The present invention relates to the conversion of chemical energy (fuel) into hydraulic, electric, or pneumatic energy, particularly by means of free-piston internal combustion engines. The general field of application is the efficient production of hydraulic, electric or pneumatic power for mobile and non-mobile power needs.
1. Free Piston Engines in General
Hydraulic power is frequently produced by rotating the drive shaft of a hydraulic pump by means of a rotational power source such as an electric motor or an internal combustion engine. The most efficient such pumps utilize a reciprocating-piston design in which the rotational power delivered to the drive shaft is converted to a linear motion of a set of pumping pistons that pump fluid and thereby create hydraulic power. When a conventional internal combustion engine is employed to drive the pump, the rotational drive power it delivers to the pump must also be converted from an originally linear motion of its combustion pistons to the rotational motion required by the pump. Conventional engines employ many parts (such as a crankshaft) to achieve this conversion. The crankshaft also provides a convenient means to achieve several ancillary functions such as: controlling the limits of movement of the combustion pistons, synchronizing and powering valve actuation by rotationally driving a camshaft or similar device, and providing inertia to help ensure each compression stroke will be completed.
The idea of directly coupling the linear motion of the engine combustion piston to the linear motion of the hydraulic piston to produce hydraulic power directly, and thereby avoid the weight and cost of the additional parts and inefficiencies (e.g., through friction losses) of converting linear motion to rotational motion and back again, is not new. In particular, free-piston engines have been considered as a means to directly convert the linear motion of a combustion piston to the linear motion of a pumping piston and thereby convert the majority of the engine's power output to hydraulic power without the need for the intermediate power-converting function of a crankshaft.
For purposes of the present application, a true free piston engine is defined here as an engine where the combustion pistons are not mechanically connected to a crankshaft or similar device. In contrast, a “quasi free piston engine,” as defined herein, which is also a direct-pumping engine like a true free piston engine, shall refer to an engine in which a majority of the engine's power output is taken out through a direct-pumping action similar to a true free piston engine, but in which the combustion pistons may nevertheless be mechanically connected to a crankshaft if desired. Unless otherwise indicated, true free piston engines and quasi free piston engines are both encompassed herein by generic references to a free piston engine.
In a true free piston engine, the absence of a crankshaft assembly means that the ancillary functions normally performed by it must be achieved by other means. Therefore one major challenge is how to control the exact stopping point of the piston assembly as it approaches the top dead center (TDC) position of the combustion piston during its compression stroke, (and more problematic, the exhaust stroke for a four-stroke configuration) in a way that is accurate and repeatable (for millions of events). A similar challenge is associated with the control of the exact stopping point of the assembly as it approaches the bottom dead center (BDC) position of the combustion piston during the expansion or power stroke. This is especially so since the friction of each stroke can vary (especially during warm-up or transient operation), the quantity of fuel provided for each combustion event can vary, the beginning of the combustion process can vary, the rate of combustion and its completeness can vary, the pressure of the hydraulic fluid being supplied to the pump can vary, the pressure of the hydraulic fluid being expelled can vary, and many other operating parameters that influence each stroke can vary; therefore, the accurate control of the TDC and BDC positions is very challenging. The consequences of inadequate control can go beyond unacceptable performance and be destructive to the engine, such as if the combustion piston hits the cylinder head of the combustion chamber or the pumping piston contacts the end of the pumping chamber.
Because of the challenges posed by operational control, most true free piston engines of the prior art operate on a two stroke cycle rather than a more desirable four-stroke cycle. A two-stroke dual piston configuration eliminates separate intake and exhaust strokes, and allows the compression stroke to be powered directly by the expansion stroke, obviating the need for crankshaft inertia to complete the cycle. Even on a two stroke cycle, stoppage of the combustion piston at the correct position at TDC during the compression stroke remains difficult. A four-stroke configuration would require a means to power the additional intake strokes and every other exhaust and compression stroke. The exhaust stroke poses a special difficulty because, unlike the compression stroke, there are no trapped gases to decelerate the combustion piston as it moves toward TDC, making it even more difficult to avoid hitting the cylinder head.
2. The Gray '204 Free Piston Engine
Multiple embodiments of a true free piston engine, including four-stroke true free piston engines, are disclosed and described in U.S. Pat. No. 6,582,204 to Gray. For purposes of better understanding the present invention, the Gray '204 engine will be briefly redescribed in part herein (with reference to
Cage 19 provides for a rigid structure to avoid bending of the assembly associated with the large acceleration and deceleration forces that occur with each stroke. A rigid structure and optional bushings 20 (
To start the engine, the dual piston assembly will be in the position as shown on
After combustion, as the dual piston assembly is accelerated by the force of the combustion gases on the cross sectional area of piston 13, the engine control unit (ECU) commands valve 24a to shut-off, so as to achieve fluid flow under pressure from cylinder 17 through check valve 28a and optional valve 33 to passage 29, thus producing hydraulic power output.
