Patent Grant
8516984
The present invention relates generally to a system for actuating one or more engine valves in an internal combustion engine. In particular, the invention relates to systems and methods for controlling valve seating velocity.
Internal combustion engines typically use either a mechanical, electrical or hydro-mechanical valve actuation system to actuate the engine valves. These systems may include a combination of camshafts, rocker arms and push rods that are driven by the engine's crankshaft rotation. When a camshaft is used to actuate the engine valves, the timing of the valve actuation may be fixed by the size and location of the lobes on the camshaft.
Hydraulic lost motion valve actuation systems may be driven with a cam, particularly those used for an internal combustion engine. The hydraulic displacement of an engine valve in such a lost motion system is directly proportional to the displacement provided by the cam during normal operation. In some applications, however, the engine valve must be closed at an earlier time than that provided by the cam profile. This earlier closing may be carried out by rapidly releasing hydraulic fluid to an accumulator in the lost motion system or to the oil sump. In such instances engine valve seating control may be required because the rate of closing the valve is governed by the hydraulic flow to the accumulator or sump instead of by the fixed cam profile. Engine valve seating control may also be required for applications (e.g. centered lift) in which the engine valve seating occurs on a high velocity region of the cam. Still further, engine valve seating control may be required in common rail Variable Valve Actuation (VVA) designs, in which all seating events occur as a result of the release of hydraulic fluid, possibly to an accumulator.
An example of known systems and methods for controlling valve seating velocity are disclosed in U.S. Pat. No. 6,302,370 to Schwoerer et al., which is hereby incorporated by reference.
It is an advantage of some, but not necessarily all, embodiments of the present invention to provide methods and systems for seating an engine valve using hydraulically actuated components.
Responsive to the need for systems and methods for controlling valve seating velocity, Applicant has developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve comprising: a housing having a housing bore extending through the housing; a housing fluid passage extending through the housing and connecting with the housing bore; a master piston disposed in the housing bore, said master piston having a master piston bore extending into the master piston defined by a master piston side wall; one or more master piston fluid passages extending through the master piston side wall and connecting with the master piston bore, wherein the one or more master piston fluid passages are adapted to selectively register with the housing fluid passage; a slave piston disposed in a lower portion of the master piston bore; a valve catch piston disposed in an upper portion of the master piston bore, said valve catch piston having a hollow interior defined by a valve catch piston wall, a lower end orifice extending from the hollow interior through a lower end of the valve catch piston wall, one or more side passages extending through a side portion of the valve catch piston wall, and one or more seating passages extending through the valve catch piston wall, wherein the lower end orifice is located so as to be selectively occluded by the slave piston, the one or more side passages are located so that hydraulic fluid communication between the one or more side passages and the one or more master piston fluid passages is selectively occluded by the master piston side wall, and the one or more seating passages are located so as to remain in hydraulic communication with the one or more master piston fluid passages; and a valve catch spring disposed in the valve catch piston hollow interior.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 wherein the master piston bore includes an upper master piston bore in which the valve catch piston is disposed and a lower master piston bore in which the slave piston is disposed, and wherein a diameter of the lower piston master piston bore is greater than a diameter of the upper master piston bore.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 further comprising a slave piston spring disposed between the housing and the slave piston, said slave piston spring biasing the slave piston away from the housing.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 wherein the one or more seating passages extend from the valve catch piston hollow interior through the valve catch piston side wall.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 wherein at least one of the one or more seating passages extend from at least one of the one or more side passages through the lower end of the valve catch piston wall.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 wherein the one or more master piston fluid passages include a lower master piston fluid passage and an upper master piston fluid passage, and wherein the valve catch piston wall forms a valve catch piston shoulder adapted to occlude hydraulic fluid communication between the one or more side passages and the upper master piston fluid passage.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0011 wherein the one or more master piston fluid passages includes a mid master piston fluid passage disposed along the master piston side wall between the lower master piston fluid passage and the upper master piston fluid passage.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 further comprising a hydraulic fluid control valve in hydraulic communication with the housing fluid passage.
Applicant has further developed an innovative hydraulic lost motion system for actuating an internal combustion engine valve as set forth above in paragraph 0006 further comprising a hydraulic fluid accumulator in hydraulic communication with the hydraulic fluid valve.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only, and are not restrictive of the invention as claimed. The accompanying drawings, which are incorporated herein by reference, and which constitute a part of this specification, illustrate certain embodiments of the invention and, together with the detailed description, serve to explain the principles of the present invention.
In order to assist the understanding of this invention, reference will now be made to the appended drawings, in which like reference numerals refer to like elements. The drawings are exemplary only, and should not be construed as limiting the invention.
