1. Field of the Invention
This invention relates generally to internal combustion engines, and more particularly to an oscillating cylinder twin power unit for an internal combustion engine.
2. Description of the Related Art
To derive power, conventional internal combustion engines ignite a compressed air-fuel mixture in a combustion chamber. The ignition of the compressed air-fuel mixture generates force against a piston, which is linked to a crankshaft in a manner such that the motion of the piston is converted into rotational motion of a drive shaft. More particularly, in operation air and fuel is provided to a combustion cylinder and compressed by the piston. Once compressed, the air-fuel mixture is ignited powering the piston and the crankshaft. The exhaust is then expelled from the cylinder.
Internal combustion engines generally can be either two-stroke or four-stroke engines. In general, two-stroke engines complete the power cycle during a single reciprocation of the piston, that is, one revolution of the crankshaft. Four-stroke engines generally require two reciprocations of the piston, or two revolutions of the crankshaft. Two-stroke engines offer certain advantages over four-stroke engines because the former produces power strokes twice as often as compared to the four-stroke engine. This permits two-stroke engines to be smaller in size and lighter in weight than four-stroke engines with a comparable power output. Two-stroke engines are also less expensive to manufacture and build because they require fewer parts that are subject to wear, breakdown and replacement.
Conventional two-stroke engines, however, are generally not as efficient as four-stroke engines because two-stroke engines do not effectively remove all of the exhaust gases from the combustion chamber before the next power producing cycle. For example,
Conventional internal combustion engines, including the prior art two-stoke engine 100 illustrated in
In view of the foregoing, there is a need for an internal combustion engine that does not lose power due to non-alignment of the axis of rotation of the crankshaft and the connecting rod. In addition, the internal combustion engine should prevent wasteful air-fuel mixture escaping the system prior to combustion.
Broadly speaking, the present invention addresses these needs by providing an oscillating cylinder twin power unit for an internal combustion engine. Broadly speaking, embodiments of the present invention utilize parallel oscillating cylinders coupled to a rod assembly, which powers a crankshaft without requiring a wrist pin. In addition, a trunnion mount allows the twin power unit to oscillate back and forth across a small arc while tracking the rotational movement of the point of contact between the base on the rod assembly and the crankshaft. For example, in one embodiment, an internal combustion engine twin power unit is disclosed. The internal combustion twin power unit includes a first cylinder and a second cylinder connected to the first cylinder via a crossover passage, where the crossover passage fluidly connects the first cylinder to the second cylinder. In addition, a rod assembly is included that is connected to a first piston and a second piston, which are disposed within the respective cylinders. The rod assembly rigidly fixes the first piston and the second piston in a fixed spatial relation to each other. The crossover passage allows, for example, an air-fuel mixture introduced in the first cylinder to be transferred to the second cylinder via the crossover passage, and an ignition in any cylinder will cause combustion of the air-fuel mixture in both cylinders via the crossover passage. The twin power unit can further include an intake port in fluid communication with the first cylinder and an exhaust port in fluid communication with the second cylinder. In this manner, air supplied to the first cylinder via the intake port is supplied to the second cylinder via the crossover passage. Here, air can be supplied to the first cylinder when the first piston clears the intake port, and the air can assist in expelling combustion exhaust gases from both cylinders out the exhaust port. The spatially fixed pistons allow, for example, both pistons to compress air present in the cylinders at essentially the same time, which further is facilitated by the first piston covering the intake port and the second piston covering the exhaust port during compression. In a similar manner, the combustion in both cylinders drives both the pistons towards lower portions of the cylinders essentially simultaneously. The twin power unit further includes a trunnion mount that allows the twin power unit to oscillate such that a centerline of the pistons is at all times aligned with a crank throw of a crankshaft.
