This invention relates generally to actuators and corresponding methods and systems for controlling such actuators, and in particular, to actuators offering efficient, fast, flexible control with large opening forces.
A split four-stroke cycle internal combustion engine is described in U.S. Pat. No. 6,543,225. It includes at least one power piston and a corresponding first or power cylinder, and at least one compression piston and a corresponding second or compression cylinder. The power piston reciprocates through a power stroke and an exhaust stroke of a four-stroke cycle, while the compression piston reciprocates through an intake stroke and a compression stroke. A pressure chamber or cross-over passage interconnects the compression and power cylinders, with an inlet check valve providing substantially one-way gas flow from the compression cylinder to the cross-over passage, and an outlet or cross-over valve providing gas flow communication between the cross-over passage and the power cylinder. The engine further includes an intake and an exhaust valve on the compression and power cylinders, respectively. The split-cycle engine according to the referenced patent and other related developments potentially offers many advantages in fuel efficiency, especially when integrated with an additional air storage tank interconnected with the cross-over passage, which makes it possible to operate the engine as an air hybrid engine. Relative to an electrical hybrid engine, an air hybrid engine can potentially offer as much, if not more, fuel economy benefits at much lower manufacturing and waste disposal costs.
To achieve the potential benefits, the air or air-fuel mixture in the cross-over passage has to be maintained at a predetermined firing condition pressure, e.g. approximately 270 psi or 18.6 bar gage-pressure, for the entire four stroke cycle. The pressure may go much higher to achieve better combustion efficiency. Also, the opening window of the cross-over valve has to be extremely narrow, especially at medium and high engine speeds. The cross-over valve opens when the power piston is at or near the top dead center (TDC) and closes shortly after that. The total opening window in a split cycle engine may be as short as one to two milliseconds, compared with a minimum period of six to eight milliseconds in a conventional engine. To seal against a persistently high pressure in the cross-over passage, a practical cross-over valve is most likely a poppet or disk valve with an outward (i.e. away from the power cylinder, instead of into it) opening motion. When closed, the valve disk or head is pressured against the valve seat under the cross-over passage pressure. To open the valve, an actuator has to provide an extremely large initial opening force to overcome the pressure force on the head as well as the inertia. The pressure force drops dramatically once the cross-over valve is open because of a substantial pressure-equalization between the cross-over passage and the power cylinder. Once the combustion is initiated, the valve should be closed as soon as desired to prevent the spread of the combustion into the cross-over passage, which also entails, during a certain period of combustion, a need to keep the valve seated against a power cylinder pressure that is higher than the cross-over passage pressure. In addition, the cross-over valve needs to be deactivated when the power stroke is not active in certain phases of the air hybrid operation. Like conventional engine valves, the seating velocity of the cross-over valve has to be kept under a certain limit to reduce noise and maintain adequate durability.
In summary, a cross-over valve actuator has to offer a large initial opening force, a substantial seating force, a reasonably low seating velocity, a high actuation speed, and timing flexibility while consuming minimum energy by itself. Most, if not all, conventional engine valve actuation systems are not able to meet these demands.
Briefly stated, in one aspect of the invention, one preferred embodiment of an actuator includes a driver further including a housing defining a longitudinal axis and first and second directions, an actuation mechanism capable of generating actuation force at least in the first direction, and a rod with one end operably connected with at least one part of the actuation mechanism and with the other end available for an operable connection with a load such as an engine valve; at least one return spring operably connected with the rod through a spring retainer assembly and biasing the rod in the second direction; and a pneumatic booster further including a pneumatic cylinder, a pneumatic piston operably connected with the rod through the spring retainer assembly and biasing the rod in the first direction, a charge mechanism providing a controlled fluid communication between the pneumatic cylinder and a high-pressure gas source, and a bleed mechanism providing a controlled fluid communication between the pneumatic cylinder to a low-pressure gas sink.
