An exhaust gas heating unit for an exhaust system of an internal combustion engine includes a jacket heating conductor element (12) including a jacket (16) and with an electrical heating conductor (14), which extends in the jacket and is enclosed by insulating material (18). A heat transfer surface formation (20) is arranged on, and in heat transfer contact with, an outer side of the jacket. The heat transfer surface formation includes a heat transfer element with a meandering extent along the jacket heating conductor element with a plurality of heat transfer element sections (32), which pass over into one another in bent areas (30) and are arranged following one another in a longitudinal direction of the jacket heating conductor element. Each heat transfer element section in association with the jacket heating conductor element has a passage opening (34), through which the jacket heating conductor element passes.

A device for reducing the emission of carbon particles from combustion of hydrocarbons, more particularly in exhaust emission of vehicles, includes a duality of electrically conducting rotating members with opposite polarities, charged with high voltage to create a corona discharge and agglomerate the ionized carbon particles. The carbon particles are cleaned using a plurality of wipers. The agglomerated carbon particles are then separated in a removable collection box or are optionally fed to a cyclone filter to be disposed. Various embodiments may be installed in existing vehicles as well as in open source pollution locations to helps control air pollution.

A disclosed system for reducing particulate matter in exhaust gas includes: a processing object unit having a preset system voltage and configured to produce exhaust gas containing particulate matters (PMs); a first conductor provided in the form of a tubular body in which the exhaust gas flows and to which a ground power supply is connected; a second conductor disposed in the first conductor and having an emitter which comes into contact with the exhaust gas and generates non-thermal plasma (NTP); an insulator configured to electrically separate the second conductor from the first conductor; and a transformer provided to be electrically insulated from the first conductor and fixedly disposed outside the tubular body that constitutes the first conductor, the transformer being configured to receive the system voltage, raise the system voltage to a preset operating voltage, and apply the preset operating voltage to the second conductor.

A transfer module for transferring power to a non-thermal plasma generator includes a power cable; a first epoxy; a second epoxy; an interface between the first epoxy and the second epoxy; and a well; the power cable including a conductor for conducting electrical power and an insulation layer for surrounding a portion of the conductor; the first epoxy being located within the well to surround the insulation layer; the second epoxy being located within the well to surround the conductor located within the well; the second epoxy being located outside the well to surround the conductor located outside the well.

An internal combustion engine provided with an engine body, a filter provided in an exhaust passage of the engine body and trapping PM in the exhaust, and an aggregating device charging PM in the exhaust flowing into the filter to make it aggregate. The control device for controlling the internal combustion engine is provided with a PM charging control part controlling the amount of charging of the PM in the exhaust flowing into the filter. The PM charging control part controls the aggregating device so that the amount of charging of the PM becomes smaller when the amount of PM buildup of the filter is large compared with when it is small.

A device for reducing the emission of carbon particles from combustion of hydrocarbons, more particularly in exhaust emission of vehicles, includes a duality of electrically conducting rotating members with opposite polarities, charged with high voltage to create a corona discharge and agglomerate the ionized carbon particles. The carbon particles are cleaned using a plurality of wipers. The agglomerated carbon particles are then separated in a removable collection box or are optionally fed to a cyclone filter to be disposed. Various embodiments may be installed in existing vehicles as well as in open source pollution locations to helps control air pollution.

An exhaust gas heating unit for an exhaust system of an internal combustion engine includes a jacket heating conductor element (12) including a jacket (16) and with an electrical heating conductor (14), which extends in the jacket and is enclosed by insulating material (18). A heat transfer surface formation (20) is arranged on, and in heat transfer contact with, an outer side of the jacket. The heat transfer surface formation includes a heat transfer element with a meandering extent along the jacket heating conductor element with a plurality of heat transfer element sections (32), which pass over into one another in bent areas (30) and are arranged following one another in a longitudinal direction of the jacket heating conductor element. Each heat transfer element section in association with the jacket heating conductor element has a passage opening (34), through which the jacket heating conductor element passes.

There is provided a first PM sensor provided upstream of a filter and including a first sensor filter having a plurality of first cells collecting PM in the exhaust gas to be introduced into the filter, and a first pair of electrodes arranged to face each other with the first cell interposed therebetween, a second PM sensor provided downstream of the filter and including a second sensor filter having a plurality of second cells collecting PM in the exhaust gas discharged from the filter, and a second pair of electrodes arranged to face each other with the second cell interposed therebetween, and a filter state determination unit for acquiring an efficiency of collecting the PM in the filter, based on a first electrostatic capacitance between the first pair of electrodes and a second electrostatic capacitance between the second pair of electrodes.

An exhaust purification device includes: an exhaust pipe configured to discharge exhaust gas from an internal combustion engine; a filter provided in the exhaust pipe and configured to collect a particulate matter contained in the exhaust gas; a plurality of electrodes configured to apply electric fields to a plurality of regions of the filter, respectively; and a power supply configured to apply at least two AC signals mutually different in phase to the plurality of electrodes.

A transfer module for transferring power to a non-thermal plasma generator includes a power cable; a first epoxy; a second epoxy; an interface between the first epoxy and the second epoxy; and a well; the power cable including a conductor for conducting electrical power and an insulation layer for surrounding a portion of the conductor; the first epoxy being located within the well to surround the insulation layer; the second epoxy being located within the well to surround the conductor located within the well; the second epoxy being located outside the well to surround the conductor located outside the well.