Not Applicable.
The present disclosure relates generally to variable valve timing for internal combustion engines and, more specifically, to systems and methods for cam phasing control.
Internal combustion engines include a plurality of cylinders with pistons received therein that are connected to drive a crank shaft. Each cylinder has two or more valves that control the flow of air into the cylinder and the flow of exhaust gases out of the cylinder. The intake and exhaust valves can be actuated at different times during the engine cycle (e.g., during the intake and exhaust strokes, respectively) by a cam shaft, which is mechanically connected to be rotated by the crank shaft.
It has been recognized that optimum engine performance (e.g., engine efficiency and emissions) can be obtained if the valve timing varies, for example, as a function of engine speed, engine load, atmospheric pressure, and other factors. During engine operation, a cam phase actuator (cam phaser) can be used to alter a rotational relationship of the cam shaft relative to the crank shaft (i.e., cam phasing), which, in turn, alters when the intake and/or exhaust valves open and close.
Currently, cam phasers can be hydraulically actuated, electronically actuated, or mechanically actuated. For hydraulically actuated cam phasers, there are two operational modes for cam phasing, namely, cam torque actuation mode and oil pressure actuation mode. Cam torque actuation mode utilizes torque pulses imposed on the cam shaft to rotate the cam phaser. Oil pressure actuated mode uses oil pressure from the engine's pump to rotate the cam phaser.
The present disclosure provides systems and methods for cam phasing control. In particular, a cam phasing control system is disclosed that can be configured to control a first cam phase actuator and a second cam phase actuator, and selectively switch the operation thereof between a regenerative mode and an oil pressure actuation mode.
In one aspect, the present disclosure provides a cam phasing control system configured to be coupled to an internal combustion engine for controlling a flow of fluid to and from a cam phase actuator. The internal combustion engine includes a pump, a cam shaft, and a crank shaft. The cam phase actuator includes a first actuator port and a second actuator port. The cam phasing control system includes a manifold having a supply chamber, a first port chamber, a second port chamber, a regen chamber, and an outlet port. The cam phasing control system further includes at least one control valve having a solenoid and a spool moveable between a plurality of positions in response to activation of the solenoid. The spool is slidably received within the manifold. The cam phasing control system further includes at least one regen valve arranged within the manifold and in fluid communication with the regen chamber. The at least one regen valve is moveable between a first regen valve position where fluid communication is inhibited from the regen chamber through the outlet port and a second regen valve position where fluid communication is provided from the regen chamber through the outlet port. The at least one regen valve is moveable between the first position and the second position in response to a pressure in the supply chamber. When the at least one regen valve is in the first regen valve position, the cam phase actuator is operable in a regenerative mode, and when the at least one regen valve is in the second poppet position, the cam phase actuator is operable in an oil pressure actuated mode.
In another aspect, the present disclosure provides a filter plate for a cam phasing control system. The cam phasing control system includes a supply port, one or more workports, and one or more regen ports. The filter plate includes one or more check valves. One of the one or more check valves is arranged to enable fluid to flow through the supply port only in a desired direction. The filter plate further includes one or more filters. One of the one or more filters is arranged to filter fluid flowing from the supply port.
The foregoing and other aspects and advantages of the invention will appear from the following description. In the description, reference is made to the accompanying drawings which form a part hereof, and in which there is shown by way of illustration a preferred embodiment of the invention. Such embodiment does not necessarily represent the full scope of the invention, however, and reference is made therefore to the claims and herein for interpreting the scope of the invention.
The invention will be better understood and features, aspects and advantages other than those set forth above will become apparent when consideration is given to the following detailed description thereof. Such detailed description makes reference to the following drawings.