In the '204 patent, position sensors are disclosed to determine velocity and acceleration, and determine when to command valve closure. The ECU determines in real time the available energy produced from each combustion event from the velocity of the dual piston assembly mass and the forces still being applied to it (determined by the acceleration) at each position, considers the frictional energy consumption from characterization maps, and determines the power stroke of the pumping piston needed to achieve a dual piston assembly stoppage position so that the compressing combustion piston achieves the real time specified compression ratio for the next combustion event. The ECU then commands the fluid intake valve (valve 24a or 24b as appropriate) to close at that position intended to achieve the needed pumping piston power stroke.
As shown in the '204 patent, mechanically balanced four and eight cylinder dual piston assemblies in the true free piston engine configurations can be also be operated in a four stroke cycle. It will be helpful in understanding the invention to review the sequence of strokes in such a configuration.
3. Other Free Piston Prior Art
U.S. Pat. No. 4,441,587 to Patten mentions possible use of a crankshaft of reduced mass with a free piston engine to synchronize operation of the piston assemblies, but teaches away from the use of the crankshaft to limit or control piston travel or to transfer energy developed within the combustion chamber. Patten instead provides a novel braking system to prevent piston overtravel. Patten does not provide a flywheel to assist in supplying energy for carrying out the compression stroke to avoid power-down (i.e., in the event that combustion energy from the expansion stroke of the opposing piston is insufficient to fully power the corresponding compression stroke). Because Patten concerns itself only with providing a braking means for piston overtravel, Patten presumably provides an additional fuel increment to be sure that power down does not occur due to variabilities in combustion. Such over-fueling wastes fuel and is inefficient, as it would be more desirable to target the “right” amount of fuel for the combustion as long as it is possible to ensure desired TDC position in the movement of the pistons.
In addition, an internal combustion engine driving a crankshaft for a conventional vehicle drivetrain, but with a floating free piston in an auxiliary chamber for reducing peak combustion pressures and pumping fluid is disclosed in U.S. Pat. No. 5,611,300.
4. Challenges of the Prior Art
One challenge that remains with free piston engines is the difficulty in ensuring exact TDC position in the movement of the pistons.
For example, while the apparatus and methods of the Gray '204 patent have proven successful in providing operating control of a four stroke free piston engine, it has become desirable to ensure highly exact TDC positioning of the pistons in combustion in order to further improve the efficiency of the free piston engine. In particular, it has been found with the Gray device that even relatively small variability in the piston position requires operating the engine with a safety zone for the squish volume at TDC of greater than 1 millimeter, which has the undesirable effect of reducing the compression ratio and efficiency of the engine. Further, it has been found that if the engine is operated with a smaller squish volume (e.g. 0.5 mm), the variability can result in the combustion pistons hitting the cylinder head at higher engine speeds (e.g., above 2500 cycles per minute). It is instead desirable to be able to keep the squish volume down to a level below 1 millimeter, for better efficiency, but without resulting in hitting the cylinder head, thus requiring more exact TDC stopping positions.
In addition, it is also desirable to provide for efficient and reliable actuation of the intake and exhaust valves. Crankshaft and camshaft architecture for valve actuation in conventional engines is absent in a true free piston engine. Hydraulic actuation of the intake and exhaust valves of a free piston engine is also known, but involves significant energy loss. Applicant has found that a more efficient hydraulic valve actuation could further improve efficiency of a free piston engine by 2%-3%.
Accordingly, it is one object of the present invention to provide an efficient means for ensuring exact stoppage of combustion and pumping pistons at appropriate top dead center and bottom dead center positions in a free-piston engine.
A second object of the present invention is to provide an efficient valve actuation structure and method for a free-piston engine.
In order to achieve the foregoing objectives, a small and lightweight crankshaft connects the piston assemblies of the free piston engine with a flywheel, thereby providing a quasi free piston engine. While most of the power (e.g., up to 99% of the power output) from the combustion pistons is still extracted by the pumping pistons in the direct pumping action of a true free piston engine, the small crankshaft and flywheel nevertheless serve to ensure exact TDC position. Flywheel speed may additionally be monitored by a speed sensor, to provide feedback on power extraction for further control of the system. In addition, in one embodiment, a novel “hydraulic push-rod” system for more efficient valve actuation is provided. The embodiments disclosed herein encompass both two-stroke and four-stroke configurations.
A cross-sectional view of a preferred embodiment of a two-stroke quasi free piston engine of the present invention is presented in
As with
However, it will be noted that the quasi free piston engine of
As the combustion piston 13 in the power stroke approaches BDC, with its linked combustion piston 14 approaching TDC, or vice versa, any residual power not extracted by the pumping piston will cause rotation of the crankshaft 68, which in turn will drive flywheel 70. By appropriate sizing of the radius of crankshaft orbit 91 to effect the desired stroke of pistons 13 and 14, this connection of the various pistons of the quasi free piston engine to the crankshaft 68 provides a reliable desired stopping point for the combustion pistons in a similar manner as for a conventional engine, thereby enabling desired compression ratio and squish volume for efficient operation as well. Conversely, if too much power is extracted by the pumping piston 15 or 16, the inertia of flywheel 70 and the crank system (i.e., crankshaft 68, connecting rod 66, weight 65, and gearing mechanism 63 and 62b) will help move the piston assembly through the compression stroke to the proper TDC position for the next stroke to begin. Thus the flywheel 70 acts as a buffer against cycle-to-cycle variability as hydraulic power is extracted.