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings. With reference to
A rocker arm 130 may be pivotally mounted on a rocker shaft 140 adjacent to the engine valve 100. The rocker arm 130 may have a first end in contact with the upper end or stem of the engine valve 100 and a second end having an elephant foot assembly 150. The elephant foot assembly 150 may include a nut 152 which permits the position of the elephant foot assembly to be adjusted relative to the rocker arm 130. The elephant foot assembly 150 may permit the rocker arm 130 to receive linear motion from a hydraulic lost motion system 210 used to pivot the rocker arm.
The hydraulic lost motion system 210 may be slidably disposed in a lost motion system housing 200 and may have an end in contact with the elephant foot assembly 150. The end of the lost motion system 210 which is opposite from the end in contact with the elephant foot assembly 150 (i.e., the lower end in
The lost motion system 210 may be in hydraulic fluid communication with a hydraulic fluid valve 260, such as a high-speed trigger valve, via a housing fluid passage 202. If the hydraulic fluid valve 260 is a high-speed trigger valve, it may be capable of being opened and closed at least once per engine cycle. Hydraulic fluid may be provided to, and released from, the lost motion system 210 under the control of the hydraulic fluid valve 260. The fluid passage 202 may also be directly or indirectly in hydraulic fluid communication with a hydraulic fluid accumulator 262 in an alternative embodiment of the present invention. The accumulator 262 may be used to rapidly receive hydraulic fluid vented from the lost motion system 210 by the hydraulic fluid valve 260, as well as to rapidly refill the lost motion system 210 with hydraulic fluid under the control of the hydraulic fluid valve 260.
With reference to
A lost motion system 210 may be slidably disposed in a lost motion system housing 200 adjacent to and in contact with the upper end or stem of the engine valve 100. The lost motion system 210 may have an end (i.e., the upper end in
The rocker arm 130 may be pivotally mounted on a rocker shaft 140 adjacent to the lost motion system 210 so as to be able to impart linear motion to the lost motion system 210. The rocker arm 130 may have a cam roller 132 mounted on a second end of the rocker arm and in contact with a cam 170. The cam 170 may include one or more lobes or bumps 172 which impart motion to the rocker arm 130 and lost motion system 210. The bumps 172 may provide one or more intake valve actuations or one or more exhaust valve actuations, such as engine braking and exhaust gas recirculation motions, for example.
The lost motion system 210 may be in hydraulic fluid communication with a hydraulic fluid valve 260, such as a high-speed trigger valve, via a housing fluid passage 202. If the hydraulic fluid valve 260 is a high-speed trigger valve, it may be capable of being opened and closed at least once per engine cycle. Hydraulic fluid may be provided to, and released from, the lost motion system 210 under the control of the hydraulic fluid valve 260. The housing fluid passage 202 may also be directly or indirectly in hydraulic fluid communication with a hydraulic fluid accumulator 262 in an alternative embodiment of the present invention. The accumulator 262 may be used to rapidly receive hydraulic fluid vented from the lost motion system 210 by the hydraulic fluid valve 260, as well as to rapidly refill the lost motion system 210 with hydraulic fluid under the control of the hydraulic fluid valve 260.
With reference to
Reference will now be made to a first embodiment of the lost motion system 210, shown in
The master piston 220 may include one or more master piston fluid passages 222 extending from the tappet plenum 221 to the exterior of the master piston. The master piston fluid passages 222 may be located along the side wall of the master piston 220 so as to register with an annular recess 204 provided in the housing 200 as part of the housing fluid passage 202. The annular recess 204 may be sized so as to remain in hydraulic communication with the hydraulic fluid valve 260 and the one or more master piston fluid passages 222 throughout the stroke of the master piston 220.
A slave piston 230 may be slidably disposed in the tappet plenum 221. The slave piston 221 may biased by one or more springs 232 into a contact with a push tube 160 (as shown in
With continued reference to
The lost motion system 210 shown in
Once the hydraulic lost motion system 210 is charged with hydraulic fluid, the hydraulic fluid valve 260 may be closed so that the separation of the master piston 220 from the slave piston 230 is maintain due to the tappet plenum 221 being hydraulically sealed. Thereafter motion imparted from the cam 170 to the lost motion system may be transferred from the master piston 220 to the slave piston 230, and in turn to the engine valve 100. In order to terminate the actuation of the engine valve 100 before the time prescribed by the one or more bumps 172 on the cam 170, the hydraulic fluid valve 260 may be selectively opened. When the hydraulic fluid valve 260 is opened, hydraulic fluid may escape from the lost motion system 210 past the hydraulic fluid valve 260 to the low pressure fluid supply (not shown) and/or potentially to an accumulator 262.