The components and design of the first side 122 of the cam phasing control system 100 can be similar to the components and design of the second side 124 of the cam phasing control system 100. As such, the following description of the components, design, and operation of the first side 122 of the cam phasing control system 100 also applies to the components, design, and operation of the second side 124 of the cam phasing control system 100. Similar features are identified using like reference numerals with the features on the first side 122 denoted using the suffix “a” and the features on the second side 124 denoted using the suffix “b.” That is, for each feature described using a reference numeral with the suffix “a,” the cam phasing control system 100 includes a corresponding symmetric feature arranged on the second side 124 labeled using the suffix “b.” It should also be appreciated that the first control valve 114 and the second control valve 116 can be similar in design and functionality and, thus, the following description of the first control valve 114 also applies to the second control valve 116. Additionally, the first regen valve 118 and the second regen valve 120 can be similar in design and functionality and, thus, the following description of the first regen valve 118 also applies to the second regen valve 120.
Turning to
When assembled, the filter plate 104 can be coupled between the end plate 102 and a front surface 148 of the manifold 106. The filter plate 104 can define a flat, thin plate that includes a plurality of check valve and filter features. In some non-limiting examples, the filter plate 104 can be fabricated from a metal material (e.g., stainless steel) or can be fabricated from a plastic material (e.g., nylon). As shown in
The filter plate 104 can include a supply check valve 164a, a first regen port check valve 166a, and a second regen port check valve 168a. Each of the illustrated supply check valve 164a, the first regen port check valve 166a, and the second regen port check valve 168a can be in the form of a reed valve hingidly attached to the filter plate 104. When the filter plate 104 is assembled between the front surface 148 of the manifold 106 and the end plate 102, the supply check valve 164a can be in engagement with the back surface 125. This can prevent the supply check valve 164a from hinging open in a direction toward the end plate 102, and only allow the supply check valve 164a to hinge open in a direction toward the manifold 106. In this way, the supply check valve 164a can allow fluid to flow only in a direction from the supply port 129a into the manifold 106. Similarly, the first regen port check valve 166a and the second regen port check valve 168a can engage the back surface 125 of the end plate 102, when assembled. Accordingly, the first regen port check valve 166a can allow fluid to flow only in a direction from the first regen port 136a into the manifold 106, and the second regen port check valve 168a can allow fluid to flow only in a direction from the second regen port 142a into the manifold 106.
Turing to
The manifold 106 can include a control valve mounting bore 188a, a regen valve mounting bore 190a, and a bracket mounting aperture 192a. The control valve mounting bore 188a can extend into the manifold 106 from a top side 194 to a location between the top side 194 and a bottom side 196. The control valve mounting bore 188a can extend through each of the first port chamber 172a and the second port chamber 174a. The control valve mounting bore 188a can also extend partially through the regen chamber 176a and into the supply chamber 170a. The regen valve mounting bore 190a can extend at least partially through the regen chamber 176a and into the supply chamber 170a. The regen valve mounting bore 190a can include an outlet port 198a. The illustrated outlet port 198a can define a generally U-shaped cutout in the regen valve mounting bore 190a adjacent to the top side 194 of the manifold. The generally U-shaped cutout defined by the outlet port 198a can enable fluid to flow through the outlet port 198a when the mounting bracket plate 112 is fastened on top of the regen valve mounting bore 190a, when the cam phasing control system is assembled. It should be appreciated that the shape (i.e., the generally U-shaped cutout) defined by the outlet port 198a is not meant to be limiting in any way and, in other non-limiting examples, the outlet port 198a may be designed to define any shape or profile, as desired.
Turning to
The spool 202a can be dimensioned to be received within the control valve mounting bore 188a. The spool 202a can define a generally annular shape with an internal bore 224a extending longitudinally therethrough such that fluid can flow into and through the internal bore 224a of the spool 202a. The spool 202a can include a first spool cutout 226a, a spool notch 228a, and a second spool cutout 230a. The first spool cutout 226a and the second spool cutout 230a can define annular radial recesses in the spool 202a. The first spool cutout 226a can be longitudinally, or axially, separated from the second spool cutout 230a with the spool notch 228a arranged therebetween. In operation, as will be described, the first spool cutout 226a can enable fluid to flow from the internal bore 224a into the second port chamber 174a, and the second spool cutout 230a can enable fluid to flow from the internal bore 224a into the first port chamber 172a. The spool notch 228a can define a radial recess on an outer surface 231a of the spool 202a. The spool 202a can be biased upwards in a direction toward the housing 200a by a spool spring 232a. The spool spring 232a can be arranged between a distal end 234a of the internal bore 224a and a spring retainer 236a.
