The present invention pertains in general to an apparatus and method for the drying and activating of infusing material, and the infusing, agitation and dispensation of oils in a controlled manner to produce a desired potency of an infusion while remaining below an identified maximum temperature threshold.

An analyte identifying and sorting apparatus for sorting a target analyte based on an identification result of analytes dispersed in a liquid. The apparatus includes an identification unit including an analyte storage section configured to store analytes dispersed in a liquid, a pressure control section configured to feed the liquid to a flow path provided to extend downward from the analyte storage section, a light irradiation section configured to irradiate light to the analytes, an optical information measurement section measuring optical information of the analytes, and a determination section determining whether the analyte is a target analyte or a non-target analyte based on the optical information. Also included is a sorting unit that includes a sorting nozzle connected to the identification unit and sorts a sorted solution containing the target analyte to the vessel, an effluent collection section having a suction nozzle to suck and collect an effluent involving an effluent discharged from a tip of the sorting nozzle, and a collection vessel configured to collect the sorted solution containing the target analyte. A moving unit moves the sorting nozzle and/or the collection vessel, a control unit moves the sorting nozzle and/or the collection vessel based on the optical information, and a stirring unit including a stirring member in an inner space of the analyte storage section.

In accordance with aspects and embodiments, a magnetically driven liquid dispersion device is provided comprising a rotor, a funnel, and a rotary sprayer. The rotor is received by the funnel comprises an Archimedes screw and at least one diametric rotor magnet. The sprayer receives the funnel and comprises at least one diametric sprayer magnet. Application of an external rotating magnetic field generated by, for example, magnetic stirrer, causes the rotor to rotate within the funnel. Rotation of the rotor causes rotation of the sprayer about the funnel.

A novel device for frothing milk is disclosed. The frothing device preferably includes a rotatable impeller and a screen disposed about the bottom of the impeller downstream of milk being pushed by the impeller. The frothing device may further include a pitcher and a base upon which the pitcher sits wherein the base includes a heater. The pitcher includes a magnetic drive capable of turning the impeller at very high speeds. The impeller is positioned off-center within the pitcher that preferably includes a tapered interior. The structure of the device and programs that adjust the speed of rotation of the impeller permit the user to create bubbles and further break the bubbles down into a silky smooth microfoam without the conventional use of a steam wand or other such device and without the skills of a professional barista.

According to various implementations, the bioreactor system includes a bioreactor vessel, an impeller for stirring contents within the vessel, a temperature control source for controlling the temperature of the contents of the vessel, an aeration system for supplying air to the vessel, and one or more data loggers. According to certain implementations, the impeller is a novel impeller design that spins more smoothly and rapidly than known impellers. In addition, the bioreactor system is modular, durable, and relatively inexpensive compared to existing bioreactor systems, which allows for bench-scale implementation, use with differently sized bioreactor vessels, and accessibility to more educational programs, according to some implementations.

A device for frothing milk preferably includes a rotatable impeller and a screen disposed about the bottom of the impeller downstream of milk being pushed by the impeller. The frothing device may further include a pitcher and a base upon which the pitcher sits wherein the base includes a heater. The pitcher includes a magnetic drive capable of turning the impeller at very high speeds. The impeller is positioned off-center within the pitcher that preferably includes a tapered interior. The structure of the device and programs that adjust the speed of rotation of the impeller permit the user to create bubbles and further break the bubbles down into a silky smooth microfoam without the conventional use of a steam wand or other such device and without the skills of a professional barista.

A beverage machine system that includes: an insulated potable liquid storage tank having an interior volume; a liquid carbonator spaced within the interior volume of the insulated potable liquid storage tank and submerged therein; a high pressure potable liquid pump configured to pump potable liquid from the interior volume of the insulated potable liquid storage tank through a potable liquid conduit to a spray nozzle within an interior volume of the liquid carbonator; and a cooling coil positioned in a spaced apart relationship but wound around the carbonator such that the cooling coil does not physically touch an exterior surface of the carbonator submersed within the chilled potable liquid and the space between the cooling coil and the carbonator is at least substantially free of any other structure other than periodic frozen potable liquid adjacent the cooling coil.

Devices for carbonating drinking water are disclosed. The devices include a container that is configured to hold a volume of carbonated drinking water; a CO.sub.2 gas supply line that is configured to deliver CO.sub.2 gas to the volume of carbonated drinking water within the container; and a variable speed electric motor located outside of and adjacent to an external surface of the container. In addition, the devices include a turbine type impeller that is magnetically coupled to and driven by the variable speed electric motor. The turbine type impeller is configured to rotate at variable speeds and spray carbonated drinking water transferred from a bottom portion of the container into an air space located above the volume of carbonated drinking water and the top internal surface of the container.

Disclosed are a method for stirring milk powder solution and a stirring type feeding-bottle. The method comprising: driving a counterweight head (24) and a flexible straw (23) to revolve by a drive device (12). The stirring type feeding-bottle includes a feeding-bottle assembly (2) comprising a feeding-bottle (21), a nipple subassembly (22), a flexible straw (23) and a counterweight head (24). The counterweight head (24) is connected to a lower end of the flexible straw (23). The stirring type feeding-bottle further comprises a drive device (12) for driving the flexible straw (23) and the counterweight head (24) to revolve. A gap is formed between the counterweight head (24) and an inner bottom surface of the feeding-bottle (21). The stirring type feeding-bottle achieves automatic stirring, reduces the generation of bubbles in the stirring process, and improves the uniformity of stirring and facilitates feeding.

Provided is a mixing device that is configured to install therein a multi-well plate including a plurality of wells capable of containing matter to be mixed and includes mixing mechanisms each of which mixes the matter to be mixed with a motor and is provided for each of the wells. The mixing mechanisms each includes a first rotator that is connected to the motor and rotates due to activation of the motor, a mixing rod that mixes the matter to be mixed, a second rotator that supports the mixing rod, a magnetic coupling mechanism that magnetically couples the first rotator to the second rotator, and a seal ring that surrounds an opening of the well and is capable of closing the well together with the second rotator.