Methods and systems are provided for an exhaust gas mixer. In one example, a system may include a mixer configured to alter exhaust gas flow.

Methods and systems are provided for mixing gas in a flow passage by mounting a static flow mixer inside the flow passage. The static flow mixer may include a plurality of open and curved channels. The open and curved channels may mix the gas in multiple directions in the flow passage.

An exhaust system for an internal combustion engine, especially in a vehicle, includes an exhaust gas flow duct (14), a reactant release device (20) for the release of reactant (R) into the exhaust gas flow duct (14) and a catalytic converter device (16) downstream of the reactant release device (20). At least one part of a component surface is provided by a hydrophilic material (34) of at least one exhaust gas-carrying component (12, 22) positioned in the reactant flow path or/and defining this reactant flow path, or/and at least one part of the component surface is provided by a hydrophobic material (40) of at least one exhaust gas-carrying component (12, 18, 22) positioned in the reactant flow path.

A carbon monoxide oxidation device for oxidizing carbon monoxide contained in a hydrogen rich reformat gas includes a housing, wherein the housing incorporates an oxidation catalyst, which is adapted to oxidize the carbon monoxide of the reformat gas by an oxidizing agent to carbon dioxide, includes upstream of the catalyst at least one gas inlet for providing a gas stream of at least the reformat gas into the housing, includes downstream of the catalyst a gas outlet for exiting treated gas from the housing, and incorporates a gas stream perturbation device which is arranged upstream of the catalyst and which is adapted to provide a perturbation in the gas stream, wherein the gas stream perturbation device is designed as at least one propeller-shaped plate with a plate portion having a surface facing the gas stream and at least one blade which is connected to the plate portion and has a leading edge and an effluent edge, wherein a surface defined between leading edge and effluent edge is inclined in relation to the surface of the plate portion with a predetermined blade inclination angle, thereby defining at least one opening in the plate.

A gas mixing arrangement for mixing a process gas (MF) of a process plant, which arrangement comprises a gas duct (10a) for flow of said process gas, a mixing plate section (24) arranged in the gas duct (10a) and comprising at least one mixing plate (42, 44) arranged at an angle with respect to a main flow direction (C) of said process gas flowing through the gas duct (10a). The arrangement further comprises a guide vane section (22) arranged upstream of said mixing plate section (24) to cooperate therewith in mixing the process gas (MF) flowing through the gas duct (10a), the guide vane section (22) comprises a first group of guide vanes (26) arranged to direct a first gas flow portion (GP1) in a direction towards a first side wall (34) of the gas duct (10a), and a second group of guide vanes (28) arranged to direct a second gas flow portion (GP2) in a direction towards a second side wall (36) of the gas duct (10a), said second side wall (36) being opposite said first side wall (34).

Embodiments of gas mixing apparatus are provided herein. In some embodiments, a gas mixing apparatus may include a container defining an interior volume, the container having a closed top and bottom and a sidewall having a circular cross section with respect to a central axis of the container passing through the top and bottom; a plurality of first inlets coupled to the container proximate the top of the container to provide a plurality of process gases to the interior volume of the container, the plurality of first inlets disposed such that a flow path of the plurality of process gases through the plurality of first inlets is substantially tangential to the sidewall of the container; and an outlet coupled to the container proximate the bottom of the container to allow the plurality of process gases to be removed from the interior volume of the container.

A static mixing device subassembly that can be joined with other static mixing device subassemblies to form a static mixing device. The subassembly comprises a first pair of intersecting grids of spaced-apart and parallel deflector blades and a second pair of intersecting grids of spaced-apart and parallel deflector blades. The deflector blades in each one of the grids are interleaved with the deflector blades in the paired intersecting grid and have uncut side portions that join them together along a transverse strip where the deflector blades cross each other and cut side portions that extend from the uncut side portions to the ends of the deflector blades. Each of the deflector blades in one of the grids in each pair of grids has a bent portion that places segments of the deflector blade on opposite sides of the uncut portion in offset parallel planes. Some or all of the deflector blades in the other one of the grids in one of the pairs of grids has uncut ends that are interconnected with uncut ends of deflector blades in the other one of the grids in the other one of the pairs of grids along a reverse bend that aligns one of the pairs of grids with the other pair of grids.

An SCR exhaust aftertreatment device of an internal combustion engine, containing an injector for injecting a reductant, a mixing unit and an SCR catalytic converter disposed immediately downstream in the direction of exhaust flow, wherein the mixing unit exhibits a swirl element and an impact element positioned upstream of the swirl element in the direction of exhaust flow, whereby the swirl element is configured of two guide elements disposed inside one another and swirl vanes for creating a swirling motion are disposed in an inner guide element and swirl vanes, which create a counterswirling motion, are disposed between the inner guide element and the outer guide element.

An exhaust aftertreatment device for aftertreatment of exhaust gas of an internal combustion engine includes an SCR catalyst for selective catalytic reduction, a feeding apparatus for adding a reductant at an entry point upstream of the SCR catalyst to the exhaust gas, and a mixing apparatus arranged in a flow direction of the exhaust gas between the entry point and the SCR catalyst. The mixing apparatus includes a mixing element and a catalyst element, with the catalyst element having in the flow direction of the exhaust gas a cross sectional area which is smaller than a cross sectional area of the mixing element.

A mixing chamber assembly adapted for an engine aftertreatment system includes a first sub-compartment, a second sub-compartment, a mounting hole for installing a urea injector for spraying urea droplets into the first sub-compartment, and a middle sub-compartment connecting the first sub-compartment and the second sub-compartment. A mixer is positioned in the middle sub-compartment and includes a plurality of first blades inclined to the second sub-compartment. The first blades are divided into two groups of different inclined directions in order to achieve a double-swirl mixing effect. A plurality of second blades are inclined in the same direction and positioned upstream the first blades. As a result, flow distance within limited space can be increased to assure sufficient mixing of the urea droplets and the exhaust gas. The urea droplets are sufficiently heated to improve urea evaporation rate, improve uniformity of ammonia molecule and reduce the risk of urea deposits.