Example aspects described herein relate to lash compensators within a valve train of an internal combustion engine.
An internal combustion (IC) typically employs a valve train to convert rotary lift of a camshaft to linear lift of an engine poppet valve to enable a gas exchange process. Precise control of a valve lift event is required for consistent performance, emission control, and durability. To enable such precise control, clearances between valve train components must be maintained throughout the life of the engine. The summation of the clearances between valve train components is typically in the form of a resultant clearance or gap between the tip of the valve and the adjacent valve train component acting on the valve. This resultant clearance, often called “valve lash” must compensate for thermal growth of the valve and wear at each of its two interfaces over the life of the IC engine. Too high of a valve lash can result in unwanted wear, noise and undesirable performance of the engine, while too low of a valve lash can cause the valve to be inadvertently opened when it should be closed.
Valve lash can be mechanically adjusted, for example, by a threaded valve interface and jam nut combination arranged within the valve train component that actuates the valve. However, periodic valve lash adjustments throughout the life of the IC engine must be made to accommodate engine wear.
Many of today's valve trains employ a hydraulically controlled lash compensator that automatically adjusts to the dimensional and thermal variations of the valve train components to provide a zero valve lash condition throughout the life of the IC engine, eliminating the need for periodic valve lash adjustments. A component of the lash compensator is an axially displaceable piston configured with a control valve assembly that manages the exchange of hydraulic fluid between a high pressure chamber and a low pressure reservoir. Different configurations of the control valve assembly are possible. One such configuration is a reverse-spring design shown in
Referring to the reverse spring design of
A lash compensator for a valve train component of an internal combustion engine is provided that includes a central axis and an axially moveable piston assembly arranged within a bore of an outer housing. The piston assembly includes a piston and a control valve assembly. The piston has a first reservoir and an inner radial wall configured with a through-aperture. The control valve assembly has a control valve housing, a bias spring, an end-cap, and a closing body. The control valve housing is configured with at least one fluid port and provides axial guidance to the closing body. A first side of a retaining end of the control valve housing is engaged with a bottom surface of the piston. The bias spring, axially aligned with the through-aperture of the inner radial wall, has a first upper end engaged with the bottom surface of the piston. The end-cap is configured with a cupped end; an inner side of the cupped end receives a second lower end of the bias spring, and an outer side of the cupped end engages an upper portion of the closing body. The closing body can move from a first open position to a second closed position. The end-cap minimizes or eliminates the variation in fluid flow induced forces on the closing body caused by a variation in end-coil geometry of the second lower end of the bias spring. Multiple configurations of end-caps are possible, including, but not limited to embodiments that have a through-hole or piloting land arranged on the cupped end. Several manufacturing methods and corresponding materials can be utilized for the end-cap including stamped metal and injection molded plastic. The piston assembly can be a component within several different valve train components including, but not limited to, a pivot element, valve lifter, tappet, or rocker arm.
A return resilient element can be arranged within the lash compensator such that a third upper end is engaged with a second side of the retaining end of the control valve housing and a fourth lower end is engaged with a bottom surface of the bore of the outer housing. The bottom surface of the piston and the bottom surface of the bore define a high pressure chamber. With the closing body in the first open position, flow of hydraulic fluid between the first reservoir and high pressure chamber is permitted. With the closing body in the second closed position, flow of hydraulic fluid between the first reservoir and high pressure chamber is prevented. In the first open position, the closing body can engage a stop arranged on the control valve housing at an end opposite the retaining end, and in the second closed position, the closing body can engage a valve seat formed on the bottom surface of the piston. The bias spring can bias or forcibly act upon the closing body to the first open position; flow of hydraulic fluid around the closing body and through the through-aperture can generate a fluid force that overcomes the bias spring and moves the closing body to engage the valve seat.
The above mentioned and other features and advantages of the embodiments described herein, and the manner of attaining them, will become apparent and better understood by reference to the following descriptions of multiple example embodiments in conjunction with the accompanying drawings. A brief description of the drawings now follows.
Identically labeled elements appearing in different figures refer to the same elements but may not be referenced in the description for all figures. The exemplification set out herein illustrates at least one embodiment, in at least one form, and such exemplification is not to be construed as limiting the scope of the claims in any manner. Certain terminology is used in the following description for convenience only and is not limiting. The words “inner,” “outer,” “inwardly,” and “outwardly” refer to directions towards and away from the parts referenced in the drawings. Axially refers to directions along a diametric central axis. Radially refers to directions that are perpendicular to the central axis. The words “left”, “right”, “up”, “upward”, “down”, and “downward” designate directions in the drawings to which reference is made. The terminology includes the words specifically noted above, derivatives thereof, and words of similar import.
