A fluid mixing device is provided with a plurality of flow channel units disposed to be divided in a plurality of layers. Each of the flow channel units has an inflow port, an outflow port, and a plurality of branch flow channels making the inflow port and the outflow port communicate with each other. The flow channel units located in different layers are connected to each other at the inflow port and the outflow port between the flow channel units, thereby configuring a three-dimensional flow channel as a whole. When the direction from the inflow port to the outflow path of each flow channel unit is set to be a flow direction in the flow channel unit, the flow directions intersect each other between the respective layers.

A static spray mixer for the mixing and spraying of at least two flowable components is proposed having a tubular mixer housing (2) which extends in the direction of a longitudinal axis (A) up to a distal end (21) which has an outlet opening (22) for the components, having at least one mixing element (3) arranged in the mixer housing (2) for the mixing of the components as well as having an atomization sleeve (4) which has an inner surface which surrounds the mixer housing (2) in its end region, wherein the atomization sleeve (4) has an inlet channel (41) for a pressurized atomization medium, wherein a plurality of grooves (5) are provided in the outer surface of the mixer housing (2) or in the inner surface of the atomization sleeve (4) which respectively extend toward the distal end and which form separate flow channels (51) between the atomization sleeve (4) and the mixer housing (2) through which the atomization medium can flow from the inlet channel (41) of the atomization sleeve (4) to the distal end (21) of the mixer housing (2). The inlet channel (41) is arranged asymmetrically with respect to the longitudinal axis (A).

A valvular conduit, preferably a Tesla valvular conduit, in which a plug member is coaxially received within a bore in a sleeve member and in which passageways are defined between the plug member and the sleeve member within interior walls configured to permit mixing of fluid flowing through the passageways in at least one direction, preferably, the relatively free passage of fluid through the passageways upstream but increased the resistance to downstream flow of the fluid through each passageway.

A static mixer including a housing, a first inlet channel, a second inlet channel, a first outlet channel aligned with the first inlet channel along a first axis, and a second outlet channel aligned with the second inlet channel along a second axis. The static mixer also includes a first opening between the first inlet channel and the second outlet channel, and a second opening between the second inlet channel and the first outlet channel.

A mixing element for a static mixer for installation into a tubular mixer housing has a longitudinal axis along which a plurality of installation bodies are arranged behind one another. A first installation body has a first wall element which extends in the direction of the longitudinal axis and a first side wall and a second side wall which is arranged opposite the first side wall. A deflection element is arranged adjacent to the first wall element and has a deflection surface extending in the transverse direction to the wall element at both sides of the wall element. A first opening is provided in the deflection surface at the side which faces the first side wall of the first wall element.

A static mixer includes at least one flow inverter baffle. The flow inverter baffle includes a first dividing panel to divide the fluid flow into a first flow portion adjacent a first side of the first dividing panel and a second flow portion adjacent a second side of the first dividing panel. The flow inverter baffle also includes a dividing element to divide the second flow portion into first and second perimeter flow portions. Additionally, first, second and third inversion elements to invert the flow layers of the at least two components by shifting the fluid flow to a different portion of a flow cross-section within the mixer while maintaining the general orientation of the flow layers as the fluid flow moves progresses through the flow inverter baffle. The flow inverter baffle also reduces backpressure by limiting the total amount of movement to cause the inversion.

A mixing segment for a static mixer has one inlet section, one outlet section disposed opposite of the inlet section, and a longitudinal axis being defined between the inlet section and the outlet section. The mixing segment further has a plurality of first passages, each first passage adjoining the inlet section and being arranged radially with respect to the longitudinal axis, and at least one second passage adjoining the outlet section and being arranged radially with respect to the longitudinal axis. Said first passages are in fluid connection the second passage with flow paths being defined between said inlet section, said first passages, said second passage and said outlet section.

A valvular conduit, preferably a Tesla valvular conduit, in which a plug member is coaxially received within a bore in a sleeve member and in which passageways are defined between the plug member and the sleeve member within interior walls configured to permit mixing of fluid flowing through the passageways in at least one direction, preferably, the relatively free passage of fluid through the passageways upstream but increased the resistance to downstream flow of the fluid through each passageway.

The present disclosure relates to a mixer for mixing pasty components, comprising a mixing case extending along a longitudinal axis and having at least one inlet, preferably two inlets, and an outlet, and comprising at least one mixing element received in the mixing case, which defines a plurality of chambers together with the mixing case, said chambers being arranged successively and/or adjacently along a flow path from the inlets to the outlet. The chambers are defined by transverse walls, each extending perpendicularly to the longitudinal axis, and four side walls that each extend parallel to the longitudinal axis, and adjacent chambers are interconnected by a flow by means of through-openings provided in the side walls, the mixing element comprising two strips forming side walls, which are connected by a web that forms other side walls and is perpendicularly arranged in relation to the strips, a first group of chambers having first through-openings arranged in the web, which extend up to a strip, and a second group of chambers comprising second through-openings positioned at a distance to at least one strip in the web.

A fluid mixer includes a flow splitter and a mixing chamber. The flow splitter includes an inlet for receiving a flow of fluid and is configured to split the flow of fluid into first and second fluid streams. The second fluid stream has a higher density than the first fluid stream. The mixing chamber includes a first inlet, a second inlet and a mixing well. The second inlet is positioned below the first inlet. The second inlet of the mixing chamber is configured to receive the first fluid stream and the first inlet of the mixing chamber is configured to receive the second fluid stream to promote mixing of the first and second streams in the mixing well.