The present disclosure relates to cylinder heads for internal combustion engines including valve bridges that connect to two similar valves for mutual actuation.
A cylinder head of an internal combustion engine includes at least one intake valve that allows intake air to enter a combustion chamber of the internal combustion engine and at least one exhaust valve that allows exhaust gases (e.g., ignited air and gasoline mixture) to exit the combustion chamber. Some cylinder heads include a valve bridge connecting to two similar valves (e.g., two intake valves or two exhaust valves) such that actuation of the valve bridge moves the two similar valves from a closed position to an open position. When open, the intake valves allow intake air to enter the combustion chamber. When the exhaust valves are opened, exhaust gases are allowed to exit the combustion chamber. When in their respective closed positions, the intake and exhaust valves block the intake air/exhaust gases from entering/exiting the combustion chamber.
In one aspect, a cylinder head assembly is for an internal combustion engine. The cylinder head assembly includes a cylinder head and first and second valves coupled to the cylinder head. The first and second valves are associated with a combustion chamber partially defined by the cylinder head. The cylinder head assembly also includes a fixed member coupled to the cylinder head and a valve bridge engageable with the first and second valves. The valve bridge is axially moveable along an axis relative to the fixed member to move the first and second valves together between an open position and a closed position. The cylinder head assembly further includes an anti-rotation feature between the valve bridge and the fixed member. The anti-rotation feature restricts rotational movement of the valve bridge about the axis.
In another aspect, a cylinder head assembly is for an internal combustion engine. The cylinder head assembly includes a cylinder head and first and second valves coupled to the cylinder head. The first and second valves are associated with a combustion chamber partially defined by the cylinder head. The cylinder head assembly also includes a fixed member coupled to the cylinder head and a valve bridge having a first arm engageable with the first valve and a second arm engageable with the second valve. The valve bridge is receivable through an aperture of the fixed member from above the fixed member for the first and second arms to engage the first and second valves while the fixed member is coupled to the cylinder head.
In yet another aspect, a cylinder head assembly is for an internal combustion engine. The cylinder head assembly includes a cylinder head and first and second valves coupled to the cylinder head. The first and second valves are associated with a combustion chamber partially defined by the cylinder head. The cylinder head assembly also includes a fixed member coupled to the cylinder head. The fixed member includes a wall defining an aperture. The cylinder head assembly further includes a valve bridge having a body received within the aperture of the fixed member, a first arm engageable with the first valve, and a second arm engageable with the second valve. The body slidably engages the wall of the fixed member such that the valve bridge is moveable along an axis relative to the fixed member for the first and second arms to move the first and second valves.
In addition, other aspects of the disclosure will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the disclosure are explained in detail, it is to be understood that the disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The disclosure is capable of supporting other embodiments and being practiced or being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. Terms of degree, such as “substantially,” “about,” “approximately,” etc. are understood by those of ordinary skill to refer to reasonable ranges outside of the given value, for example, general tolerances associated with manufacturing, assembly, and use of the described embodiments.
With reference to
A first fixed member (e.g., a first fixed post 100) is fixedly coupled within a first post aperture 105 of the cylinder head 65 (e.g., threadably coupled to the post aperture 105) for the first fixed post 100 to be positioned between valve stems 110 of the two intake valves 75. The first fixed post 100 includes a first longitudinal axis 115 oriented substantially parallel to a longitudinal axis of each valve stem 110 of the two intake valves 75. In other embodiments, the first longitudinal axis 115 can be obliquely oriented (e.g., about 5 degrees) relative to each longitudinal axis of the valve stems 110 to accommodate a radial combustion chamber 70. Likewise, a second fixed member (e.g., a second fixed post 120) is fixedly coupled within a second post aperture 125 of the cylinder head 65 (e.g., threadably coupled to the post aperture 125) for the second fixed post 120 to be positioned between valve stems 128 of the two exhaust valves 85. The second fixed post 120 includes a second longitudinal axis 130 oriented substantially parallel to a longitudinal axis of each valve stem 128 of the two exhaust valves 85. In other embodiments, the second longitudinal axis 130 can be obliquely oriented (e.g., about 5 degrees) relative to each longitudinal axis of the valve stems 128 to accommodate a radial combustion chamber 70. Each of the first and second fixed posts 100, 120 includes an internal passageway 135 (the passageway 135 of the first fixed post 100 is shown in