The RSCVA 30 includes a control valve housing 32, a closing body 42, the bias spring 34, and the end-cap 50A. The control valve housing 32, is configured with at least one fluid port 44 and a stop 40 for the closing body 42 arranged at an end opposite a retaining end 38. A first side 39 of the retaining end 38 of the control valve housing 32 is engaged with the bottom surface 41 of the piston 26. The closing body 42 opens and closes a hydraulic fluid passageway in the form of a through-aperture 27 that is arranged in an inner radial wall 33 of the piston 26. A first upper end 35 of the bias spring 34 is engaged with the bottom surface 41 of the piston 26, with the bias spring 34 axially aligned with the through-aperture 27. A second lower end 36 of the bias spring 34 is engaged with an inner side 54A of a cupped end 52A of the end-cap 50A. An outer side 56A of the cupped end 52A of the end-cap 50A is engaged with an upper portion 47 of the closing body 42. The bias spring 34 is arranged to bias the closing body 42 to a first open position with a spring force Fs; in other words, the bias spring 34 engages the closing body 42 and provides a spring force Fs such that the closing body 42 is forcibly engaged with the stop 40 of the control valve housing 32 in a first open position. Those skilled in the art of lash compensators would understand that other forms of the stop 40 are also possible. As the plunger 22 receives a valve train force Fvt that causes it and the piston assembly 24 to move axially downward within the bore 21 of the outer housing 20, hydraulic fluid 43 flows into the at least one fluid port 44 of the control valve housing 32. The hydraulic fluid 43 then flows around and past the closing body 42; through a controlled flow crevice CFC formed between the closing body 42, a valve seat 28, and the end-cap 50A; and, out through the through-aperture 27 into the first reservoir 46. As the plunger 22 receives the valve train force Fvt, with the closing body 42 in the first open position, hydraulic fluid 43 flows from the high pressure chamber 31 to the first reservoir 46 and the plunger 22 and piston 26 descend axially downward within the bore 21 of the outer housing 20. If an axial downward velocity of the plunger 22 and piston 26 is achieved that produces a fluid force Ff greater than the spring force Fs provided by the bias spring 34, the closing body will ascend upward until the closing body 42 engages the valve seat 28, achieving a second closed position. In the second closed position, the magnitude of axial descent of the plunger 22 and piston assembly 24 is a function of a clearance between an outer diameter of the piston 26 and a diameter of the bore 21 of the outer housing 20.
The return resilient element or spring 29 is disposed within the high pressure chamber 31 of the pivot element 10. A third upper end 16 of the return spring 29 is engaged with a second side 45 of the retaining end 38 of the control valve housing 32 and a fourth lower end 18 of the return spring 29 is engaged with the bottom surface 23 of the bore 21. In the absence of the valve train force Fvt, the return spring 29 urges the piston assembly 24 and plunger 22 upward to engage a rocker arm (not shown) in order to maintain a zero-lash condition of the valve train.
The end-cap 50A provides encapsulation of the second lower end 36 of the bias spring 34 which provides a consistent flow path resistance and impingement surface in the area of the controlled flow crevice CFC between the closing body 42 and the valve seat 28. This consistent flow path resistance yields a consistent hydraulic fluid force Ff acting on the closing body 42 for a given fluid velocity. Such a consistent hydraulic fluid force Ff not only reduces or eliminates any variation in engine valve lift within an engine, but also eliminates engine-to-engine variation of valve lift amongst a large population of manufactured lash compensators.
Referring to
In the foregoing description, example embodiments are described. The specification and drawings are accordingly to be regarded in an illustrative rather than in a restrictive sense. It will, however, be evident that various modifications and changes may be made thereto, without departing from the broader spirit and scope of the present invention.
In addition, it should be understood that the figures illustrated in the attachments, which highlight the functionality and advantages of the example embodiments, are presented for example purposes only. The architecture or construction of example embodiments described herein is sufficiently flexible and configurable, such that it may be utilized (and navigated) in ways other than that shown in the accompanying figures.
Although example embodiments have been described herein, many additional modifications and variations would be apparent to those skilled in the art. It is therefore to be understood that this invention may be practiced otherwise than as specifically described. Thus, the present example embodiments should be considered in all respects as illustrative and not restrictive.
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Number | Date | Country | |
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20180195420 A1 | Jul 2018 | US |