The present disclosure provides methods for manufacturing a shelf-stable food product. In a general embodiment, the methods include acoustically mixing the food product with an acoustic mixing device during thermal processing of the food product. The methods of the present disclosure provide several advantages including, but not limited to, rapid achievement of a uniform temperature distribution during thermal processing, retention of nutrient content and organoleptic properties of the food product, and retention of particle integrity in the food product during and after mixing.

Gas hydrate slurry formation systems are provided. The gas hydrate slurry formation system includes a cavitation chamber configured to receive a fluid and a cavitation device placed within the cavitation chamber. The cavitation device is configured to form a plurality of bubbles within the fluid in the cavitation chamber. The gas hydrate slurry formation system also includes a gas inlet configured to introduce a gas within the cavitation chamber such that the gas is entrained in the plurality of bubbles to form a plurality of gas-entrained bubbles. The plurality of gas-entrained bubbles implode within the cavitation chamber to form a gas hydrate slurry.

Devices, systems and methods including a sonicator for sample preparation are provided. A sonicator may be used to mix, resuspend, aerosolize, disperse, disintegrate, or de-gas a solution. A sonicator may be used to disrupt a cell, such as a pathogen cell in a sample. Sample preparation may include exposing pathogen-identifying material by sonication to detect, identify, or measure pathogens. A sonicator may transfer ultrasonic energy to the sample solution by contacting its tip to an exterior wall of a vessel containing the sample. Multipurpose devices including a sonicator also include further components for additional actions and assays. Devices, and systems comprising such devices, may communicate with a laboratory or other devices in a system for sample assay and analysis. Methods utilizing such devices and systems are provided. The improved sample preparation devices, systems and methods are useful for analyzing samples, e.g. for diagnosing patients suffering from infection by pathogens.

In the field of automatic analyzers, as items to be analyzed are increase, various reagents differing in such properties as liquid viscosity and contact angle are being used more frequently, and this trend is expected to continue. Also, reagents now take various forms (e.g., a concentrated reagent to be diluted by the water of an automatic analyzer), and so does dilution water. Such being the case, the invention provides an automatic analyzer capable of sufficient stirring regardless of items to be analyzed. To sufficiently stir a substance to which a reagent has been added, the automatic analyzer is designed to alter stirring conditions after a given amount of time has passed since the addition of that reagent.

An ionic liquid can disperse graphene at a high concentration. The ionic liquid can be represented by general formula (1): ##STR00001##
in which R.sub.1 and R.sub.5 may be the same or different and each independently represents a substituted or unsubstituted C1-7 linear or branched alkyl group; R.sub.2 is represented by formula (2): ##STR00002##
in which R.sub.6 and R.sub.7 may be the same or different and each independently represents a C1-4 linear or branched alkylene group, and m represents an integer of 1-5; R.sub.3 and R.sub.4 may be the same or different and each independently represent a hydrogen atom, substituted or unsubstituted C1-4 linear or branched alkyl group; X.sup. represents a counter ion; and n represents 0-30.

Device for shaking, within a rigid container, a powder and liquid, for conducting a test on the shaken content, includes: a frame; a first plate assembled thereto; a second plate assembled indirectly to the frame, arranged close to the first plate and movable relative to the frame and first plate; and a drive unit for moving the second plate relative to the frame and first plate. The container is carried by the second plate and is movably mounted relative thereto; the first plate includes a stop fixedly mounted on the first plate; and the second plate is moved relative to the first plate by the drive unit, in an alternating and periodic translational and/or rotational motion between a proximal position and a distal position, to move the container relative to the second plate and cause a series of impacts between the container and the stop to achieve a non-periodic shaking.

A nanobubble-producing apparatus includes a liquid vat provided with a bubble-containing-liquid inlet in an upper part thereof and a bubble-containing-liquid outlet in a bottom part thereof, a microbubble-containing-liquid supply unit to supply microbubble-containing liquid that contains microbubbles to the bubble-containing-liquid inlet of the liquid vat, an ultrasonic collapse unit to radiate ultrasonic waves to the inside of the liquid vat so that an ultrasonic collapse field in which the collapsing of the microbubbles with the ultrasonic waves is concentrated and nanobubbles are generated is formed at a location where the microbubble-containing liquid supplied into the liquid vat through the bubble-containing-liquid inlet flows downward, and a nanobubble-containing-liquid extraction portion where the nanobubble-containing liquid that contains the nanobubbles generated by the ultrasonic collapse unit is taken out of the liquid vat through the bubble-containing-liquid outlet.

A flow-through cavitation device having an elongated housing with an inlet and an outlet. One or more variable multi-jet nozzles are disposed throughout the elongated housing with a working chamber following each variable multi-jet nozzle. Each variable multi-jet nozzle consists of a movable disk fixedly mounted on a central shaft and a stationary disk fixedly mounted on the housing and in contact with the rotating disk. The movable and stationary disks of each variable multi-jet nozzle have through channels. The flow cross-sectional area of the through channels is variable by rotating the movable disk relative to the stationary disk.

To provide a reactor to improve evenness in the thickness of shell metals coated on the surface of core particles by increasing area sizes in the reactor chamber to control electric potentials, the present invention is configured to comprise a top surface able to move up and down while serving as a working electrode, a wall serving as a working electrode, a bottom surface, a standard electrode, a power supplying part and a solution injecting part, wherein the top surface can move up and down automatically by an electric motor or manually. Also, the top surface is configured to be suitable for the interior diameter of the reactor chamber, for solutions inside the reactor chamber not to leak from the top surface or from the crevice between the top surface and the wall of the reactor chamber. The bottom surface of the reactor chamber may comprise an impeller or an ultrasonic wave diffuser to bring about even diffusion in the reactor chamber.

A batch or continuous mixer for mixing powders, immiscible liquids, or a powder with a liquid includes one or more vibrational energy applicators which propagate vibrational energy into the mixture, causing powders to flow like liquids and breaking up liquid droplets and powder clumps. In embodiments, the vibration frequency and amplitude are selected according to properties of the mixture components. Vibrations can be propagated through container walls, impellers, or other structures within the mixing container. Vibrated structures can be flexibly supported for enhanced propagation of the vibrations. Vibrational energy can be uniform throughout the container, or focused in a desired region. Ultrasonic energy can be simultaneously applied with acoustic energy.