An additional internal combustion engine twin power unit is disclosed in a further embodiment. In this embodiment, the internal combustion engine twin power unit includes a crossover passage fluidly connecting the first cylinder to the second cylinder such that an air-fuel mixture introduced in the first cylinder is transferred to the second cylinder via the crossover passage, and wherein an ignition in any cylinder causes combustion of the air-fuel mixture in both cylinders via the crossover passage. Also included is a rod assembly, which is connected to the first piston and the second piston which are disposed in the cylinders. As above, the rod assembly rigidly fixes the first piston and the second piston in a fixed spatial relation to each other. In addition, an intake port is included that is in fluid communication with both the first cylinder and the second cylinder. To control air passage within the intake port, a one-way valve is included. In this manner, air drawn into the first cylinder and the second cylinder via the intake port below the first piston and the second piston is prevented from escaping either cylinder via the intake port during downward motion of the first piston and the second piston. The twin power unit can further include an intake charge passage disposed between the intake port and first cylinder and between the intake port and the second cylinder. The intake charge passage is configured such that the first piston clears an area of the intake charge passage before the second piston during downward motion of the first piston and the second piston. In this manner, air compressed below the first piston and the second piston during downward motion of the pistons escapes into the first cylinder above the first piston via the intake charge passage when the first piston clears an area of the intake charge passage. In addition, an exhaust port can be included that is in fluid communication with the second cylinder. Here, compressed air escaping into the first cylinder via the intake charge passage purges combustion exhaust gases from both cylinders out the exhaust port.
In a further embodiment, an internal combustion engine twin power unit having a first cylinder and a second cylinder and an exhaust valve is disclosed. As above, the internal combustion engine twin power unit includes a crossover passage fluidly connecting the first cylinder to the second cylinder, wherein an air-fuel mixture introduced in the first cylinder is transferred to the second cylinder via the crossover passage, and wherein an ignition in any cylinder causes combustion of the air-fuel mixture in both cylinders via the crossover passage. Also as above, a rod assembly is included that is connected to the pistons and rigidly fixes the pistons in a fixed spatial relation to each other. A trunnion mount is included that allows the twin power unit to oscillate such that a centerline of the pistons is at all times aligned with a crank throw of a crankshaft. The oscillating motion produced via the trunnion is utilized to control the operation of an exhaust valve controlling exhaust gas flow from the second cylinder. In particular, a rocker assembly coupled to the exhaust valve controls the exhaust valve based on the oscillation of the twin power unit. In one embodiment, a rocker roller rotatebly attached the rocker assembly moves along a ramp cam having a high end and a low end during oscillation of the twin power unit. In this manner, oscillation of the twin power unit during downward motion of the pistons causes the rocker roller to move toward the high end of the ramp cam, which causes the rocker assembly to open the exhaust valve. Conversely, oscillation of the twin power unit during upward motion of the pistons causes the rocker roller to move toward the low end of the ramp cam, which causes causes the rocker assembly to close the exhaust valve.
In this manner, embodiments of the present invention advantageously allow power to be applied to crankshaft without the need of a wrist pin via the trunnion mount which allows the twin power unit to oscillate. In addition, the intake charge air compression and purge allows the efficient expulsion of combustion exhaust gases without the need of an external system. Other aspects and advantages of the invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
The invention, together with further advantages thereof, may best be understood by reference to the following description taken in conjunction with the accompanying drawings in which:
An invention is disclosed for providing a twin power unit having an oscillating cylinders for an internal combustion engine. Broadly speaking, embodiments of the present invention utilize parallel oscillating cylinders coupled to a rod assembly, which powers a crankshaft without requiring a wrist pin. In addition, a trunnion mount allows the twin power unit to oscillate back and forth across a small arc while tracking the rotational movement of the point of contact between the base on the rod assembly and the crankshaft. Hence, the trunnion mount allows the twin power unit to oscillate such that the centerline of the pistons is at all times aligned with the crank throw of the crankshaft to eliminate lateral force vectors. Since the rod assembly directly connects the pistons to the crankshaft, there is no need for a wrist pin and connecting rod. Moreover, in one embodiment, a unique enclosed cylinder design is utilized to allow an intake air charge to be compressed beneath the pistons and later blasted into the cylinders above the pistons to purge combustion exhaust gases from the cylinders. As will be appreciated after a careful reading of the present disclosure, the twin power units described below can be utilized alone, or with multiple twin power units connected to the crankshaft.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without some or all of these specific details. In other instances, well known process steps have not been described in detail in order not to unnecessarily obscure the present invention.
Embodiments of the present invention provide twin power pistons (i.e., the intake piston 202 and exhaust piston 204) that fire simultaneously to drive a crankshaft via a one piece rod assembly 218, that rigidly fixes the intake piston and exhaust piston in a fixed spatial relation to each other. As will be described in greater detail below, the trunnion mounted cylinders allow the twin power unit 200 to rotate with the one piece rod assembly 218 allowing power transference without the need for a wrist pin. Moreover, the use of fully enclosed cylinders allows an intake charge without the need of an enclosed crankcase, which leads to oil mixing with the intake charge resulting in heavy emissions concerns.
