A fine bubble generator for generating fine bubbles in a liquid without externally introducing gas. According to an embodiment, a liquid flows in a gap between a first helical part on an inner surface of an outer member having a tubular shape and a second helical part on an outer surface of an inner member in the outer member, so that cavitation occurs because of the decrease in pressure when the liquid flows out of the gap between the first helical part and the second helical part, and fine bubbles are generated in the liquid. In this process, the liquid flowing near the inner surface of the outer member swirls along the first helical part, and the liquid flowing near the outer surface of the inner member swirls along the second helical part, and cavitation is promoted by the swirl flows, and the amount of fine bubbles generated is increased.

A nanobubbler includes a porous ceramic material, a first inlet configured to inject a gas into the porous ceramic material, wherein the porous ceramic material is configured to emit nanobubbles into the chamber from the surface in response to the injection of the gas, a chamber positioned adjacent to a surface of the porous ceramic material, a second inlet configured to inject a liquid into the chamber so that the nanobubbles are dislodged from the surface of the porous ceramic material into the liquid, and an outlet configured to output from the chamber the liquid infused with the nanobubbles. The nanobubbles infused into the liquid have an average diameter of less than 500 nanometers.

The present invention relates to a system (300), method and generator (301) for producing solvated nanoclusters of a guest substance. The method comprises providing a container (302) containing a plurality of surfaces (304) distributed therein; introducing a solvent (103) within which the solvated nanoclusters are to be generated into the container such that the solvent comes in contact with the surfaces; and distributing a fluid guest substance within the solvent, wherein the plurality of surfaces comprises random packings or structured packings or both, wherein the packings are made of or coated with (i) permanent-magnetic material or (ii) dielectric material that has a quasi-permanent electric charge or dipole polarisation.

The present invention relates to a system (300), method and generator (301) for producing solvated nanoclusters of a guest substance. The method comprises providing a container (302) containing a plurality of surfaces (304) distributed therein; introducing a solvent (103) within which the solvated nanoclusters are to be generated into the container such that the solvent comes in contact with the surfaces; and distributing a fluid guest substance within the solvent, wherein the plurality of surfaces comprises random packings or structured packings or both, wherein the packings are made of or coated with (i) permanent-magnetic material or (ii) dielectric material that has a quasi-permanent electric charge or dipole polarisation.

The present application provides a high-gravity device for generating nano/micron bubble and a reaction system. In the device, the liquid phase is continuous phase and the gas phase is dispersed phase. A gas enters the interior of the device from a hollow shaft, and the gas is subjected to primary shearing under a shearing effect of aerating micropores to form bubbles; then, the bubbles rapidly disengage from the surface of a rotating shaft under the effect of the rotating shaft rotating at a high speed, and are subjected to secondary shearing under the high-gravity environment with the strong shearing force formed by the rotating shaft to form nano/micron bubbles. The device has the advantages of fastness, stability, and small average particle size. The average particle size of the formed nano/micron bubbles is between 800 nanometers and 50 microns, and the average particle size of the bubbles can be regulated in a range by adjusting the rotating speed of the rotating shaft.

The present application provides a high-gravity device for generating nano/micron bubble and a reaction system. In the device, the liquid phase is continuous phase and the gas phase is dispersed phase. A gas enters the interior of the device from a hollow shaft, and the gas is subjected to primary shearing under a shearing effect of aerating micropores to form bubbles; then, the bubbles rapidly disengage from the surface of a rotating shaft under the effect of the rotating shaft rotating at a high speed, and are subjected to secondary shearing under the high-gravity environment with the strong shearing force formed by the rotating shaft to form nano/micron bubbles. The device has the advantages of fastness, stability, and small average particle size. The average particle size of the formed nano/micron bubbles is between 800 nanometers and 50 microns, and the average particle size of the bubbles can be regulated in a range by adjusting the rotating speed of the rotating shaft.

A system for stabilizing gas-infused liquid, includes a tubular flow path configured to receive and pass therethrough the gas-infused liquid under a pressure of at least 20 psi, wherein a surface of the flow path configured to engage the gas-infused liquid flowing through the flow path is formed of material having a surface roughness (Ra) in a range of 0.1 m-10.0 m, and the flow path has a length which is at least 100 times a mean inner diameter thereof.

A system for stabilizing gas-infused liquid, includes a tubular flow path configured to receive and pass therethrough the gas-infused liquid under a pressure of at least 20 psi, wherein a surface of the flow path configured to engage the gas-infused liquid flowing through the flow path is formed of material having a surface roughness (Ra) in a range of 0.1 m-10.0 m, and the flow path has a length which is at least 100 times a mean inner diameter thereof.

An air-water current purifying device allows the size of the bubbles from the mixture to be reduced includes an inlet for the air-water mixture; a first filter occupying the cross-section of the device, with a plurality of holes; a first expansion chamber after the first filter; a second filter with the same characteristics and arrangement as the first filter and located after the first expansion chamber; a second expansion chamber after the second filter; a third filter after the second expansion chamber, with the same features and arrangement as the first and second filters; a third expansion chamber after the third filter; a pressure-regulating valve arranged at the outlet of the device; and a regulating flywheel that allows the valve to be closed and opened.

An air-water current purifying device allows the size of the bubbles from the mixture to be reduced includes an inlet for the air-water mixture; a first filter occupying the cross-section of the device, with a plurality of holes; a first expansion chamber after the first filter; a second filter with the same characteristics and arrangement as the first filter and located after the first expansion chamber; a second expansion chamber after the second filter; a third filter after the second expansion chamber, with the same features and arrangement as the first and second filters; a third expansion chamber after the third filter; a pressure-regulating valve arranged at the outlet of the device; and a regulating flywheel that allows the valve to be closed and opened.