A generating method for generating one of mist and fine-bubbles or fine-bubbles is provided. The generating method includes arranging a piezoelectric substrate equipped thereon with an excitation source in a liquid, generating a flow of the liquid using a liquid flow generator that generates the flow of the liquid relative to the piezoelectric substrate, exciting a surface acoustic wave on the excitation source, propagating the excited surface acoustic wave so as to generate mist on a gas side and to generate fine-bubbles on a liquid side of the piezoelectric substrate, carrying the generated fine-bubbles away from the piezoelectric substrate with the generated flow of the liquid, and drawing the liquid containing the fine-bubbles from a liquid container which contains the liquid.

A method for producing an ultrafine-bubble-containing liquid includes: supplying a liquid containing at least one substance selected from a group stated below to a liquid supply region where an ejection orifice forming member in which an ejection orifice with a minute diameter is formed is disposed; and ejecting the liquid from the ejection orifice as a droplet by causing a pressure application unit in contact with the liquid to apply pressure to the liquid supplied to the liquid supply region. The group consists of a thermally denaturing material, inorganic salts, amino acids and their salts, carbohydrates/sugars and their salts, organic polymers and their salts, inorganic polymers and their salts, a dispersion, and an organic liquid.

Provided are a device for generating an ozone-containing UFB liquid and a method for generating the ozone-containing UFB liquid, which enable the generation of the ozone-containing UFB liquid that can be stored long-term at a high concentration. To this end, an ultrafine bubble liquid containing ultrafine bubbles is generated by applying energy to a liquid and ejecting the liquid from an ejecting port having a small diameter, and the generated ultrafine bubble liquid is irradiated with ultraviolet ray.

The present disclosure is generally related to systems and methods for producing liquid extracts from a solid raw material, as well as related equipment. Certain aspects are related to the production of multiple liquid extract products using a single system by adjusting one or more displaceable fluidic pathway segments within the system to switch between first and second (or more) extraction configurations. In certain embodiments, a first liquid extract can be produced when the displaceable fluidic pathway segment is in a first configuration, and a second liquid extract (different from the first liquid extract) can be produced when the displaceable fluidic pathway segment in in a second configuration (different from the first configuration).

The present disclosure is generally related to systems and methods for producing liquid extracts from a solid raw material, as well as related equipment. Certain aspects are related to the production of multiple liquid extract products using a single system by adjusting one or more displaceable fluidic pathway segments within the system to switch between first and second (or more) extraction configurations. In certain embodiments, a first liquid extract can be produced when the displaceable fluidic pathway segment is in a first configuration, and a second liquid extract (different from the first liquid extract) can be produced when the displaceable fluidic pathway segment in in a second configuration (different from the first configuration).

A bioFET device includes a semiconductor substrate having a first surface and an opposite, parallel second surface and a plurality of bioFET sensors on the semiconductor substrate. Each of the bioFET sensors includes a gate formed on the first surface of the semiconductor substrate and a channel region formed within the semiconductor substrate beneath the gate and between source/drain (S/D) regions in the semiconductor substrate. The channel region includes a portion of the second surface of the semiconductor substrate. An isolation layer is disposed on the second surface of the semiconductor substrate. The isolation layer has an opening positioned over the channel region of more than one bioFET sensor of the plurality of bioFET sensors. An interface layer is disposed on the channel region of the more than one bioFET sensor in the opening.

An apparatus for preparing compound dispersoids of hydrophobic nanoparticles and surfactants, comprises a water supply pipeline, a compounding mixing pipeline and an aggregating pipeline; the compounding mixing pipeline comprises an ultrasonic dispersion instrument and a liquid storage tank connected in series into a loop, and a second plunger pump allowing unidirectional circulation of materials is arranged between the ultrasonic dispersion instrument and the liquid storage tank; the water supply pipeline is connected to the top of the ultrasonic dispersion instrument; and the aggregating pipeline is connected to a discharge end of the liquid storage tank.

A device for producing a concrete includes a cement premixer for mixing a cement suspension, the cement premixer having an ultrasonic probe for preparing a cement suspension, a crystallization tank arrangement with the first crystallization tank, for increasing the early strengths of the concrete, and a concrete mixer for producing a concrete mixture from the premixed cement suspension, in particular with the addition of aggregates.

A device for producing a concrete includes a cement premixer for mixing a cement suspension, the cement premixer having an ultrasonic probe for preparing a cement suspension, a crystallization tank arrangement with the first crystallization tank, for increasing the early strengths of the concrete, and a concrete mixer for producing a concrete mixture from the premixed cement suspension, in particular with the addition of aggregates.

An ultrasonic system for homogenizing a sample includes an ultrasonic transducer and a control system. The transducer includes a horn or other probe that oscillates to produce cavitation in the sample and a converter that drives the horn through its oscillatory motion. The control system includes a closed-loop amplitude-control configuration and process. In particular, the control system includes a user interface, a controller, and a high-frequency driver, all connected together in a closed-loop configuration for enabling amplitude-control feedback. Control software includes programming for the closed-loop amplitude-control process including receiving a user-inputted desired amplitude of oscillatory horn motion, driving the transducer at a corresponding power level, determining the actual amplitude of oscillatory horn motion, and automatically adjusting the power level to the transducer to maintain the desired amplitude during operation of the ultrasonic system.