In operation, the twin power unit functions utilizing three cycles: 1) charge cycle, 2) power cycle, and 3) purge cycle, which will be described with reference to
In addition, as the intake piston 208 and exhaust piston 210 rise, the pistons move to reveal the intake charge passage 232. The rising movement of the intake piston 208 and exhaust piston 210 draws in an air intake charge from the intake port 230 and through the intake charge passage 232 into the bottom portions of the intake cylinder 202 and exhaust cylinder 204 beneath the pistons 208 and 210. Both the intake cylinder 202 and the exhaust cylinder 204 are fully enclosed, thus preventing the intake air from escaping. In addition, as will be described in greater detail subsequently, during the charge cycle the exhaust port 228 is covered by the exhaust piston skirt 226, preventing the intake air charge from escaping via the exhaust port 228.
The power cycle begins once the pistons reach the top of the cylinders at 12 o'clock and full compression is achieved, as illustrated in
Once the exhaust piston 210 begins to clear the exhaust port 228, the combustion exhaust gases from the power cycle begin to escape the exhaust cylinder 204 via the exhaust port 228 into the exhaust pipe 302. As the pistons 208 and 210 continue to travel downward, the intake piston 208 begins to reveal the intake charge passage 232. Once the top of the intake piston 208 drops below the top of the intake charge passage 232, the intake charge air compressed beneath the pistons 208 and 210, and in the portion of intake port 230 on the piston side of the reed valve 300, is blasted into the intake cylinder 202 above the intake piston 208.
The rapid intake charge air blast purges the combustion exhaust gases from the intake cylinder 202, through the air-fuel crossover passage 234, through the exhaust cylinder 204, and out the exhaust port 228. As will be appreciated by those skilled in the art after a careful reading of the present disclosure, the rapid intake charge air blast also purges the combustion exhaust gases from the air-fuel crossover passage 234 and the exhaust cylinder 204.
As the intake piston 208 and exhaust piston 210 begin to travel back upward, the intake charge air, forced via the upward motion of the pistons 208 and 210 further expels the combustion exhaust gases from the cylinders 202/204 and air-fuel crossover passage 234 out the exhaust port 228. In addition, another charge cycle begins with the fuel injector 212 delivering fuel to the intake cylinder 202, and the pistons 208/210 rising to reveal the intake charge passage 232, and thereby drawing in another air intake charge into the bottom portions of the intake cylinder 202 and exhaust cylinder 204 beneath the pistons 208 and 210. As mentioned above, the trunnion mounted cylinders of the embodiments of the present invention allow the twin power unit 200 to rotate with the one piece rod assembly 218 allowing power transference without the need for a wrist pin, as discussed next with reference to
In operation 404, the air-fuel mixture present in the top portions of the intake cylinder and exhaust cylinder above the pistons is ignited utilizing a spark plug.
Referring back to
During operation 406, the downward motion of the pistons 208/210 also drives the intake air present in both cylinders 202/204 below the pistons 208/210 back into the intake port 230 via the intake charge passage 232. However, the one-way reed valve present in the intake port 230 prevents the intake air from escaping out of the intake port 230. As a result, the downward motion of the pistons 208/210 compresses the intake air in the bottom portion of the cylinders 202/204 and portion of intake port 230 on the piston side of the reed valve.
In operation 408, the compressed intake air is blasted into the intake cylinder via the intake charge passage.
Turing back to
In addition, the intake piston 208 and exhaust piston 210 rise to reveal the intake charge passage 232. The rising movement of the pistons 208/210 draws in an air intake charge from the intake port 230, through the intake charge passage 232 and into the bottom portions of the cylinders 202/204 beneath the pistons 208/210. As discussed above, both the intake cylinder 202 and the exhaust cylinder 204 are fully enclosed, thus preventing the intake air from escaping. In addition, during operation 410 the exhaust piston skirt 226 covers the exhaust port 228, thereby preventing the intake air charge from escaping via the exhaust port 228.
