Embodiments described herein methods can be used in particulate filter regeneration, such as particulate filters used for filtering the exhaust of an engine, e.g., a diesel engine. Systems herein can be configured to dispense combustion gas(es) into housing were a particulate filter is contained and to ignite the combustion gases. Methods for conducting a safety verification process of such systems are disclosed, as well as methods for regenerating the filters. Still other embodiments are described.

A burner for an exhaust gas tract that can be flowed through by exhaust gas of an internal combustion engine includes a combustion chamber in which a mixture of air and liquid fuel is to be ignited and combusted and an inner swirl chamber that can be flowed through by a first part of the air and causes a turbulent flow of the first part of the air. The swirl chamber has a first outflow opening that can be flowed through by the first part of the air flowing through the inner swirl chamber and via which the first part of the air can be removed from the inner swirl chamber. The burner further includes an introduction element that can be flowed through by the liquid fuel and via which the fuel can be introduced into the inner swirl chamber.

An exhaust treatment system comprises an excitation chamber that generates a plasma field to excite a stream of exhaust gas and a mixing chamber that allows a portion of the exhaust gas stream to be oxidized. The excitation chamber comprises an inner housing, an outer housing, and an exhaust inlet that directs a stream of exhaust gas to enter into the outer housing of the excitation chamber. The enclosure of the inner housing includes orifices that allow at least a portion of the exhaust gas to enter into the inner housing from the outer housing. The inner housing includes electrodes for generating the plasma field. The inner wall of the inner housing includes a surface topology that cooperates with the orifices of the enclosure to entrain the exhaust gas to travel in a coherent-structured turbulence flow form in the inner housing.

Methods and systems are provided related to an emissions control system. The emissions control system has an exhaust after-treatment system defining a plurality of distinct exhaust flow passages through which at least a portion of an exhaust stream can flow, e.g., the exhaust stream is produced by an engine. The emissions control system also includes a controller for controlling injection of reductant into the exhaust stream flowing through each of the flow passages. In one example, the emissions control system is configured for use in a vehicle, such as a locomotive or other rail vehicle.

An operation control apparatus for an internal combustion engine includes: an exhaust emission purifier; a fuel supplying valve for supplying fuel to an exhaust passage; ignition means for igniting the fuel supplied; a warm up determining section for determining whether or not the purifier need be warmed; an exhaust heating determining section for determining whether or not the engine is in an operational state in which the fuel should be ignited and burned; an exhaust heating predicting section for predicting the transition from the operational state in which the fuel should not be ignited and burned to an operational state in which the fuel should be ignited and burned; and a heat generation temperature setting section for setting the temperature of a heating portion of the ignition means based on the result by the heating determining section and the predicting section.

Embodiments described herein methods can be used in particulate filter regeneration, such as particulate filters used for filtering the exhaust of an engine, e.g., a diesel engine. Systems herein can be configured to dispense combustion gas(es) into housing were a particulate filter is contained and to ignite the combustion gases. Methods for conducting a safety verification process of such systems are disclosed, as well as methods for regenerating the filters. Still other embodiments are described.

A burner for an exhaust-gas aftertreatment system. The burner includes a housing forming a combustion chamber, the housing having an outlet connected or connectable to an exhaust-gas line of the exhaust-gas aftertreatment system; a fuel feed device for feeding fuel into the combustion chamber; a fresh air feed device for feeding fresh air into the combustion chamber; and an ignition unit for igniting a fresh air-fuel mixture arranged in the combustion chamber. The ignition unit has a glow plug, which is arranged in the combustion chamber in such a way that a longitudinal center axis of the glow plug is oriented obliquely to a cross-sectional plane of the combustion chamber.

A system for reducing internal combustion engine emissions includes an engine, a catalytic converter fluidly connected to a combustion chamber via an exhaust line, a glow plug positioned along the exhaust line between the catalytic converter and the combustion chamber, and a flame accelerator, without a fluid connection to a separate fuel supply. Methods of using the system include igniting a mixture of air and fuel in the exhaust line using the glow plug, producing an amount of heated combustion gas.

A method of decomposing particulate pollutants present in exhaust gases is disclosed. Also disclosed are compositions for use in the method for cleaning exhaust gases, as well as methods of preparing said compositions. Also disclosed are systems configured to carry out a decomposition process to remove particulate pollutants from exhaust gas.

A burner for an exhaust-gas aftertreatment system. The burner includes a housing forming a combustion chamber. The housing has an outlet which is or can be connected to an exhaust-gas line of the exhaust-gas aftertreatment system. The burner further includes a fuel feed device for feeding fuel into the combustion chamber; a fresh-air feed device for feeding fresh air into the combustion chamber; and an ignition element for igniting a fresh-air/fuel mixture located in the combustion chamber. It is provided that the housing is designed such that the combustion chamber has a cylindrical main portion and a bulge protruding radially outward from the main portion, and that the ignition element is arranged in the bulge.