An apparatus for disrupting solid materials suspended in a fluid medium includes a plurality of hammer elements that transfer acoustic energy from an acoustic transducer into a concentration zone between heads of the hammer elements and inner walls of a fluid duct which act as an anvil, thereby causing cavitations to form within the concentration zone. The transducer may be a cylindrical transducer compression fit into an acoustic projector from which the hammer elements extend towards a distal end, and mass balance elements extend towards a proximal end. The apparatus can be used to efficiently extract juice from fruit pulp, separate oils from plant matter, and process various organic and inorganic materials.

A hydrodynamic cavitation unit for a hydrodynamic cavitation device is provided. The hydrodynamic cavitation device is configured for fluid communication with an inlet conduit and an outlet conduit. The hydrodynamic cavitation unit includes a body; and a plurality of lumens through the body. Each of the lumens is configured for fluid communication from the inlet conduit, through the body, and to the outlet conduit. A ratio of a total cross-sectional area of the lumens to a cross-sectional area of the inlet conduit is about 1:1. A ratio of a cross-sectional area of the hydrodynamic cavitation unit to the cross-sectional area of the inlet conduit is about 2:1. Each of the lumens may have a frustoconical or Venturi shape. Related apparatuses, systems, techniques, and articles are also described.

Chemical reactors (10) and methods crack hydrocarbons in process fluids by accelerating the process fluid to a velocity greater than Mach 1 with an axial impulse impeller (40) and generating a shock wave (90) in the process fluid by decelerating it in a static diffuser (70) having diverging diffuser passages (72). Temperature increase of the process fluid downstream of the shockwave cracks the entrained hydrocarbons in a single pass, through a unidirectional flow path (F), within a single stage, without recirculating the process fluid for another pass through the same stage. In some embodiments, the turbomachine chemical reactor (110) has multiple successive stages of one or more axial impulse impellers (40A, 40B), paired with a diverging passage, static diffuser (70). Successive stages crack additional hydrocarbons by successively raising temperature of the flowing process fluid.

The present invention aims to provide techniques for preparing complexes of magnesium carbonate particles and a fiber. The complexes of magnesium carbonate microparticles and a fiber can be synthesized efficiently by synthesizing the magnesium carbonate in a solution containing the fiber.

A method and device for producing high quality alcohol beverages, including liquor, cordial, tincture, whiskey, cognac, brandy, vodka, rum, gin, wine, cocktail, etc., is based on the action of hydrodynamic cavitation treatment of components of alcohol beverages. The fluid flow moves at a high rate through a multi-stage blending hydrodynamic device and multi-stage cavitation device to generate hydrodynamic cavitation features in the fluid flow. The cavitation features generate changes in the velocity, pressure, temperature, chemical composition and physical properties of the liquid. Hydrodynamic cavitation processing provides effective blending of components and homogenization of alcoholic beverage, improves its organoleptic qualities.

An apparatus for enhancing phase contact and chemical reactions is provided. The apparatus comprises at least one high-turbulence mixing stage and at least one high-shear-stress and high-cavitation stage. The stages are adapted to cause an increase in relative sliding speeds of phases involved in a multiphase flow passing through the stages. The high-shear-stress and high-cavitation stage comprises a rotor having radial teeth housed in a cavitation chamber surrounded by a stator having radial teeth. The facing surfaces of the radial teeth have a parabolic profile in circumferential direction. For each tooth, the parabolic profile lies along a curve of a parabola of which a vertex is arranged at a rear edge of the tooth, with respect to a direction of rotation of the rotor, and along a radius extending from the rear edge to a center of the rotor. The focus of the parabola is also located on the radius.

Disclosed is an apparatus and method for providing asymmetric oscillations to a container. The container may include a fluid, a particle, and/or a gas. A vibration driver attached to the container provides asymmetric oscillations. A controller connected to the vibration driver controls an amplitude, frequency, and shape of the asymmetric oscillations. An amplifier amplifies the asymmetric oscillations in response to the controller. A sensor disposed on the vibration driver provides feedback to the controller.

A cavitation apparatus capable of performing multiple, different-type cavitation processes taking place simultaneously in the same geometric space, thereby obtaining an effective cavitation process that is significantly faster than those provided by conventional cavitation apparatus. The cavitation apparatus can include consecutive and/or simultaneous cavitation units which are configured to carry out consecutive and/or simultaneous cavitation processes on a material flowing through the apparatus, such that effects of one or more prior cavitation processes are present in the material while the material is subjected to one or more further cavitation processes within the apparatus, enhancing the cavitation effects in a reduced amount of time and increasing productivity of the apparatus. In some embodiments, the apparatus can perform seven cavitation processes, of four different types.

Disclosed is a method for enhancing leaching of metals in zinc hypoxide powder by mechanochemistry coupling with sonochemistry, comprising the following: mechanical activation: a raw material containing zinc hypoxide powder is mechanically activated so that an activated material is obtained; and ultrasonic treatment: the activated material is mixed with an acidic leaching solution to obtain a mixture, the mixture is subjected to ultrasonic treatment, and a liquid phase is obtained as the leachate. Mechanochemical activation and ultrasonic chemistry synergistically enhance the leaching efficiency and leaching rate of multiple metals through the destruction and cavitation of the zinc oxide powder structure. This process can indirectly reduce the concentration of the used acidic leaching solution and shorten the leaching duration. In practical production, the specific application of the process can reduce the anticorrosion cost and running cost of reaction equipment, indirectly leading to excellent production benefit.

A process for the combined degumming and neutralization of an oil containing phosphatides and FFA, the process comprising: dosing an aqueous degumming reactant into the oil to form a mixture; introducing the mixture into a first set of flow-through hydrodynamic cavitation reactors to form at the exit of the first set of flow-through hydrodynamic cavitation reactors a mixture; dosing, at the exit of the first set of flow-through hydrodynamic cavitation reactors an aqueous caustic solution into the oil to form a mixture of aqueous caustic dispersed into the oil; introducing the mixture of an aqueous caustic dispersed into the oil into a second set of flow-through hydrodynamic cavitation reactors to form a mixture of oil containing hydrated phosphatides and neutralized FFA (soaps); and separating the mixture of oil containing hydrated phosphatides and soaps to obtain an oil phase and an aqueous phase.