With reference to
As shown in
During assembly of the cylinder head assembly 60, the support plate 140 is secured to the cylinder head 65 by fasteners after the valves 75, 85, the valve springs 95, and the fixed posts 100, 120 are coupled to the cylinder head 65. Thereafter, the first valve bridge 200a is inserted downwardly through the intake valve bridge aperture 170 such that the first fixed post 100 is received within the central cavity 212 (
An anti-rotation feature 230 is positioned between the first valve bridge 200a and the support plate 140 to inhibit substantial rotation (e.g., less than 20 degrees, less than 10 degrees, etc.) of the first valve bridge 200a about the first longitudinal axis 115 (e.g., restrict movement of the first valve bridge 200a to maintain the engagement between the intake valves 75 and the arm portion 210). In other words, the anti-rotation feature 230 restricts the first valve bridge 200a to one degree of freedom (i.e., axial movement along the first longitudinal axis 115). The anti-rotation feature 230 includes a bracket 235 secured to the support plate 140 by a fastener 232. In the illustrated embodiment, the bracket 235 is a non-metallic bracket (e.g., a nylon bracket, etc.), however, in other embodiments, the bracket 235 can be a metallic bracket (e.g., an aluminum bracket, etc.). A portion of the bracket 235 is received within a recess 245 formed in the support plate 140 adjacent the intake valve bridge aperture 170 (
A similar assembly process is associated with the second valve bridge 200b as is described above directed to the first valve bridge 200a. For example, the second valve bridge 200b is inserted downwardly through the exhaust valve bridge aperture 195 such that the second fixed post 120 is received within the central cavity 212 of the second valve bridge 200b, the first arm 215 engages an end of the valve stem 128 of one exhaust valve 85, and the second arm 220 engages an end of the valve stem 128 of the other exhaust valve 85. Once the second valve bridge 200b is received on the second fixed post 120, the body 205 is constrained to be coaxial with the second longitudinal axis 130 of the second fixed post 120. A second anti-rotation feature 230 is positioned between the second valve bridge 200b and the support plate 140 to restrict movement of the second valve bridge 200b to one degree of freedom (i.e., axial movement along the second longitudinal axis 130). The exhaust rocker arm 180 is coupled to the second mounting protrusion 175 such that a finger 270 of the exhaust rocker arm 180 engages the end surface 214 of the second valve bridge 200b.
In operation of the engine 40, the intake rocker arm 155 is pivotable by the intake pushrod 165 for the finger 265 of the intake rocker arm 155 to push the first valve bridge 200a axially downwardly along the first longitudinal axis 115 (toward the combustion chamber 70) against the biasing force of the valve springs 95 associated with the intake valves 75. Simultaneously, the arm portion 210 of the first valve bridge 200a moves the intake valves 75 from the closed position (
Furthermore, the first and second fixed posts 100, 120 supply portions of the cylinder head assembly 60 with lubricant. Operation of such lubricant supply will be discussed in respect to the first fixed post 100 as shown in
The disclosed arrangement of the valve bridges 200a, 200b can significantly improve the valve-to-valve imbalance present in known bridge-type valve trains where two similar valves are actuated by a rocker arm through a valve bridge. In the illustrated embodiment, the first valve bridge 200a simultaneously actuates the two intake valves 75 between the open and closed positions for the intake stroke of the engine 40. Likewise, the second valve bridge 200b simultaneously actuates the two exhaust valves 85 between the open and closed positions for the exhaust stroke of the engine 40. Because the valve bridges 200a, 200b are restricted to one degree of freedom, pivotable movement of the rocker arms 155, 180 is not transferred to the valve bridges 200a, 200b, which could cause relative movement between the two intake valves 75 or relative movement between the two exhaust valves 85. Such relative movement of the pair of common valves 75, 85 could decrease performance of the engine 40. However, the improved valve-to-valve actuation uniformity as disclosed in the illustrated embodiment can enable higher engine operating speeds and performance potential than known bridge-type valve trains. For example, the illustrated embodiment can reach a maximum engine operating speed between about 6,800 revolutions per minute (RPM) and about 7,000 RPM, whereas known bridge-type valve trains can only reach a maximum engine operating speed of about 4,000.
Furthermore, maintenance/replacement of the valve bridges 200a, 200b can be easily accomplished by removing the respective rocker arms 155, 180 and anti-rotation feature 230 without removing the support plate 140. For example, the valve bridges 200a, 200b are removable through the respective valve bridge aperture 170, 195 without removing the support plate 140 from the cylinder head 65.
