The present disclosure relates to a method for storage or transportation of graphene oxide. The method for storage or transportation of graphene oxide comprises the steps of: carrying out wet spinning of a graphene oxide spinning solution to a coagulating bath to obtain graphene oxide pellets; drying the obtained graphene oxide pellets; storing or transporting the dried graphene oxide pellets; and redispersing the stored or transported graphene oxide pellets.

A method of producing lipid-based micro/nano bubbles includes steps of (a) preparing a lipid mixture including one or more first lipids with different phase transition temperature, and a second lipid bonding with a hydrophilic polymer moiety or molecules capable of getting across a lipid membrane and decreasing van der Waals forces between lipid bilayers; (b) emulsifying the lipid mixture with a solvent, to form a transparent lipid carrier solution; (c) placing the transparent lipid carrier solution in a closed vessel with halo-substituted hydrocarbon; (d) manipulating temperature of the transparent lipid carrier solution to be close to a main phase transition temperature thereof; and (e) agitating in a mechanical manner the vessel containing the transparent lipid carrier solution to form micro/nano bubbles within the closed vessel. This method contributes to form micro/nano bubbles with desired diameters in a way of optimal material utilization efficiency.

A mixing apparatus includes a phosphoric acid aqueous solution supply, an additive supply, a tank, a phosphoric acid aqueous solution supply path and an additive supply path. The phosphoric acid aqueous solution supply is configured to supply a phosphoric acid aqueous solution. The additive supply is configured to supply an additive configured to suppress precipitation of a silicon oxide. The phosphoric acid aqueous solution supply path is configured to connect the phosphoric acid aqueous solution supply with the tank. The additive supply path is configured to connect the additive supply with the tank. The additive is supplied while fluidity is imparted to the phosphoric acid aqueous solution supplied from the phosphoric acid aqueous solution supply into the tank.

Devices, systems, and their methods of use, for generating droplets are provided. One or more geometric parameters of a microfluidic channel can be selected to generate droplets of a desired and predictable droplet size.

Devices, systems, and their methods of use, for generating droplets are provided. One or more geometric parameters of a microfluidic channel can be selected to generate droplets of a desired and predictable droplet size.

Acoustofluidic systems including acoustic wave generators for manipulating fluids, droplets, and micro/nano objects within a fluid suspension and related methods are disclosed herein. According to an aspect, an acoustofluidic system includes a substrate including a substrate surface. The system also includes an acoustic wave generator configured to generate acoustic streaming within an acoustic wave region of the substrate surface. Further, the acoustic wave generator is controllable to change the acoustic streaming for movement of a droplet or other micro/nano object on a fluid suspension about the acoustic wave region.

Increased control and efficiency over the wastewater purification can be achieved through creating conditions that allow the operator to selectively prioritize the digestive function of microorganism in the activated sludge. The gas-dispersion return sludge is created using pure oxygen or oxygen containing trace amounts of ozone as a reactive gas, which is blended with return sludge to create a mixture of gas and liquid, which is passed through an atomizer or a cavitation pump to instantly render the reactive gas to an ultra-fine bubble state. At least a portion of the ultra-fine bubbles dissolve within the gas-dispersion return sludge, activating the dormant microorganisms. Due to a complete or an almost complete absence of biodegradable material in the gas-dispersion return sludge, the microorganism prioritize their digestive function, and when exposed to biodegradable pollutants present in wastewater, digest the pollutants using biochemical pathways different from the ones used in nature.

A system for continuously processing materials. The system includes a continuous process vessel (CPV) and an acoustic agitator coupled to the CPV and configured to agitate the CPV along an oscillation axis. The CPV includes at least one inlet configured for introducing first and second process ingredients into an upper portion, with respect to the oscillation axis, of the CPV. The CPV includes an outlet for discharging the product of mixing the ingredients from a lower portion, with respect to the oscillation axis, of the CPV. The CPV includes a plurality of mixing regions, each defined by an upper angled surface and a lower angled surface. The surfaces of each mixing region are angled such that the distance between the surfaces is greater towards the upper portion of the continuous process vessel than the distance between the surfaces towards the lower portion of the continuous process vessel.

A cold brew coffee extraction device for adjusting the sonic vibration based on the sound signal includes: a current support extended in one direction and configured to apply an alternating current in a tangential direction of an outer peripheral portion; a magnetic vibrator accommodating one end of the current support therein, and configured to generate a magnetic field in a direction of crossing over the current support to be vibrated in a longitudinal direction of the current support due to a change in a polarity of the alternating current; a plate coupled to the magnetic vibrator to transmit the vibration to a fluid including a particulate matter; and a vibration adjustment circuit configured to, in a first mode, adjust the vibration only based on setting information inputted through a user interface, and in a second mode, to adjust the vibration based on the setting information and an external sound source.

Disclosed are mixing apparatus adapted to provide mixing of components in an automated analyzer. The mixing apparatus includes a reservoir configured to contain a coupling liquid, a transducer configured to be driven at a frequency and communicate with the coupling liquid, and a signal generation unit configured to provide a phase modulatable drive signal to the transducer. In some embodiments, improved patient sample and reagent mixing may be provided. Systems and methods are provided, as are other aspects.