The invention relates to an oil control valve assembly operatively connected to a drip rail in an engine.
Hydraulic control systems for engines are used to control oil under pressure that may be used to switch latch pins in switching lifters, lash adjusters, and rocker arms for cam switching. Valve lifters are engine components that control the opening and closing of exhaust and intake valves in an engine. Rocker arms are used to change the lift profile of camshafts. Lash adjusters may also be used to deactivate or vary exhaust and intake valves in an engine. By varying valve lift, fuel efficiency of an engine may be improved. Camshafts and other rotating, sliding or otherwise movable components within the engine require lubrication. In some engines, fluid is pumped to a drip rail positioned above the components to provide the necessary lubrication.
An oil control valve assembly for an engine is provided that has a control valve with a valve body which defines both a control passage in fluid communication with a valve lift switching component, such as a switching rocker arm or switching lash adjuster, and an exhaust passage for exhausting fluid from the valve. The control valve is controllable to selectively direct fluid from a supply source to the control passage to actuate the valve lift switching component. An elongated tubular member, such as a drip rail, is positioned adjacent the engine component and is operatively connected to the exhaust passage such that fluid flows from the exhaust passage to the elongated tubular member and through the elongated tubular member onto the engine component. In this manner, oil flow need not be separately directed to the elongated tubular member from the supply source. Oil flow requirements are reduced, thus saving energy.
The oil control valve assembly includes a pressure relief valve in fluid communication with the exhaust passage that is configured to open when pressure in the exhaust passage reaches a predetermined pressure that is less than a minimum pressure required to actuate the valve lift switching component. The pressure relief valve thus helps to maintain a residual pressure to the valve lift switching component. This prevents air from entering the passages or reaching the valve lift switching components, which would disrupt actuation timing. Maintaining a residual pressure also decreases the time required to raise the pressure level to the minimum pressure required for actuation, thus decreasing actuation response time. The pressure relief valve may be between the exhaust passage and the elongated tubular member, in which case, fluid drips from the elongated tubular member by gravity only. Alternatively, the elongated tubular member may be between the exhaust passage and the pressure relief valve such that fluid within the elongated tubular member is pressurized up to the predetermined pressure at which the relief valve opens. A pressurized elongated tubular member ensures lubrication of the engine components even at low temperatures. Other means of dispensing pressurized oil to lubricate the engine components, such as through squirters in the rocker arms are unnecessary.
A feed passage is in fluid communication with the supply source and also with an engine cam phaser, causing fluid pressure in the feed passage to vary. A pressure regulator valve is configured to regulate fluid pressure provided to the supply passage and the bypass passage through the feed passage. Supply pressure is thus stabilized, making response times more consistent over a variety of temperature and pressure fluctuations in the fluid provided from the supply source. For example, interference caused by fluid demand of other hydraulic valves and components is reduced. Because the maximum pressure is controlled, the apertures in the elongated tubular member can be larger. This is especially beneficial if fluid in the elongated tubular member is not pressurized, as adequate fluid flow through the apertures at low temperatures requires sufficiently large apertures.
The above features and advantages and other features and advantages of the present invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.
Referring to the drawings, wherein like reference numbers refer to like components throughout the several views,
The hydraulic control system 12 shown in
The engine 10 has an oil sump 30 containing hydraulic fluid, also referred to herein as oil, that is pressurized and directed through a feed passage 32 by a pump 34. Some of the oil in the feed passage 32 is used by cam phaser valves 36 that adjust and retard cam timing based on factors such as engine speed and load. Because the cam phasers 36 intermittently draw fluid from the feed passage 32, pressure in the feed passage 32 varies. In order to regulate fluid pressure flowing to the oil control valves 20 and avoid extreme fluctuations, the pressure regulator valve 26 moderates pressure supplied from the feed passage 32 through the regulator valve 26 to supply passage 40, which feeds into both of the control valves 20. The pressure regulator valve 26 is shown and described in further detail with respect to
Flow through the bypass passage 42 must pass through a restriction 44 (also referred to as a first orifice) dropping the pressure and limiting flow. This, in combination with the regulated pressure, causes a consistent flow rate to the drip rail 22. In the embodiment shown, which is described further with respect to
The oil control valve 20 also has a control passage 46 in fluid communication with the rocker arm 14 and lash adjuster 16. In
In
An armature 62 and the valve member 48 connected thereto are movable in the armature chamber 58 in response to energizing of the coil 50. A flux collector 64 (also referred to as a flux bracket) is supported adjacent the coil 50 and armature 62 by a valve body 66 of the manifold 56. Electrical wiring for energizing of the coil 50 may be connected with the coil 50 through wiring openings or through an electrical connector mounted to the coil cover 53, as is known.
The pole piece 60, can 53, coil 50, armature 62 and flux collector 64 form an electromagnet. Lines of flux are created in an air gap between the pole piece 60 and the armature 48 when the coil 50 is energized by an electric source (such as a battery, not shown). The armature 62 moves in response to the flux. The coil 50 is energized under the control of an electronic controller (not shown) in response to various engine operating conditions, as is known. The armature 62 and valve member 48 are shown in a position in which the coil 50 is not energized, as is
The pressure relief valve 28 is shown installed within the manifold 56, upstream of the drip rail 22. The pressure relief valve 28 is shown closed, but will open when spring-biased ball 72 moves away from valve seat 74 at a sufficient fluid pressure in the exhaust passage 18 that is still lower than the pressure required to actuate the rocker arm 14 and lash adjuster 16. When the pressure relief valve 28 opens, fluid is supplied to drip rail 22. Drip rail 22 is connected to the manifold 56 with a connector 75 press-fit or otherwise secured within the exhaust passage 18. Fluid in the drip rail 22 will gradually drain onto engine components 80 through apertures 82 in the drip rail 22 at a rate dependent on the fluid pressure within the drip rail 22 and the size of the apertures 82. The apertures 82 are spaced according to the positions of the engine components 80, which may be cam bearings, gears, or any engine components that benefit from consistent lubrication.
The drip rail 22 is non-linear with S-shaped curves. This shape helps to keep fluid draining through the apertures 82 from spreading along the outside of the drip rail 22, and instead positions the apertures 82 at low points on the drip rail 22 to encourage fluid to drip onto the engine components 80. Preferably the drip rail 22 is located above the engine components 80. However, depending on the operating fluid pressure within the drip rail 22, fluid could dispense sideways onto engine components 80, allowing the drip rail 22 to be positioned laterally alongside the engine components 80. The drip rail 22 is upturned at a terminal portion 84. If fluid fills the drip rail 22 and rises in the terminal portion 84, it forms a fluid head that helps to maintain pressure in the drip rail 22. The fluid will spill over the open end of the terminal portion of the drip rail 22 into the engine 10 if pressure in the drip rail 22 exceeds a certain level.
While the valve member 48 is in the position shown in
Referring to
The valve member 85 is biased by spring 89 toward the open plug 83. One end of the spring 89 is held by open plug 91. When the spring 89 is in an extended position, the chamber 58A is fully open to the feed passage 32. A stationary cap 95 attached to base portion 66A limits movement of the valve member 85 toward the open plug 83. Any fluid that passes around the valve member 85 will be exhausted to the sump 30 of
While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will recognize various alternative designs and embodiments for practicing the invention within the scope of the appended claims.
This application is a continuation application of U.S. application Ser. No. 12/692,865, filed Jan. 25, 2010, which claims the benefit of U.S. Provisional Application No. 61/147,543, filed Jan. 27, 2009, both of which are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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Parent | 12692865 | Jan 2010 | US |
Child | 13603936 | US |