The cylinder head assembly 360 includes substantially the same cylinder head 65, intake valves 75, exhaust valves 85, valve springs 95, intake rocker arm 155, exhaust rocker arm 180, intake pushrod 165, exhaust pushrod 190, etc. as discussed above. However, a support plate 440 of the cylinder head assembly 360 includes cylindrical walls 610 extending from a top surface 450 of the plate 440 with each wall 610 surrounding one of an intake valve bridge aperture 470 and an exhaust valve bridge aperture 495. In this embodiment, the apertures 470, 495 are substantially circular apertures.
As shown in
During assembly of the cylinder head assembly 360, a first fixed post 400 is secured to the cylinder head 65 and the arm portion 510 of the first valve bridge 500a is received on the first fixed post 400 for the first fixed post 400 to extend through the recess 620 of the arm portion 510. Moreover, the arm portion 510 includes at least one non-circular surface 624 (two flat surfaces 624 are illustrated in
A similar process occurs to couple the arm portion 510 of second valve bridge 500b to a second fixed post 420 such that the arms 515, 520 of the second valve bridge 500b maintain engagement with the exhaust valves 85 and restricts movement of the arm portion 510 about a second longitudinal axis 430 of the second fixed post 420. In addition, the anti-rotation feature 530 and the ball-and-socket joint of the second valve bridge 500b allows the arm portion 510 to pivot about the point 622 on the second longitudinal axis 430 (similar to what is shown in
After the bridges 510 of the valve bridges 500a, 500b are installed onto their respective fixed posts 400, 420, the support plate 440 is secured to the cylinder head 65. The body 505 of the first valve bridge 500a is inserted into one of the cylindrical walls 610 to engage its arm portion 510, and the body 505 of the second valve bridge 500b is inserted into the other cylindrical wall 610 to engage its arm portion 510. In other embodiments, the body 505 of the first and second valve bridges 500a, 500b can be installed before the support plate 440 is secured to the cylinder head 65.
The intake rocker arm 155 is coupled to a first mounting protrusion 445 of the support plate 440 for the finger 265 of the intake rocker arm 155 to engage an end surface 514 of the first valve bridge 500a. Likewise, the exhaust rocker arm 180 is coupled to a second mounting protrusion 475 such that the finger 270 of the exhaust rocker arm 180 engages the end surface 514 of the second valve bridge 500b.
Operation of the engine 40 including the cylinder head assembly 360 is substantially the same as operation of the engine 40 including the cylinder head assembly 60. However, due to the ball-and-socket joint of the valve bridges 500a, 500b, the arm portion 510 of the valve bridges 500a, 500b can move in two degrees of freedom. First, the arm portion 510—in addition to the body 505—of each valve bridge 500a, 500b is axially moveable along the corresponding first and second longitudinal axis 415, 430. The axial movement is guided by the respective fixed posts 400, 420 being received within a cavity 512 of the corresponding valve bridge 500a, 500b, as well as, the body 505 of each valve bridge 500a, 500b received within the corresponding wall 610 of the support plate 440. As such, the walls 610 inhibit the pivoting movement of the rocker arms 155, 180 to be transferred to the valve bridges 500a, 500b. Second, the arm portion 510 can pivot relative to the body 505 of the valve bridges 500a, 500b via the ball-and-socket joint about the point 622 to account for different lengths of the intake and exhaust valves 75, 85 (e.g., due to manufacturing tolerances) and/or different spring rates of the valve springs 95. The pivoting movement of the arm portion 510 relative to the body 505 during installation and/or operation of the engine 40 seeks to provide actuation balance to the intake and exhaust valves 75, 85.
In addition, each wall 610 of the support plate 440 includes a notch or opening 625 sized to receive the finger 265, 270 of the corresponding intake and exhaust rocker arm 155, 180. As such, enough clearance between each wall 610 and the respective intake and exhaust rocker arms 155, 180 is provided for the intake and exhaust rocker arms 155, 180 to move the valves 75, 85 between the open and closed positions.
Furthermore, the first and second fixed posts 400, 420 supply portions of the cylinder head assembly 360 with lubricant from an oil gallery 438. Operation of such lubricant supply will be discussed in respect to the first fixed post 400 as shown in
Although the disclosure has been described in detail with reference to certain preferred embodiments, variations and modifications exist within the scope and spirit of one or more independent aspects of the disclosure as described. Various features and advantages of the disclosure are set forth in the following claims.
This application claims priority to U.S. Provisional Patent Application No. 62/633,259 filed on Feb. 21, 2018, the contents of which are incorporated herein by reference.
Number | Date | Country | |
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62633259 | Feb 2018 | US |