Guidance members 64 provide a guidance means for weight 65 and related components. Preferably guidance members 64 are of a smooth rail-like form, rigidly attached to block 71 and providing one or more smooth linear surfaces upon which one or more linear recesses on weight 65 may axially slide. Alternatively, the guidance means could be a rolling contact, such as a roller bearing situated between weight 65 and an inner surface of the block 71 or similarly rigid surface, or any other sliding or rolling means. The weight and dimensions of balancing member 63a are selected to counteract the weight and movements of gearing mechanism 63 and weight 65, and related components of the crank section, to provide mechanical balancing for the engine.
It should be noted that only minimal side forces are introduced by the crank system because most of the energy is taken out by the pumping piston and because of the small mass of the crankshaft 68.
Flywheel 70 may be configured either to rotate at the same speed as crankshaft 68, or to freewheel. As an incidental benefit of the engine of
A speed sensor 69 may be positioned on the crankshaft 68 or flywheel 70 (or in alternative locations to allow determination of rotational velocity, acceleration, or position of the crankshaft and/or flywheel). Signals from sensor 69 may be transmitted to an engine control unit (not shown) for the quasi free piston engine, to provide information which may then be used for engine control purposes. In particular, a feedback loop to adjust fuel feed for the engine, or to adjust the hydraulic power extraction, may be established. For example, if signals from sensor 69 indicate an acceleration or increased velocity of the crankshaft 68 or flywheel 70, that would indicate an excess of fuel feed in the prior combustion cycle, and the ECU could then send the appropriate signal to reduce fuel feed for the following combustion event.
The method of attaining a four-stroke, four- or eight-cylinder mechanically balanced configuration by combining multiple free-piston engine assemblies, as well established by the Gray '204 patent, applies as well to the quasi free piston engine. It will therefore be understood that multiple piston assemblies may be mechanically coupled, such as for example by gear and rack, such that the assemblies are balanced and synchronized. In such case, just one connection to the crankshaft is needed to control stopping position of pistons for all of the multiple potential combustion cylinders.
Referring now to an embodiment of additional features of the engine as shown in
Crankshaft 68 rotationally drives cam 74. Pistons 175a-d are biased to a default position and retained by return springs 179a-d. In this default position, low pressure ports 177a-d are exposed to a low pressure fluid source (not shown) to maintain fluid volume in the respective line. As cam 74 rotates, it sequentially engages each of pistons 175a-d, causing respective return springs 179a-d to compress, and causing the respective linear displacement of the respective pistons into the fluid-occupied space of respective hydraulic lines 176a-d, and the resultant displacement of fluid toward, and transmittal of force upon, the respective valve hydromechanical surfaces to which they connect. On displacement of a piston 175a-d, respective low pressure port 177a-d becomes closed off by the piston to ensure that fluid trapped in the respective line may not escape via the low pressure supply path. Alternatively, a one-way check valve may be provided at appropriate points in the low pressure supply path to serve the same purpose, and the low pressure ports 177a-d may remain exposed.
Following
Referring now to
As can be seen, in this manner, the fluid in lines 176a-d essentially acts as flexible, fixed-length rods for valve actuation. This fluidic mechanism of valve actuation may be analogized to the traditional mechanical push rods as known in conventional internal combustion engine art. In brief, this traditional mode of action is for a cam driven by a camshaft (which is in turn driven by a crankshaft) to cause lifting of rods which in turn cause rocker arms to cause intake and exhaust valves to lift and close for intake of air and exhaust of combustion gases from the combustion cylinder. The fluidic mechanism is clearly less complex and more efficient than the traditional method which relies on many intricate parts and is subject to many sources of mechanical friction. In addition, as the fluid in lines 176a-d is confined to a fixed volume, and is not pressurized and then discharged to lower pressure (as commonly done in camless hydraulic valve actuation systems), the valve actuation becomes more efficient.
The hydraulic valve actuation means described in
The sequence of valve actuation for the remaining strokes of the four-stroke cycle may be followed by comparing
Crankshaft 68 can also alternatively drive a rotary conventional valve actuation cam by gearing, belt or other commonly known means. Valve actuation by direct cam means is well known in prior art.
It should be noted that the quasi free piston engine of
As will be understood, the inventions herein may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning- and range of equivalency of the claims are therefore intended to be embraced therein.
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Number | Date | Country | |
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20100275884 A1 | Nov 2010 | US |