In operation, the actuator holds the load to a second-direction end position with the force from the at-least-one return spring biasing in the second direction and overcoming the sum of the rest of the forces including those from the pneumatic booster and the load, without generating the actuation force in the first direction from the actuation mechanism, and with the pneumatic booster being charged through the charge mechanism to yield a substantial force in the first direction to oppose a substantial load force in the second direction.
The actuator initiates the travel of the load in the first direction by generating the actuation force in the first direction from the actuation mechanism, with the combination of the actuation force and the force from the pneumatic booster being able to overcome the sum of the rest of the forces including those from the at-least-one return spring and the load and accelerate the load in the first direction.
The actuator keeps the travel in the first direction with the actuation force in the first direction until reaching the target stroke, and keeping the actuation force in the first direction if the load needs to be held at the target stroke. The actuator initiates the return travel of the load in the second direction at least by turning off the actuation force in the first direction so that the load is accelerated in the second direction at least by the return spring.
The actuator bleeds off excess air in the booster cylinder through the bleed mechanism during at least part of the time period described in the above paragraph to reduce the force from the pneumatic booster, which is otherwise too excessively resistant to the return travel of the load. It completes the return travel with a decreasing force from the return spring and an increasing force from the pneumatic booster, which help slow down the load.
In another embodiment, the driver is a fluid driver; the actuation mechanism comprising an actuation piston, an actuation cylinder, first and second fluid spaces in fluid communication with first and second ports, respectively; and the rod being a piston rod operably connected with the actuation piston and the load.
In another embodiment, the driver is an electromagnetic driver; the actuation mechanism comprising an armature disposed in an armature chamber, and at least a first electromagnet on the first direction side of the armature chamber, whereby being able to pull the armature in the first direction when energized; and the rod being an armature rod operably connected with the armature and the load.
In another embodiment, the charge mechanism includes a charge orifice, whereby substantially restricting the charge flow rate. It may also includes a control mechanism that substantially closes off charge flow at least when the bleed mechanism is actively bleeding off excess air.
The present invention provides significant advantages over the prevailing fluid actuators and their control, especially those needed for the cross-over passage engine valve that needs a large initial opening force, a substantial seating force, a reasonably low seating velocity, a high actuation speed, and timing flexibility while consuming minimum energy by itself. The pneumatic booster is able to provide that large initial force, without adding too much construction complexity or demanding too much energy consumption or stretching the capacity and functional limits of the fluid or electromagnetic actuators, by tapping directly into the cross-over passage or the air storage tank. With the charge mechanism, the boost force can be directly adjusted to the varying operating pressure in the cross-over passage, without sophisticated active control. With the bleed mechanism, the engine valve return force can be greatly reduced by making the boost force to be substantially lower during the return stroke.
With the pneumatic booster, the driver, be it a fluid or electromagnetic one, is able to concentrate on more or less conventional valve actuation, without the design, function and cost burden associated with the large initial opening force, which conventionally entails large flow rate and package size for fluid drivers and high, if not impossible, magnetic force and electrical power for electromagnetic drivers.
The present invention, together with further objects and advantages, will be best understood by reference to the following detailed description taken in conjunction with the accompanying drawings.
Referring now to
The actuation 3-way valve 90 supplies the fluid driver 30 through a second port 62 of the fluid driver 30. The 3-way valve 90 has two of its three ways connected with a low-pressure P_L fluid line and a high-pressure P_H fluid line, and the third way connected with the second port 62. A first port 60 of the fluid driver 30 is in fluid communication directly with the low-pressure P_L fluid line.
The actuation 3-way valve 90 is switched either to a left position 92 or a right position 94. At the left and right positions 92 and 94, the second port 62 is in fluid communication with the P_H and P_L lines, respectively.
