Abstract: The invention relates to an internal combustion engine comprising a combustion cylinder housing a combustion piston, a compressor cylinder housing a compressor piston, an expander cylinder housing an expander piston, and a crankshaft connected to the combustion piston and the expander piston by a respective connecting rod. The internal combustion engine further comprises a connecting element rigidly connecting the compressor piston and the expander piston such that the compressor piston and the expander piston move in unison.

Abstract: In a reciprocating internal combustion engine operating on a two-stroke cycle, the power stroke is followed by an abbreviated exhaust phase which ends with a portion of the exhaust products retained for recirculation, then by an abbreviated intake phase wherein pressurized new air is introduced, then by an abbreviated compression phase which completes the cycle. Fuel injection and ignition then initiate the next power stroke. Intake and exhaust take place through cylinder-head valves. The combination of a full expansion stroke with an abbreviated compression phase can offer efficiency superior to that of existing engines. Due to flexibility in the amount of pressurized air that can be introduced during intake, and because of the recirculation of relatively large amounts of exhaust gas, cylinder temperatures can be reduced, as can the emission of undesirable exhaust products.

Abstract: A balancing device for an engine includes a crankshaft for converting reciprocal motion of a piston of the engine to a rotary motion, at least one electromagnetic force generator mounted apart from the crankshaft by a predetermined distance and generating an electromagnetic force, and a control portion controlling the electromagnetic force generator to generate an electromagnetic force offsetting an unbalanced force occurring according to a rotational position of the crankshaft.

Abstract: Methods, systems, and devices are disclosed that generally involve split-cycle engines in which a combustion event is initiated in a crossover passage that interconnects a compression cylinder and an expansion cylinder of the split-cycle engine. In one embodiment, the compression piston leads the expansion piston by a phase shift angle so that, for example, a substantial amount of the combustion event can occur in the crossover passage at a constant volume.

Abstract: A twin vertical bank hybrid internal combustion H-engine system; an assembly having an engine block with parallel left side and right side vertical inline piston banks, each having a crankshaft and pistons, a cylinder head, and individual fuel feeds operable on a first and second fuel type respectively. Each piston bank operates independently of the other but is housed within the same engine block and has separate lubrication systems. An operator selects which engine to run based on fuel availability, convenience, or lower cost of a certain fuel type. The chosen engine is mechanically or electrically selected via an engine bank selector box using a selector control which selects the fuel type and engages a drive gear on the crankshaft of the selected engine, and transfers power to the transmission. The selector control actuates a transfer system that prevents simultaneous operation of both engines.

Abstract: An opposed-piston, opposed-cylinder OPOC engine is disclosed in which the central axis of the two cylinders is collinear. In four-stroke engines, this is possible with a built up crankshaft. Disclosed are connecting rod configurations that are suitable for a two-stroke engine that can be assembled to a unitary crankshaft, including both pullrods in tension and pushrods in compression. The configuration includes pistons arranged symmetrically, but with offset timing of the intake and exhaust pistons. The offset timing leads to a slight imbalance which can be partially overcome by having the center of gravity of the crankshaft offset from the axis of rotation.

Abstract: An engine has a stationary first body portion with one or more surfaces that define a portion of a fluid flow path through the engine. The stationary first body portion has a substantially cylindrical outer surface. A first piston assembly is configured to reciprocate relative to the stationary first body portion and to accommodate one or more second piston assemblies reciprocating inside and relative to the first piston assembly. The first piston assembly has an extension portion. The extension portion has a substantially cylindrical inner surface that defines a space to receive the stationary first body portion. One or more sealing elements are between the substantially cylindrical outer surface of the stationary first body portion and the extension portion of the first piston assembly.

Abstract: An engine includes an engine casing and a first piston configured to reciprocate relative to the engine casing. The first piston has a wall that defines a substantially cylindrical chamber. One or more second pistons are configured to reciprocate inside the substantially cylindrical chamber. A combustion chamber intake port and a combustion chamber exhaust port extend through the wall. A shutter is outside the wall and is movable between a first position substantially blocking fluid flow through the combustion chamber exhaust port but not blocking fluid flow through the combustion chamber intake port and a second position substantially blocking fluid flow through the combustion chamber intake port but not blocking flow through the combustion chamber exhaust port. An actuator causes the shutter to move between the first position and the second position in response to the first piston reciprocating relative to the engine casing.

Abstract: The horizontally opposed center fired engine improves on the traditional design of the horizontally opposed engines and center fired engines with a better engine geometry. The present invention utilizes four pairs of opposing pistons to compress a larger volume of air-fuel mixture within four different cylinders. The four different cylinders are radially positioned around a center axle in order to achieve a perfectly symmetric engine geometry. The center axle consists of two different shafts spinning in two different directions, which could drastically reduce engine vibrations in the present invention. Engine vibrations are caused by a change in engine speed and result in a loss of energy. Due to the design, the present invention will only experience energy loss in the form of entropy and friction. Thus, the present invention can convert a higher percentage of chemical energy into mechanical energy than any other internal combustion engine.

Abstract: An internal combustion engine twin power unit that includes a crossover passage fluidly connecting a first cylinder to a 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. 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.

Abstract: An invention is provided for an internal combustion engine twin power unit. The invention includes a crossover passage fluidly connecting a first cylinder to a 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. 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.

Abstract: A hybrid electric powertrain includes a direct-injection, two-stroke, port scavenged engine in hybrid combination with an electric motor. The engine is configured to use a fuel with wide flammability limits, such as hydrogen, for extremely lean combustion to significantly reduce emissions. The two-stroke engine eliminates the engine displacement problems associated with extremely lean combustion, and the use of a hybrid powertrain allows the engine to be operated efficiently with reduced throttling compared to the prior art. A continuously variable transmission, or a transmission with closely-stepped ratios, is preferably employed.

Abstract: A two stroke internal combustion engine, comprising one or more power cylinders with intake and exhaust ports and a source of scavenging of the power cylinders, with improvements, including use of double-sided cylinders with upper and lower cavities used as power or pumping cavities connected to each other in different combinations; multi-bank engine structures with cavities of the cylinders in the first and second bank used as power or pumping cavities, connected to each other in different combinations.

Abstract: A Recuperative Cycle tow-stroke internal combustion engine having an expander cylinder with an open combustion chamber in its working end and a separate compressor for injecting a compressed air charge into the chamber obtains improved Carnot efficiency by the containment of all its working components in a new and novel cylinder head. This head captures thermal energy normally thrown away in engine exhaust and transfers it advantageously back into the working cycle. The result, long sought by others, has been achieved by incorporating compactly within the head an internal exhaust heat recuperator or heat exchanger closely coupled with a combustion chamber open to the expansion cylinder. A recuperator-protecting valve isolates the recuperator from hot combustion gases until they have been cooled by full piston expansion and a catalytic convertor may be placed in an optimum temperature position within the recuperator chamber.