When the hydraulic fluid valve 260 is opened, the engine valve springs 110 may push the engine valve 100 upward which in turn may cause the slave piston 230 to be pushed into the fluid in the tappet plenum 221. The fluid in the tappet plenum 221 may be displaced and flow out of the lost motion system 210 through the one or more master piston fluid passages 222 and the housing fluid passage 202. As the fluid vents through the housing fluid passage 202, the slave piston 230 may slide into the tappet plenum 221 relatively rapidly until it contacts the valve catch piston 240 at which time the slave piston upper surface may occlude the lower end orifice 246. As fluid continues to vent through the housing fluid passage 202, the valve catch piston 240 may be pushed upward into the valve catch plenum 223 against the bias force of the valve catch spring 242. As the valve catch piston 240 is pushed upwards fluid in the valve catch piston plenum 223 must vent through the one or more side passages 248 and the one or more seating passages 250. The rate at which the engine valve 100, the slave piston 230, and the valve piston 240 move upward (i.e., the engine valve seating velocity) may be decreased relative to the initial engine valve seating velocity because the valve catch plenum 223 must vent through the one or more side passages 248 and the one or more seating passages 250 in order for the valve catch piston 240 to move upward. As the valve catch piston continues to move upward, the engine valve seating velocity may be further reduced as the one or more side passages 248 are occluded by the master piston shoulder 228. The occlusion of the one or more side passages 248 may prevent fluid from escaping from the valve catch plenum 223 through the side passages, and may force any additional venting of fluid from the valve catch plenum 223 to occur through the one or more seating passages 250 which remain unblocked or un-occluded by the master piston shoulder 228 throughout the stroke of the valve catch piston 240. The seating passages 250 may be selectively sized to permit venting of the correct amount of fluid from the valve catch plenum 223 that will result in an acceptable valve seating velocity for the engine valve 100 across a range of expected hydraulic fluid operating conditions. Thereafter, the process may be repeated by refilling the valve catch plenum 223 and the tappet plenum 221 with hydraulic fluid.
With reference to
The lost motion system 210 shown in
With reference to
The master piston 220 may include one or more upper fluid passages 224, one or more mid fluid passages 225 and one or more lower fluid passages 226 extending from the tappet and valve catch plenums 221 and 223 to the exterior of the master piston. The upper, mid and lower fluid passages 224, 225 and 226 may be located along the side wall of the master piston 220 so as to register with an annular recess 204 provided in the housing 200 as part of the housing fluid passage 202. The annular recess 204 may be sized so as to remain in hydraulic communication with the hydraulic fluid valve 260 and the one or more upper, mid and lower fluid passages 224, 225 and 226 throughout the stroke of the master piston 220. At a minimum, the lower fluid passage 226 should be located so as to remain in hydraulic fluid communication with the annular recess 204.
The valve catch piston 240 in the lost motion system illustrated in
The lost motion system 210 shown in
It will be apparent to those skilled in the art that variations and modifications of the present invention can be made without departing from the scope or spirit of the invention. Thus, it is intended that the present invention cover all such modifications and variations of the invention, provided they come within the scope of the appended claims and their equivalents.
The present application relates to, and claims the priority of, U.S. Provisional Patent Application Ser. No. 61/232,296, filed Aug. 7, 2009, which is entitled “Lost Motion Variable Valve Actuation System With Valve Catch Piston.”
| Number | Name | Date | Kind |
|---|---|---|---|
| 4463714 | Nakamura | Aug 1984 | A |
| 4796573 | Wakeman et al. | Jan 1989 | A |
| 6302370 | Schwoerer et al. | Oct 2001 | B1 |
| 6769385 | Chang | Aug 2004 | B1 |
| 7464678 | Rozario et al. | Dec 2008 | B2 |
| 20050132986 | Chang | Jun 2005 | A1 |
| Number | Date | Country |
|---|---|---|
| 564507 | Oct 1944 | GB |
| 1063499 | Mar 1967 | GB |
| Entry |
|---|
| Hope A. Bolton and Jay M. Larson, Valvetrain System Design and Materials, “A Chronology of Hydraulic Lash Compensation in the United States” by W.A. Dammers (Eaton Corporation, Marshall, Michigan), International Symposium on Valvetrain System Design and Materials, Apr. 14-15, 1997, pp. 27-41, ASM International, Materials Park, Ohio, United States of America. |
| Number | Date | Country | |
|---|---|---|---|
| 20110067661 A1 | Mar 2011 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61232296 | Aug 2009 | US |
