The present invention provides a fluidic device in which solutions of different concentrations can be easily obtained. The fluidic device includes: a first substrate and a second substrate which are stacked in a thickness direction; an undiluted solution introduction flow path which has an undiluted solution introduction port and which is constituted of a groove part provided on at least one of the first substrate and the second substrate; a first circulation flow path which is constituted of a groove part having an annular shape and having a shared part that shares part of a flow path with the undiluted solution introduction flow path and a non-shared part which is not shared with the undiluted solution introduction flow path and which is connected to a diluting solution introduction port; a second circulation flow path which is provided independently of the first circulation flow path and which is constituted of a groove part having an annular shape and having a shared part that shares some flow path with the undiluted solution introduction flow path and a non-shared part which is not shared with the undiluted solution introduction flow path and which is connected to a diluting solution introduction port; and/or a third circulation flow path which is constituted of a groove part having an annular shape and having a shared flow path that shares part of a flow path with the first circulation flow path and a non-shared flow path which is not shared with the first circulation flow path and which is connected to a diluting solution introduction port, wherein the undiluted solution introduction flow path includes a valve at both ends of the shared part.

A container system for liquids, including an in-container mixer/aerator in the exit throat of the container. The mixer/aerator is a cylinder, having axial peripheral grooves, and and axial central bore, divided by axial vanes.

A static mixer includes two or more mixing segments, each mixing segment including an inlet section, an outlet section oppositely disposed to the inlet section, a longitudinal axis defined between the inlet section and the outlet section, a plurality of mixing passages and a common distributor connected to each of the plurality of mixing passages of the mixing segment. The common distributor is arranged at the inlet section. Furthermore, inlets of the passages of the mixing segments form an inlet arrangement at the distributor of the corresponding mixing segment and outlets of the passages of the individual mixing segments form an outlet arrangement at the outlet section of the corresponding mixing segment. Thereby, the outlet arrangement is different from the inlet arrangement.

The invention relates to a mixing device (1) for integration into an exhaust pipe (4.1, 4.2) of an internal combustion engine and for mixing an exhaust gas stream (T), which device is formed from a housing (2) having a tubular wall (2.1) and a mid-axis (2.2) that can be aligned parallel to the exhaust pipe (4.1, 4.2) and from an intermediate wall (3) which is aligned transversely with respect to the mid-axis (2.2), wherein the intermediate wall (3) divides the housing (2) and has an inflow side (3.1) and an outflow side (3.2), wherein at least one inflow opening (E1) is provided in the intermediate wall (3), via which the exhaust gas stream (T) can at least partly flow from the inflow side (3.1) of the intermediate wall (3) to the opposite outflow side (3.2) of the intermediate wall (3), wherein the at least one inflow opening (E1) is placed eccentrically with respect to the mid-axis (2.2) and is brought close to a wall section (W1) of the tubular wall (2.1), wherein a flow guide element (S2) having a longitudinal axis (L2) is provided on the outflow side (3.2), which at least partly bounds a mixing chamber (2.3) with the intermediate wall (3) and by means of which an at least partial deflection of the exhaust gas stream (T) in a radial direction in relation to the mid-axis (2.2) can be effected, wherein the flow guide element (S2) has at least two outflow openings (A1, A2) and, by means of the flow guide element (S2), the exhaust gas stream (T) coming from the inflow opening (E1) can be guided to the at least two outflow openings (A1, A2), wherein the outflow openings (A1, A2) are placed eccentrically with respect to the mid-axis (2.2) and brought close to a common wall section (W2) of the tubular wall (2.1), wherein the wall section (W2) is arranged opposite to the wall section (W1) with respect to the mid-axis (2.2), and wherein the outflow openings (A1, A2) are arranged on opposite sides of the flow guide element (S2) with respect to the longitudinal axis (L1, L2), wherein, with respect to the mid-axis (2.2), the first partial stream (T3) can be can at least partly guided in the anticlockwise direction and a second partial stream (T4) can at least partly be guided in the clockwise direction out of the outflow openings (A1, A2).

The purpose of the present disclosure is, in a bubble generating device provided with a bubble generating unit for generating minute bubbles in water flowing through the inside of the cylindrical main body unit, to improve the bubble generating efficiency of the bubble generating unit. Provided is a bubble generating device provided with a cylindrical main body unit and a bubble generating unit disposed within the main body, wherein: the bubble generating unit is provided with slits extending radially centered on one point within the main body unit in a cross-sectional plane of the main body unit, and a column part protruding from the inner peripheral surface of main body unit and formed on the peripheral edge of the slits; and the amount of protrusion of the column part is gradually reduced toward the upstream side from the peripheral edges of the slits, and the column part has a recessed part formed on the downstream surface.

The purpose of the present disclosure is, in a bubble generating device provided with a bubble generating unit for generating minute bubbles in water flowing through the inside of the cylindrical main body unit, to improve the bubble generating efficiency of the bubble generating unit. Provided is a bubble generating device provided with a cylindrical main body unit and a bubble generating unit disposed within the main body, wherein: the bubble generating unit is provided with slits extending radially centered on one point within the main body unit in a cross-sectional plane of the main body unit, and a column part protruding from the inner peripheral surface of main body unit and formed on the peripheral edge of the slits; and the amount of protrusion of the column part is gradually reduced toward the upstream side from the peripheral edges of the slits, and the column part has a recessed part formed on the downstream surface.

A container system for liquids, including an in-container mixer/aerator in the exit throat of the container. The mixer/aerator is a cylinder, having axial peripheral grooves, and and axial central bore, divided by axial vanes.

An apparatus includes a body having a length extending from a first end to a second end. The body defines a bore extending through the entirety of the body and at least one of a plurality of grooves or holes around the bore. The body has a length that is dimensioned to be received entirely within a neck of a container.

A system and method of the purification of drinking water, ethanol and alcohol beverages is based on the action of hydrodynamic cavitation processing of microbiological and chemical contaminants, micro particles and colloidal particles. The fluid flow moves at a high rate through a multi-stage cavitation device and filtration module to generate hydrodynamic cavitation features in the fluid flow. The cavitation features generate changes in the velocity, pressure, temperature, chemical composition and physical properties of the liquid. The cavitation features also prevent the deposition of contaminants upon and remove contaminants from the surface of the filter module, reduce the load on the filter elements and increase the life of the filter module.

The present disclosure relates to a fluid path member for generating nano-bubbles, and a fluid path integrator and a nano-bubble generator that use the same. The fluid path member may be configured such that a perimeter length of a cross-section of a fluid path is greater than a cross-sectional area of the fluid path so as to maximize a friction area per volume of fluid. In addition, the fluid path member may be configured such that a single fluid path is continuously formed over several tens of meters or more without a joint. Further, the fluid path member may be configured with a high density. Accordingly, the fluid path member may have improved ability to generate the nano-bubbles. A fluid path member configured to generate nano-bubbles according to some embodiments of the present disclosure includes a body formed as a bendable single tube, wherein the body is configured such that one or more dividing walls dividing a fluid path space inside a fluid path so as to expand a surface area and a friction area of a fluid are continuously integrally formed along a flow direction of the fluid, wherein the body is formed of a soft material of any one of silicone, rubber, and soft resin material so as to be freely bent and wound, and wherein the body is manufactured by extrusion molding such that the one or more dividing walls are continuously formed in a longitudinal direction of the body.