The pressure P_H can be either constant or continuously variable. When variable, it is to accommodate variability in system friction, engine valve opening, air pressure, the engine valve seating velocity requirement, etc., and/or to save operating energy when possible. The pressure P_L can be simply the fluid tank pressure, the atmosphere pressure, or a fluid system backup pressure. The fluid system backup pressure can be simply supported or controlled, for example, by a spring-loaded check valve, with or without an accumulator. The P_L value is preferred to be as low as possible to increase the system efficiency, and yet high enough to help prevent fluid cavitation. When necessary, The P_L can be more tightly controlled as well. When necessary and/or allowed, the two P_L lines connected with the two ports 60 and 62 may maintain two pressure values. For example, the first port 60 may be simply used to dump some leakage flow to the fluid tank (not shown in
The engine valve 20 includes an engine valve head 22 and an engine valve stem 24. The engine-valve head 22 includes a first surface 28 and a second surface 29, which in the case of a split-cycle engine, are exposed to a cross-over passage 110 and the engine cylinder 102, respectively. The engine valve 20 is operably connected with the fluid driver 30 along a longitudinal axis 116 through the engine valve stem 24, which is slideably disposed in an engine valve guide 120. For ease of description, the assembly and the longitudinal axis 116 have first and second directions, which are the same as the top and bottom directions in
When the engine valve 20 is fully closed, the engine valve head 22 is in contact with an engine valve seat 26, sealing off the fluid communication between the cross-over passage 110 and the engine cylinder 102.
The fluid driver 30 comprises an actuator housing 70, an actuation piston 40, and an actuation cylinder 50. The actuation piston 40 is slideably disposed in the actuation cylinder 50. The actuation piston 40 is fixed on to a piston rod 46 between a fastening element 45 and a shoulder 49. The actuation piston 40 includes a first surface 42 and a second surface 44, and longitudinally divides the actuation cylinder 50 into a first fluid space 52 (between an actuation-cylinder first end 56 and an actuation-piston first surface 42) and a second fluid space 54 (between the actuation-piston second surface 44 and the actuation-cylinder second end 58). The radial clearances around the actuation piston 40 and the piston rod 46 are substantially tight, provide substantial fluid seal, and yet offer tolerable resistance to relative motions.
The second fluid space 54 is in fluid communication with the second port 62 through a second flow passage 64 around a neck feature 48 on the piston rod. The second flow passage 64 becomes substantially more restrictive when the actuation piston 40 is close to the actuation-cylinder second end 58, with the shoulder 49 longitudinally approaching and/or overlapping the second flow passage 64. If a second flow mechanism is defined to include the second flow passage 64, the neck 48, and the shoulder 49, then the second flow mechanism provides substantially open fluid communication between the second fluid space and the second port. It provides a snubbing function when the actuation piston 40 is close to the actuation-cylinder second end 58. When desired, the second flow mechanism may also include a one-way or check valve (not shown in
The first fluid space 52 is in fluid communication with the first port 60 without much flow restriction.
The piston rod 46 is operably connected with the engine valve stem 24, and in this embodiment (as illustrated in
A spring retainer assembly 74 is designed to help hold the return spring 72 and transfer its force on to the engine valve stem 24. The return spring 72 as illustrated in
The spring retainer assembly 74 includes a first and second spring retainers 78 and 80 and a set of valve keepers 76. The first spring retainer 78 also functions or doubles as a pneumatic piston, which is slideably disposed inside a pneumatic cylinder 84, a cavity at the top of the engine valve guide 120, to form the pneumatic booster 85. The side, sliding walls of the first spring retainer 78 and the pneumatic cylinder 84 maintain an air-tight seal and yet reasonable level of friction with necessary lubrication and sealing mechanism (details not in
The pneumatic cylinder 84 is charged or supplied with the pressurized gas or air from the cross-over passage 110, a high-pressure gas source, through a charge mechanism including a charge passage 112 and a charge orifice 86. The charge orifice 86 is designed to be more restrictive than the charge passage 112. The passage 112 and orifice 86 may be combined into a single restrictive long orifice (not shown in
The actuation cylinder 50 offers substantial room longitudinally such that the actuation piston 40 does not touch the first and second ends 56 and 58 of the cylinder 50 when the load or engine valve 20 is at its first-direction and second-direction end positions, respectively. When the engine valve 20 is seated or at its second-direction end position as shown in
Alternatively, one may design for the engine valve opening travel to be limited or defined by the physical contact between the actuation-piston first surface 42 and the actuation cylinder first end 56, or between their equivalent surfaces, with necessary snubbing or control measures, like those shown later in
The engine valve head 22 is generally exposed to the pressure of the cross-over passage 110 on the first surface 28 and the pressure of the engine cylinder 102 on the second surface 29.
