In remotely rendering chemical signatures, a remote request received from a user comprises a requesting user identifier, a substrate specification, and a chemical signature. The chemical signature includes identifiers for one or more chemicals comprising a selected set of chemicals, and for each identified chemical at least a quantity of the selected set of chemicals. The received remote request is directed to a chemical printer that prints chemicals on the substrate based at least on the chemical signature. The printed substrate may be tagged with a predetermined digital tag format based at least on the requesting user identifier.

An apparatus (100) for mixing a fluid (F) comprises a mixing container (10) with a container wall (11) for holding the fluid (F). One or more acoustic transducers (21, 22) are arranged on the container wall (11) and configured to generate respective acoustic waves (W1, W2) directed into the fluid (F) for causing a respective flow pattern (F1, F2) in the fluid (F) by acoustic streaming. A controller (15) is configured to control the acoustic transducers (21, 22) to automatically switch between generation of different acoustic waves (W1, W2) for causing switching between different flow patterns (F1, F2).

A system for recalculating a formula previously used in preparing a mixture made from adding at least two components. The system includes a control system and salon management software. The control system has a processor, a computer-readable memory, and a display. The memory contains software configured to receive a formula defining instructions for blending a hair dye mixture using one or more blending materials and amounts recommended for the hair dye mixture. The salon management software is stored in the computer-readable memory and executed by the control system. The salon management software is in communication with the control system to exchange information on customers and formulas of hair dye mixtures associated with the customers.

A fluid mixing system includes a support housing having an interior surface bounding a chamber. A flexible bag is disposed within the chamber of the support housing, the flexible bag having an interior surface bounding a compartment. An impeller is disposed within the chamber of the flexible bag. A drive shaft is coupled with the impeller such that rotation of the drive shaft facilitates rotation of the impeller. A drive motor assembly is coupled with the draft shaft and is adapted to rotate the drive shaft. An adjustable arm assembly is coupled with the drive motor assembly and is adapted to move the drive motor assembly which in turn moves the position of the drive shaft and impeller. An electrical controller can control movement of the adjustable arm.

A method for operating a shaking machine, in particular for optimizing an operating state of the shaking machine, including shaking at least one shaking material in at least one shaking vessel; setting at least one target operating parameter to at least one target value or one target range; detecting an adjustment range of at least one additional operating parameter; determining an operating state by means of an optimizer that varies at least one adjustable operating parameter and by using at least one model, such that at least one target operating parameter maintains, achieves, or approaches the target value or target range, wherein at least one operating state of the shaking machine is imaged by at least one model.

A laboratory device (4, 9), in particular a magnetic stirrer, comprises at least one adjustable operating parameter for controlling at least one laboratory device function, and an outer housing (2). The outer housing (2) has a coupling device (11a, 11b) for coupling the laboratory device (4, 9) to at least one further laboratory device (5, 9) for the same at least one laboratory device function, at which further laboratory device the at least one operating parameter can also be adjusted, and the coupling device (11a, 11b) is configured such that by means of the coupling device (11a, 11b) the laboratory device (4, 9) and the at least one further laboratory device (5, 9) can be operated simultaneously and by means of a common adjustment device the at least one operating parameter can be adjusted in a central manner independently and/or consistently for the laboratory device (4, 9) and the at least one further laboratory device (5, 9).

Mixing device (1) and fluid mixing method, by means of successive transfers between syringes. The mixing method comprises placing a pair of syringes (2, 3) in the mixing device (1), adjusting a variable fixing element adaptable to the pair of syringes (2, 3) and selecting and running a mixing programme, being the mixing force, the speed and the range and the number of transfers adjustable. The mixing device comprises a mobile carriage (7) longitudinally movable and fixing elements (8, 9) with an adjustable distance between them. The invention allows for the mixing or emulsifying of blood fluids with different viscosity, particularly a protein gel and a platelet-rich plasma, for the preparation of dermatological formulations, in a versatile, hygienic and effective manner.

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.

A fluid mixing system includes a support housing having an interior surface bounding a chamber. A flexible bag is disposed within the chamber of the support housing, the flexible bag having an interior surface bounding a compartment. An impeller is disposed within the chamber of the flexible bag. A drive shaft is coupled with the impeller such that rotation of the drive shaft facilitates rotation of the impeller. A drive motor assembly is coupled with the draft shaft and is adapted to rotate the drive shaft. An adjustable arm assembly is coupled with the drive motor assembly and is adapted to move the drive motor assembly which in turn moves the position of the drive shaft and impeller. An electrical controller can control movement of the adjustable arm.

A system includes a recirculation line, a mainline flow meter operable to measure a flowrate of fluid flowing through the recirculation line, a mixing chamber, an inlet line coupled between the recirculation line and the mixing chamber, at least one chemical injection port coupled to the inlet line, a dedicated feed pump operably associated with each chemical injection port, and an outlet line coupled between the mixing chamber and the recirculation line. The mixing chamber includes a plurality of mixing zones, a mixing blade assembly that includes at least one blade within each mixing zone, and a motor coupled to the mixing blade assembly and operable to rotate the mixing blade assembly. Each of the dedicated feed pumps is coupled to a separate chemical supply and is operable to pump a chemical to the corresponding chemical injection port for injection into the inlet line.