Referring back to
Similar to the embodiment of
The purge cycle begins as the pistons 208 and 210 travel downward within the cylinders 202/204 and the twin power unit 200′ begins to pivot about the trunnion mount 304 allowing the rod assembly 218 and pistons 208/210 to follow the rotation of the crankshaft via the crank journal. As the twin power unit 200′ pivots about the trunnion mount 304, the rocker roller 604 begins to roll up the ramp cam 606. The ramp cam 606 is mounted outside the twin power unit 200′ and remains in a fixed position as the twin power unit 200′ pivots. The rocker roller 604 is coupled to the rocker assembly 602, which is attached to the twin power unit 200′. Hence, as the twin power unit 200′ pivots, the rocking motion of the twin power unit 200′ causes the rocker roller 604 to roll back and forth along the ramp cam 606. As the rocker roller 604 rolls up the ramp cam 606, the attached rocker assembly 602 causes the exhaust valve 600 to open. Then, as the rocker roller 604 rolls back down the ramp cam 606, caused by the twin power unit 200′ pivoting in the opposite direction, the attached rocker assembly 602 allows the exhaust valve 600 to close.
In this manner, when the rod assembly 218 is located at about 3:00 with respect to the crankshaft, and the pistons 208/210 have traversed approximately half the distance to their bottom most position, the rocker roller 604 is positioned on the ramp cam 606 such that the rocker assembly 602 causes the exhaust valve 600 to open. The opening of the exhaust valve 600 allows the combustion exhaust gases in the upper portion of the cylinders 202/204 to escape the cylinders 202/204. In addition, as the pistons 208/210 continue travel downward within the cylinders 202/204, the exhaust the exhaust piston 210 begins to clear the exhaust port 228 when the rod assembly 218 reaches about 4:00 with respect to the crankshaft, allowing additional combustion exhaust gases to escape.
The charge cycle begins as the pistons travel further downward and the intake piston 208 begins to clear the intake port 230. At this point, a blower blast intake charge air into the intake cylinder 202 above the intake piston 208. The intake blast air helps purge the remaining combustion exhaust gases present in both the intake cylinder 202 and the exhaust cylinder 204. A bellows charges intake air through the intake port 230, up the intake cylinder 202, through the air-fuel crossover passage 234, and out the exhaust cylinder 204 through the exhaust port 228 and the past the open exhaust valve port 608. As can be appreciated, the twin power unit 200′ of
Compression starts when the rod assembly 218 reaches about 9:00 o'clock with respect to the crankshaft and the fuel injector 212 injects fuel into the intake cylinder 202. The intake charge air coupled with the compression from the rising pistons 2058/210 causes the fuel to efficiently mix with the compressed intake air charge creating an air-fuel mixture. In addition, part of the air-fuel mixture in the intake cylinder 202 flows into the air-fuel crossover passage 234 and into the exhaust cylinder 204, which at this point has all exhaust ports closed. Once the pistons 208/210 reach their top most positions within the cylinders 202/204, another power cycle begins with the spark plug 214 igniting the air-fuel mixture present in both cylinders 202/204 and the air-fuel crossover passage 234.
As those skilled in the art will appreciate after a careful reading of the present disclosure, embodiments of the present invention provide power on each revolution of the crankshaft. Moreover, the trunnion mount allows the twin power unit to oscillate back and forth across a small arc while tracking the rotational movement of the point of contact between the base on the rod assembly and the crankshaft. Hence, trunnion mount allows the twin power unit to oscillate such that the centerline of the pistons is at all times aligned with the crank throw of the crankshaft to eliminate lateral force vectors. The rigid fixed-length rod assembly connecting the pistons to the crankshaft causes the cylinders to oscillate while the pistons rotate semi-elliptically in their motion to turn the crankshaft. Since the rod assembly directly connects the pistons to the crankshaft, there is no need for a wrist pin and connecting rod. Furthermore, the below piston compressed intake air charge and reed valve design of the embodiment of
Although the foregoing invention has been described in some detail for purposes of clarity of understanding, it will be apparent that certain changes and modifications may be practiced within the scope of the appended claims. Accordingly, the present embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalents of the appended claims.
This application claims the benefit of U.S. Provisional Patent Application having Ser. No. 61/016,454, filed on Dec. 22, 2007, entitled “Internal Combustion Engine Twin Power Unit Having an Oscillating Cylinder,” by inventor Joseph E. Springer, which is hereby incorporated by reference.
Number | Date | Country | |
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61016454 | Dec 2007 | US |