the change in the positional relationship of the slider gears 128, which is determined by the control shaft 132, is substantially the same as the change in the positions of the input sleeve 122 and the rocking cams 124 and 126. Thus, the intake valves 12 have substantially the same lift amount in all of the cylinders. Since temperature changes do not cause differences between cylinders in the lift amount of the intake valves 12, the accuracy of lift amount adjustment is improved.
A variable valve actuation mechanism according to a second embodiment of the present invention is similar to that of the first embodiment except in that the rocker shaft 130 is omitted. A plurality of collars 364 (
Referring to
Referring to
Referring to
In the shaft assembly shown in
In the second embodiment, the control shaft 332 functions as a shaft. The pivot shaft portions 364c formed on the ends of the sleeves 364a function to position the variable valve lift mechanisms 320.
The second embodiment has the advantages described below.
The pivot shaft portions 364c are formed on opposite ends of each collar 364. The pivot shaft portions 354c pivotally support the adjacent variable valve lift mechanism 320 and function as a pivot shaft of the variable valve lift mechanisms 320. This eliminates the need for a rocker shaft that extends through the variable valve lift mechanisms 320 and reduces the diameter of the variable valve lift mechanisms 320.
A third embodiment of the present invention will now be discussed with reference to
Each variable valve lift mechanism 520 is rotatably supported by pivot shaft portions 564c of the adjacent collar 564 without the use of a rocker shaft. The collar 564 located farthest from the slide actuator 500 is fixed to the front wall 554 by a pin 565 and does not move in the axial direction. The collar 564 located closest to the slide actuator 500 is pushed toward the corresponding variable valve lift mechanism 520 by a spring 567. This keeps the collars 564 in a state directly contacting the variable valve lift mechanisms 520 or in a state indirectly contacting the variable valve lift mechanisms 520 by means of shim plates 572.
In the third embodiment, the cylinder block, the cylinder head, and the cam carrier 550 are formed from an aluminum alloy material. The variable valve lift mechanisms 520, the collars 564, and the shim plates 572 are formed from a steel material.
The control shaft 532 functions as a shaft. The flanges 564b and pivot shaft portions 564c formed on the ends of the sleeves 564a function to position the variable valve lift mechanisms 520.
The third embodiment has the advantages described below.
The flanges 564b of the collars 564 directly contact the end faces of the rocking cams 524 and 526 or indirectly contacts the end faces of the rocking cams 524 and 526 by means of the shim plates 572. This contact determines the positions of the variable valve lift mechanisms 520 in the axial direction. The flanges 564b are spaced with a clearance from the adjacent bearings 562 and cam caps. The positional relationship of the variable valve lift mechanisms 520 is affected only by the coefficient of thermal expansion of the collars 564, the input sleeves 522, and the rocking cams 524 and 526. However, the collars 564, the input sleeves 522, and the rocking cams 524 and 526 are formed from a steel material having a coefficient of thermal expansion that is the same or approximate to that of the material the control shaft 532 is formed from. Accordingly, even if temperature changes affect the collars 564, the input sleeves 522, and the rocking cams 524 and 526, the change in the positions of the slider gears in the variable valve lift mechanisms 520, which is determined by the control shaft 532, is substantially the same as the change in the positions of the input sleeve 522 and the rocking cams 524 and 526. Thus, the intake valves 12 have substantially the same lift amount in all of the cylinders. Since temperature changes do not cause differences between cylinders in the lift amount of the intake valves 12, the accuracy of lift amount adjustment is improved.
The pivot shaft portions 564c are formed on the two ends of each collar 564. The pivot shaft portions 564c rotatably support the adjacent variable valve lift mechanisms 520. Since the pivot shaft portions 564c function as pivot shafts of the variable valve lift mechanisms 520, the diameter of the variable valve lift mechanisms 520 is reduced.
It should be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention. Particularly, it should be understood that the present invention may be embodied in the following forms.
In each of the above embodiments, the variable valve lift mechanisms and the camshafts may be directly mounted on the cylinder head without using a cam carrier.
The engine is not limited to a gasoline engine and may be any type of engine such as a diesel engine. Further, the engine is not limited to an engine used to drive vehicles and may be an engine used for other applications. In addition to lift amount adjustment of intake valves, the present invention may be applied to lift amount adjustment of exhaust valves or lift amount adjustment of both intake and exhaust valves.
In each of the above embodiments, the collars restrict movement of the variable valve lift mechanisms in the axial direction. When using a hollow shaft (rocker shaft) covering the control shaft as in the first embodiment, positioning members such as pins may be arranged on the rocker shaft. The positioning members may restrict movement of the variable valve lift mechanisms in the axial direction. This fixes the positional relationship of the variable valve lift mechanisms with respect to the rocker shaft. Thus, the distance between the bearings arranged on the cam carrier or cylinder head does not affect the positional relationship between the variable valve lift mechanisms.
Accordingly, even if the cylinder head or cam carrier is formed from a material other than steel, such as a light alloy, to reduce weight, a variable valve actuation mechanism may be formed from a material selected in accordance with the strength requirements. Further, even if a temperature change occurs, the valve lift adjustment amount is prevented from differing between cylinders. This improves the accuracy for adjusting the valve lift amount.
The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.
Number | Date | Country | Kind |
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2004-140022 | May 2004 | JP | national |