Turning to
Assembly of the first side 122 of the cam phasing control system 100 will be described with reference to
Initially, the first control valve 114 can be assembled with the mounting bracket plate 112. The housing 200a of the first control valve 114 can be provided with the internal components (e.g., the solenoid 206a, armature tube 214a, armature 216a, pin 222a, etc.) arranged within the housing 200a. The pole piece 204a can be installed through a control valve aperture 252a of the mounting bracket plate 112. The housing 200a, with the internal components arranged therein, can then be coupled over the mounting bracket plate 112 and onto the pole piece 204a. The first regen valve 118, for example, in the form of the first poppet 237a of
The first control valve 114 with the mounting bracket plate 112 coupled thereto can be installed onto the manifold 106 such that the spool 202a is received within the control valve mounting bore 188a and a regen valve portion 256a of the mounting bracket plate 112 covers the regen valve mounting bore 190a. A fastening element (not shown) can be threaded through a bracket aperture 258a of the mounting bracket plate 112 and into the mounting aperture 192a in the manifold 106. Upon the fastening element (not shown) being threaded into the mounting aperture 192a, the first control valve 114 can be secured to the manifold 106 and the regen valve portion 256a of the mounting bracket plate 112 can compress the biasing element 246a thereby biasing the first regen valve 118 into a first regen valve position. In the first regen valve position, fluid communication can be inhibited between the regen chamber 176a and the outlet port 198a. As described above, the outlet port 198a can define a generally U-shaped profile, or another profile as desired. This can enable fluid to flow through the outlet port 198a with the regen valve portion 256a of the mounting bracket plate 112 secured onto the regen valve mounting bore 190a.
With the first control valve 114 and the first regen valve 118 secured within and coupled to the manifold 106, the end plate 102 can be fastened to the front surface 148 of the manifold with the filter plate 104 arranged therebetween to complete the assembly of the cam phasing control system 100. The assembled cam phasing control system 100 can be coupled, for example, to a cylinder head of an internal combustion engine (not shown) such that the first side 122 of the cam phasing control system 100 is in fluid communication with a first cam phase actuator and the second side 124 of the cam phasing control system 100 is in fluid communication with a second cam phase actuator. Thus, the cam phasing control system 100 described herein provides a bolt-on solution that enables the control of the cam phasing for two cam shafts on an internal combustion engine. The cam phasing control system 100 also significantly reduces the amount of components required to implement the control of two cam phase actuators. For example, the manifold 106 can replace the valve bodies that are included with current cam phase control valves, and a single connector 212 can be used to control both the first and second control valves 114 and 116. Additionally, the filter plate 104 can provide the functionality of what would require six separate filters and six separate check valves in a current cam phasing control system with a single component.
Operation of the cam phasing control system 100 will be described with reference to
In operation, the supply port 129a can be in fluid communication with a pump 262 of an internal combustion engine (not shown). The pump 262 can draw fluid (e.g., oil) from a reservoir 264 (e.g., a main oil gallery or oil pan of the internal combustion engine) and furnish the fluid under increased pressure to the supply port 129a. The first workport 134a can be in fluid communication with a first actuator port 266 of the cam phase actuator 260. The second workport 140a can be in fluid communication with a second actuator port 268 of the cam phase actuator. The outlet port 198a can be in fluid communication with the reservoir 264.
The illustrated spool 202a can be a 4-way, 3-position spool moveable between a first spool position 270, a second spool position 272, and a third spool position 274. In the first spool position 270, the cam phase actuator 260 can rotate the cam shaft in a first rotational direction relative to the crank shaft, which can either advance or retard the intake and exhaust valve events relative to the crank shaft. In the third spool position 274, the cam phase actuator 260 can rotate the cam shaft relative to the crank shaft in a second rotational direction opposite to the first rotational direction, which can perform the other of advancing or retarding the intake and exhaust valve events when compared to the first spool position 270. In the second spool position 272, the cam phase actuator 260 can maintain the rotational relationship between the cam shaft and the crank shaft.