The cross-section area of the first spring retainer or the pneumatic piston 78 is to be substantially equal to that of the engine-valve head so that the pneumatic pressure force on the pneumatic piston 78 substantially cancels the pressure force on the engine-valve first surface 28 when the pressure in the pneumatic cylinder 84 is substantially equal to that in the cross-over passage, due to fluid communication through the charge orifice 86. Alternatively, the cross-section area of the pneumatic piston 78 is to be appreciably, but not necessarily substantially, different from, either larger or smaller than, that of the engine valve head 22. A larger pneumatic piston cross-section area, for example, offers an extra engine valve opening force so that a relatively more compact fluid driver 30 is sufficient.
The system also experiences various friction forces, steady-state flow forces, transient flow forces, and other inertia forces. Steady-state flow forces are caused by the hydrostatic pressure redistribution due to flow-induced velocity variation, i.e. the Bernoulli effect. Transient flow forces are fluid inertial forces. Other inertial forces result from the acceleration of objects, excluding fluid here, with inertia, and they are substantial in an engine valve assembly because of the large magnitude of the acceleration or the fast timing.
At power-off state, all fluid supply sources P_H and P_L are at low or zero gage pressure. The total fluid force on the actuation piston 40 is substantially equal to zero. The engine valve can be seated or closed by the return spring 72 alone. The seating is even more secure if the pneumatic piston 78 has a smaller diameter than the engine valve head 22, and the cross-over passage 110 is still sufficiently pressurized, especially for an air-hybrid application with an air storage tank.
At the power-off, the default position of the actuation 3-way valve 90 is preferably, but not necessarily, to be in its right position 94 as shown in
To start-up the system from the power-off state, all fluid supply sources are pressurized, and the actuation 3-way valve 90 is secured, either by default or active control, at its right position 94 as shown in
To open the engine valve 20, the actuation 3-way valve 90 is switched to its left position 92. The second fluid space 54 is open to the high pressure P_H supply through the second flow mechanism, while the first fluid space 52 remains to be exposed to the low pressure P_L supply. The resulting differential pressure force on the actuation piston 40 is in the first direction (or upward in
As soon as the engine valve 20 cracks open, the engine cylinder 102 is filled rapidly, and its pressure reaches the cross-over passage pressure within a short period of time, well before the engine valve 20 passes the middle point of the opening stroke, resulting in a rapid disappearance of the differential pressure on the engine valve surfaces 28 and 29. During the same short period of time, the pressure in the pneumatic cylinder 84 and the differential pressure on the pneumatic piston 78 drop rapidly as well because of its limited, predefined initial volume, its rapid volume expansion associated with the engine valve movement, a limited amount of air inflow through the charge orifice 86, and the bleeding off of the air as the pneumatic piston 78 moves up a predefined distance L1, as shown in
For the rest of the opening stroke or beyond the distance L1, the air pressure forces on the pneumatic piston 78 and the engine valve 20 are minimum, and the actuation piston 40 continues to drive the engine valve 20 in the first direction (or upward in
The engine valve 20 remains open as long as the actuation 3-way valve 90 remains at its left position 92. During this period, the pneumatic cylinder 84 keeps receiving a small stream of air flow from the charge orifice 86 and keeps bleeding the air out through the substantial gap between the pneumatic piston 78 and its top, expanded cylinder wall 118. This energy loss will continue until the pneumatic piston 78 is back at the lower portion of the pneumatic cylinder 84. However, the energy loss is minimized by the restrictive nature of the charge orifice 86 and the limited engine valve opening period relative to the entire thermal cycle.
