This invention provides a method to clean the inside surfaces of an engine and its exhaust after-treatment system each time the engine is shut down. This cleaning is accomplished without disassembly of the engine and without involvement of the engine's operator. This cleaning includes the combustion chamber, valves, intake and exhaust ports, particulate filters, catalytic after-treatment processes, and exhaust piping. This is accomplished by leaving the shut down engine and its exhaust after-treatment systems in an oxygen rich atmosphere where oxidation of the hydrocarbons on the inside surfaces continues.

This invention provides a method to clean the inside surfaces of an exhaust after-treatment system each time the engine is shut down. This cleaning is accomplished without disassembly of the engine and without involvement of the engine's operator. This cleaning includes the exhaust ports, particulate filters, catalytic after-treatment processes, and exhaust conduits. This is accomplished by leaving the exhaust after-treatment systems in an oxygen rich atmosphere, with the engine shut down, where oxidation of the hydrocarbons on the inside surfaces continues.

Exhaust gas is treated onboard a vehicle. Solar energy is converted into electricity, which is used to power an electrochemical cell mounted onboard the vehicle. Oxygen and hydrogen are produced by the electrochemical cell. Heat and the oxygen produced by the electrochemical cell are provided to a particulate matter filter onboard the vehicle, thereby oxidizing particulate matter disposed on the particulate matter filter.

A flywheel assembly for a renewable energy generation system includes a flywheel housing defining a cavity therein, a flywheel rotatably disposed within the cavity of the flywheel housing, where the flywheel is simultaneously formed from the same component as the flywheel housing, a magnetic levitation disk defining opposed upper and lower surfaces, the upper surface supporting the flywheel and the lower surface including a first plurality of magnets disposed thereon, and a base plate having a second plurality of magnets disposed on a surface thereof that is facing the first plurality of magnets, the second plurality of magnets having a polarity that is opposite of a polarity of the first plurality of magnets such that the magnetic force of the first and second plurality of magnets urges the magnetic levitation disk away from the base plate.

Embodiments of a method (e.g., for operating a robotic device such as a dog device, etc.) can include: receiving one or more inputs (e.g., sensor input data, etc.) at a dog device (e.g., at one or more sensors of the dog device; a robotic dog device; etc.) from one or more users and/or other suitable entities (e.g., additional dog devices; etc.); determining one or more events (and/or a lack of one or more events), such as based on the one or more inputs (and/or a lack of one or more inputs); processing (e.g., determining, implementing, etc.) one or more scenes based on the one or more events (and/or lack of one or more events); and/or performing one or more output actions with the dog device, based on the one or more scenes (e.g., individual scenes; scene flows; etc.).

A method and system for improving the fuel economy and lowering the emissions of internal combustion engines by injecting predetermined amounts and ratios of on-board or locally generated hydrogen and oxygen to the engine's air intake and varying the gas addition volume and hydrogen/oxygen ratio as a function of the operating conditions, e.g., in line with the instant engine load.

An electrolytic system for an internal combustion engine includes an electrolyte tank for receiving an anode electrode, a cathode electrode, and an electrolytic fluid therein for communication with the anode and cathode. A power source applies an electrical potential between the anode and the cathode to generate a current through the electrolytic fluid and produce an electrolytic reaction in the electrolyte tank which produces combustible gases. A gas outlet communicates the combustible gases from the electrolyte tank to the internal combustion engine. At least one of the electrodes A hollow passage which does not communicate with the electrolytic fluid in the electrolyte tank extends through one of the electrodes to receive a heat exchange fluid circulated therethrough so as to be arranged to exchange heat with said at least one of the electrodes.

A method for operating an internal combustion engine using a gas mixture that is supplied to the fossil fuel in the engine combustion chamber in addition to the combustion air and is produced by the electrolysis of water includes measuring a quantity of air drawn into the intake tract of the engine in accordance with a particular engine operating mode. The method further includes directly supplying, to the combustion air per unit of volume of combustion air, a same, limited quantity of Brown's gas that acts as an additive, that is produced by means of an electrolyzer operated using a pulsating current, and that contains energy-enriched, gaseous water molecules. The percentage of the gas molecules present in the fuel during the combustion process is limited.

The present invention relates to a free-piston linear apparatus, comprising a piston arranged within a cylinder, said piston being configured for linear displacement within the cylinder; a combustion chamber arranged on one side of said piston and a gas expansion chamber arranged on an opposite side of said piston, wherein said piston is drivable under the action of a fuel medium expanding in the combustion chamber; an exhaust vent arranged to release exhaust gas from the combustion chamber to an exhaust system, wherein said exhaust system comprises a heat exchanger configured to transfer residual heat from said exhaust gas to said gas expansion chamber in order to heat the gas expansion chamber; and wherein said gas expansion chamber comprises at least one gas port for injecting and/or releasing gas into/from the gas expansion chamber.

A system for reducing polluting emissions of diesel engines includes a hydrogen gas generator that mixes the hydrogen gas with diesel fuel during certain operations phases of the engine. A default program mixes no hydrogen gas with the diesel fuel. A first operational program, during a cold start, mixes the hydrogen gas and diesel fuel in a 1:1 ratio. A second operational program, during a stabilization phase, mixes the hydrogen gas and diesel fuel in a 1:3 ratio. A third operational program, during a hot start phase, mixes the hydrogen gas and diesel fuel in a 1:2 ratio.