The first regen valve 118 can control an operating mode of the cam phase actuator 260. That is, that first regen valve 118 can be moveable between a first regen valve position (
The pump 262 can supply fluid to the supply port 129a and the fluid supplied by the pump 262 can flow through the supply check valve 164a and into the pre-supply chamber 178a. Fluid communication can be provided from the pre-supply chamber 178a into the supply chamber 170a via the supply passageway 146a in the end plate 102. Fluid flowing from the supply passageway 146a into the supply chamber 170a can flow through the filter 158a in the second supply cutout 152a thereby filtering contaminants and/or particulates prior to entry into the supply chamber 170a.
The fluid in the supply chamber 170a, which is supplied by the pump 262, can apply a force to the first regen valve 118 in a direction towards the outlet port 198a. Simultaneously, the fluid in the supply chamber 170a can flow through the internal bore 224a of the spool 202a and into the second port chamber 174a. From the second port chamber 174a, the fluid can flow to the second workport 140a through the filter 162a and to the second actuator port 268 of the cam phase actuator 260. Thus, in the first spool position 270, pressurized fluid can flow from the pump 262 to the second actuator port 268. With pressurized fluid entering the second actuator port 268, fluid can flow from the first actuator port 266 towards the first workport 134a. Where the fluid flows once it reaches the first workport 134a depends on the fluid pressure in the supply chamber 170a supplied by the pump 262. That is, if the pump pressure supplied to the supply chamber 170a is below a regen pressure threshold (i.e., the pump pressure applies a force to the first regen valve 118 that is unable to overcome the opposing force applied by the biasing element 246a), the first regen valve 118 can remain in the first regen valve position (
With the first regen valve 118 in the first regen valve position (
If the pump pressure supplied to the supply chamber 170a is above a regen pressure threshold (i.e., the pump pressure applies a force on the first regen valve 118 in a direction towards the outlet port 198a that is sufficient to overcome the opposing force applied by the biasing element 246a), the first regen valve 118 can move to in the second regen position (
With the first regen valve 118 in the second regen valve position (
The operation of the first regen valve 118 can be similar when the spool 202a is actuated into the second spool position 272 and the third spool position 274. In the second spool position 272, the spool 202a can provide fluid communication between the pump 262 and both the first actuator port 266 and the second actuator port 268 to maintain a rotational relationship between the cam shaft and the crank shaft. The operation of the third spool position 274 can be opposite to the first spool position 270, described above, with the pump supplying fluid to the first actuator port 266, and the fluid from the second actuator port 268 either regenerating back to the first actuator port 266 or flowing to the reservoir 264.
It should be appreciated that alternative designs, arrangements, and configurations of the cam phasing control system 100 may be possible to achieve the operational aspects of the system, described above. That is, in some non-limiting examples, the cam phasing control system 100 may not include the end plate 102 and/or the filter plate 104. Instead, the functionality of the check valves and filters on the filter plate 104 may be integrated into the manifold 106 and/or accomplished external from the manifold 106 on a given application.
The cam phasing control system 100 described herein can provide a bolt-on solution that enables the control of the cam phasing for two cam shafts on an internal combustion engine. The cam phasing control system 100 can also significantly reduces the amount of components required to implement the control of two cam phase actuators.
Thus, while the invention has been described above in connection with particular embodiments and examples, the invention is not necessarily so limited, and that numerous other embodiments, examples, uses, modifications and departures from the embodiments, examples and uses are intended to be encompassed by the claims attached hereto. The entire disclosure of each patent and publication cited herein is incorporated by reference, as if each such patent or publication were individually incorporated by reference herein.
The present application is based on, claims priority to, and incorporates herein by reference in its entirety, U.S. Provisional Patent Application No. 62/378,314, filed on Aug. 23, 2016, and entitled “Systems and Methods for a Cam Phasing Control System.”
Number | Date | Country | |
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62378314 | Aug 2016 | US |