To start closing the engine valve, the actuation 3-way valve 90 is switched to its right position 94, and the second fluid space 54 is open back to the low pressure P_L fluid supply, resulting in a substantially zero pressure differential across the actuation piston 40. The return spring 72 is able to drive the engine valve 20 downward. When the pneumatic piston 78 passes the expanded part 118 of the pneumatic cylinder 84, a substantially air-tight seal is established again between the pneumatic piston 18 and the wall of the pneumatic cylinder 84, and the pressure in the pneumatic cylinder starts building up primarily because of a shrinking cylinder volume as the engine valve 20 and thus the pneumatic piston 18 move downward. The pressure build-up is also assisted by the flow from the charge orifice 86. The pneumatic cylinder 84 functions like a pneumatic spring, slowing down the advancement of the engine valve 20 and eventually helping achieve a soft-seating when the engine valve 20 reaches the engine-valve seat 26.
Around the engine valve seating or landing and shortly after that, the pressure in the engine cylinder momentarily exceeds the cross-over passage pressure because of the effect of the combustion, resulting in a transient differential pressure force in the first direction or upward. The preload of the return spring 72 should be designed to be able to hold the engine valve 20 in seated position against this transient upward differential force on the engine valve and also against the pressure force from the pneumatic cylinder 84. The pneumatic cylinder pressure, at this moment, is however not equal to the full cross-over pressure. It is purposely so by earlier bleeding off through the expanded portion 118 of the pneumatic cylinder 84 and the restrictive nature of the charge orifice 86.
Thereafter, the engine cylinder pressure drops below the cross-over passage pressure as the volume expands further. The pneumatic cylinder pressure rises up further through the restricted flow from the charge orifice 86 during the rest of the engine thermal cycle, which is slow but sure enough to be ready for the next engine valve opening event.
Similarly, the second flow mechanism, which is the means of fluid communication between the second port 62 and the second fluid space 58, includes a second undercut 34 and at least one second snubbing groove 35. When the actuation-piston second surface 44 passes the second undercut 34 longitudinally in the second direction during an closing stroke, the working fluid is substantially trapped in the second fluid space 58, with only a limited outlet through the at-least-one second snubbing groove 35, resulting in a snubbing action to help slow down the travel speed and achieve soft-seating for the engine valve 20. It is desired to leave a predefined longitudinal distance between the actuation-cylinder second end and the actuation-piston second surface 44 to ensure a solid contact and tight seal between the engine valve head 22 and the valve seat 26 when the engine valve 20 is seated, which has to be accommodated at all engine operating conditions and throughout the engine's service life. When necessary, additional engine valve lash adjustment device (not shown in
The embodiment in
This embodiment also shows variations in the charging and bleeding mechanisms for the pneumatic booster 85. It adopts at least one bleed hole 87 as the bleed passage, instead of an expanded wall 118 in
One can also use some predefined variation (not shown in
The charge orifice 86b in
Refer now to
This embodiment further features a charge valve 108, as a control mechanism, along the charge passage 112 to help achieve better control over the charging process for the pneumatic cylinder 84. The charge valve 108 has at least one of two major functions: (1) to open the charge passage 112, allowing the pneumatic cylinder 84 to be charged, before the engine valve opening stroke, and close the charge passage 112 especially if the restrictive charge orifice 86 is not used, eliminating or reducing leak flow when the pneumatic cylinder 84 is being bled; (2) to completely close off the charge passage 112 when the engine or that particular engine cylinder is power-off, as in an air hybrid vehicle, minimizing leakage and preserving the pressurized air in the cross-over passage and/or the air storage tank. For the first function, one charge valve 108 is needed for each power cylinder of the split four-stroke cycle engine because each power cylinder has its unique timing. If only the second function is needed, one may optionally use only one charge valve 108 for an entire engine, with the valve 108 controlling a common charge passage (not shown in
At this and other figures, the charge passage 112 is connected to the cross-over passage 110. Optionally, it can be connected to the air storage tank (in the case of an air hybrid vehicle) or a separate reservoir (not shown in the figures). The separate reservoir may have its own pressure, which may be regulated to help achieve optimum charging process for the pneumatic cylinder 84.
