A “fluid mixer” device that automates the mixing of multiple fluids into a base liquid and the delivery of the mixed liquid according to user-specified parameters with automatic flush-out, full logging and reporting capabilities. The device is comprised of a plurality of modules, each of which is designed for a different environmental setting: (a) the control module, the module with which the user interfaces, is normally located in a dry area, away from both line voltage electricity and fluids; (b) the power module, which supplies power to all modules, is located near 110V-230V single phase line voltage, and thus contains all of the high-voltage gear and interfaces; and (c) the flow module, the bank of controlled liquid mixers, is located in the wet area and uses only low-voltage direct current in its operation.

A system for preparing recipes with components coming from closed containers (S1-S5) provides for using one or more robotic units (1), each of which withdraws a selected container, arranging a plurality of hoppers (7.1-7.5), in each of which the withdrawn selected container is inserted by the robotic unit (1), and in each of which the container is automatically opened for loading the component into the hopper (7), discharging a preset component dose from each hopper (7), and collecting the dosed components for preparing the required recipe; a driving and control unit (15) provides for driving and controlling all of these operations as a function of the required recipe. Thereby, an automatic system for preparing recipes is achieved, which is fast, with a low processing cost, and free from risks related to the processing.

There is provided a mixing device (2) for a beverage and CO2 gas for producing carbonated beverage. The mixing device (2) having a mixing channel (4) extending in a main direction (10). The mixing channel (4) includes: wide channel sections (16) and narrow channel sections (18) along the main direction (10). The mixing channel (4) has an elongated cross section seen in a direction perpendicular to the main direction (10). At least a first delimiting surface (22) of the mixing channel (4) is provided with protrusions (20) extending at least partially along the first delimiting surface (22) in a direction across the mixing channel (4) and protruding towards a second delimiting surface (24) of the mixing channel (4) to form the narrow channel sections (18). A turbulent flow of beverage is created by the narrow and wide channel sections. Further a carbonator for producing carbonated beverage, an appliance having a carbonator, and a method of producing a carbonated beverage are provided.

The invention relates to a mixer, in particular for mixing viscous fluids, such as paints and plasters, in a container, the mixer comprising a frame, a clamping mechanism for holding a container, which mechanism is translatably and/or rotatably mounted in the frame, a motor for translatably and/or rotatably driving the clamping mechanism a sensor for measuring vibrations of the clamping mechanism, and a controller connected to the sensor and the motor and arranged to control the motor to adjust translations and/or rotations of the clamping mechanism in dependence of the measured vibrations.

Provided herein are methods and devices for identifying and/or distinguishing UCA formulations and specifically activating such formulations to produce UCA suitable for in vivo use.

The subject matter of this specification can be embodied in, among other things, a mixing system that includes a heating assembly configured to heat liquid, and a mixing assembly including a tank defining a cavity and configured to retain liquid, an inlet in fluidic communication with the cavity and configured to receive liquid from the heating assembly, a mixing impeller assembly configured to mix contents of the cavity, an actuator configured to actuate the mixing impeller assembly to mix contents of the cavity, and an outlet in fluidic communication with the cavity and having a valve configured to selectively prevent and permit egress of contents of the cavity.

An aeration device includes a housing; a pump module mounted inside the housing and configured to provide a fluid flow; a tube connector mounted inside the housing and fluidly connected to the pump module; an aerator tube configured to be attachable to the tube connector; and a gripping recess mounted inside the housing such that the aerator tube is receivable within the gripping recess. The aerator tube is configured to receive the fluid flow from the pump module and deliver the fluid flow to a liquid in a vessel. The aerator device is configured to rest on a top rim of a vessel during operation of the pump module.

A sewage system component spray assembly is attached at a predetermined height above pumps in the interior of the component and has at least one nozzle for spraying liquid downwardly and generally tangential to a center of the sewage system component. Operation of the nozzle causes the liquid to disperse floating material on the sewage surface and creating a rotational flow around the center to direct such material to the pumps.

The present invention lies in the field of automated analyzers and relates to a method for mixing liquids in liquid containers. The arrangement for automated mixing comprises a shaking device and a gripper which is connected by way of a flexible connecting element to a transfer arm and which serves for receiving a liquid container. The coupling of gripper and shaking device is realized by way of an eccentrically movable coupling pin and a coupling hole provided for this purpose.

The present disclosure provides apparatuses and methods related to a high pressure processing device that is configured to simplify batch processing. In an embodiment, a high pressure processing device includes a processing module configured to reduce a particle size of a material or achieve a desired liquid processing result for the material, a pump configured to pump the material to an inlet of the processing module, a recirculation pathway configured to recirculate the material from an outlet of the processing module back to the pump, an input device configured to receive at least one user input variable, and a controller configured to (i) determine a number of pump strokes for the pump based on the user input variable, and (ii) control the pump according to the determined number of pump strokes so that the material makes a plurality of passes through the processing module.