Abstract: Water is mixed with a hydrate-forming fluid (gas or liquid) within a pressurized, temperature-controlled continuous-flow reactor. Intense mixing of the hydrate-forming fluid with water forms many hydrate-encased water droplets of hydrate-forming fluid which are then allowed to consolidate into a solid-like hydrate/hydrate-forming fluid/water material.

Abstract: A liquid CO2 injection system produces a negatively buoyant consolidated stream of liquid CO2, CO2 hydrate, and water that sinks upon release at ocean depths in the range of 700-1500 m. In this approach, seawater at a predetermined ocean depth is mixed with the liquid CO2 stream before release into the ocean. Because mixing is conducted at depths where pressures and temperatures are suitable for CO2 hydrate formation, the consolidated stream issuing from the injector is negatively buoyant, and comprises mixed CO2-hydrate/CO2-liquid/water phases. The “sinking” characteristic of the produced stream will prolong the metastability of CO2 ocean sequestration by reducing the CO2 dissolution rate into water. Furthermore, the deeper the CO2 hydrate stream sinks after injection, the more stable it becomes internally, the deeper it is dissolved, and the more dispersed is the resulting CO2 plume.

Abstract: A device for electrohydrodynamically (EHD) mixing fluids includes a mixing channel, the mixing channel having at least one supply channel fluidicly connected thereto for transport of fluid into the mixing channel. At least two electrodes are provided, at least one of the electrodes for charging at least a portion of the fluid in the mixing channel. The electrodes impose an electric field in the mixing channel to induce EHD mixing of the fluid in the mixing channel. A method for EHD mixing of fluids applies an electric field to a mixing channel to induce EHD mixing.

Abstract: A liquid CO2 injection system produces a negatively buoyant consolidated stream of liquid CO2, CO2 hydrate, and water that sinks upon release at ocean depths in the range of 700-1500 m. In this approach, seawater at a predetermined ocean depth is mixed with the liquid CO2 stream before release into the ocean. Because mixing is conducted at depths where pressures and temperatures are suitable for CO2 hydrate formation, the consolidated stream issuing from the injector is negatively buoyant, and comprises mixed CO2-hydrate/CO2-liquid/water phases. The “sinking” characteristic of the produced stream will prolong the metastability of CO2 ocean sequestration by reducing the CO2 dissolution rate into water. Furthermore, the deeper the CO2 hydrate stream sinks after injection, the more stable it becomes internally, the deeper it is dissolved, and the more dispersed is the resulting CO2 plume.

Abstract: The present invention is directed to the effects of applied electric fields on liquid-liquid dispersions. In general, the present invention is directed to the control of phase inversions in liquid-liquid dispersions. Because of polarization and deformation effects, coalescence of aqueous drops is facilitated by the application of electric fields. As a result, with an increase in the applied voltage, the ambivalence region is narrowed and shifted toward higher volume fractions of the dispersed phase. This permits the invention to be used to ensure that the aqueous phase remains continuous, even at a high volume fraction of the organic phase. Additionally, the volume fraction of the organic phase may be increased without causing phase inversion, and may be used to correct a phase inversion which has already occurred. Finally, the invention may be used to enhance mass transfer rates from one phase to another through the use of phase inversions.

Abstract: The present invention relates to methods and apparatus that employ electrohydrodynamic flows in miscible, partially miscible and immiscible multiphase systems to induce mixing for dissolution and/or reaction processes.

Abstract: The present invention relates to a method for the rapid production of homogeneous, ultrafine inorganic material via liquid-phase reactions. The method of the present invention employs electrohydrodynamic flows in the vicinity of an electrified injector tube placed inside another tube to induce efficient turbulent mixing of two fluids containing reactive species. The rapid micromixing allows liquid-phase reactions to be conducted uniformly at high rates. This approach allows continuous production of non-agglomerated, monopispersed, submicron-sized, sphere-like powders.

Abstract: A method and apparatus to electrolytically produce high-purity magnetite particles is provided. The apparatus comprises a container for holding an electrolytic solution. In accordance with one embodiment, the electrolytic solution includes sodium chloride and deionized water. A pair of carbon steel electrodes are submerged within the electrolytic solution. A d.c. power supply is also provided to apply a voltage to the electrodes for a period of time sufficient to produce the magnetite particles.

Abstract: A method for use in electrically forming dispersions of a nonconducting fluid in a conductive medium that minimizes power consumption, gas generation, and sparking between the electrode of the nozzle and the conductive medium. The method utilizes a nozzle having a passageway, the wall of which serves as the nozzle electrode, for the transport of the nonconducting fluid into the conductive medium. A second passageway provides for the transport of a flowing low conductivity buffer fluid which results in a region of the low conductivity buffer fluid immediately adjacent the outlet from the first passageway to create the necessary protection from high current drain and sparking. An electrical potential difference applied between the nozzle electrode and an electrode in contact with the conductive medium causes formation of small droplets or bubbles of the nonconducting fluid within the conductive medium.