Refer now to
Still another variation or option is its lack of a bleed mechanism. The actuation force in the second direction will easily help overcome the high air pressure force from the pneumatic booster 85 during the engine valve closing. The elimination of the bleed mechanism will help simplify the construction of the pneumatic booster 85. Without a bleed mechanism or substantial leakage, the charge mechanism, including the charge orifice 86, is still needed to compensate for potential minor leakages, and adjust the pressure and air mass level in the pneumatic booster 85 to accommodate the pressure level variation in the cross-over passage or air storage tank. The actuator needs a lower boost force, for example, when the cross-over passage pressure is lower. In this sense, the charge mechanism also has a balance function, which is even true for the pneumatic boosters with a bleed mechanism.
Depending on the application, the rest of the embodiment in
Refer now to
When powered, the first and second electromagnets 134 and 136 attract the armature 138 in the first (top) and second (bottom) directions, respectively. The first electromagnet 134 is able to catch the armature 138 and keep the engine valve 20 open at the full lift. To crack open the engine valve 20 when the air pressure forces on the engine valve 20 and the pneumatic piston 80 are substantially balanced, the first electromagnet 134 only needs to overcome the preload from the return spring 72, which is achievable despite the highly nonlinear nature of the electromagnetic force because the overall lift for the cross-over engine valve and thus the air gap between the armature 134 and the electromagnet 134 are small. This can be further assisted, if necessary, by designing the pneumatic piston 80 to be appreciably larger than the engine valve head 22 and thus introducing a differential air pressure force in the first direction.
To close the engine valve 20 from the full open position, the first electromagnet 134 is de-energized, and the engine valve 20 is pushed down by the returning force of the return spring 72, with the pulling assistance, if necessary, from an energized second electromagnet 136. During the later phase of the closing, the pneumatic cylinder 86 is pressurized by volumetric contraction and optional charging action through the charge orifice 86b, and it helps slow down the engine valve 20 to achieve soft-seating. A further retarding action can be achieved by re-energizing the first electromagnet 134 in a controlled way, resulting in a desired pulling force in the first direction depending on the operational needs or feedback signal.
The pulling force in the second direction from the second electromagnet 136 may also assist the return spring 72, if a low spring preload is desired otherwise, in keeping the engine valve 20 seated during at least part of combustion, when the pressure in the power cylinder 102 appreciably exceeds that in the cross-over passage 110.
If the pneumatic booster 85 includes a bleed mechanism like the bleed holes 87 in
The second electromagnet 136 is indispensable, however, if one is to adopt a pneumatic booster design without, as shown in
In
In all the above descriptions, each of the switch and/or control valves may be either a single-stage type or a multiple-stage type. Each valve can be either a linear type (such as a spool valve) or a rotary type. Each valve can be driven or piloted by an electric, electromagnetic, mechanic, piezoelectric, or fluid means.
In some illustrations and descriptions, the fluid medium may be assumed or implied to be in hydraulic or in liquid form. In most cases, the same concepts can be applied, with proper scaling, to pneumatic boosters and systems. As such, the term “fluid” as used herein is meant to include both liquids and gases. Also, in many illustrations and descriptions so far, the application of the invention is defaulted to be in split four-stroke cycle internal combustion engine valve control, and it is not limited so. The invention can be applied to other situations where a fast and/or high-initial-force control of the motion is needed.
Although the present invention has been described with reference to the preferred embodiments, those skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention. As such, it is intended that the foregoing detailed description be regarded as illustrative rather than limiting and that it is the appended claims, including all equivalents thereof, which are intended to define the scope of this invention.
This application is a continuation of U.S. application Ser. No. 12/321,789 filed on Jan. 26, 2009, now U.S. Pat. No. 8,051,812, which is a continuation of U.S. application Ser. No. 11/787,295 filed on Apr. 16, 2007, now U.S. Pat. No. 7,536,984, the entire content of which is incorporated herein by reference.
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Number | Date | Country | |
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Parent | 12321789 | Jan 2009 | US |
Child | 12636051 | US | |
Parent | 11787295 | Apr 2007 | US |
Child | 12321789 | US |