A combined lid and strainer device for a paint container features an outer mounting rim configured for mated fitting onto a rim of the paint container. Within a central circular area surrounded by the rim, there is a perforated a straining area through which paint is pourable. A movable cover is selectively movable between a closed position overlying the perforated straining area, and open positions withdrawn therefrom to allow strained pouring of the paint therethrough. Raised features on the cover are used to secure the cover closed when the lidded container is placed in a paint shaker. A sealing membrane is used, at least initially, seal the perforated area in airtight fashion to maintain paint freshness. Securement features are usable to secure the flap in both closed and open positions.

A sample purification system includes a container assembly bounding a sample purification compartment and having an upper end and an opposing lower end, the sample purification compartment comprising mixing zones and settling zones. A plurality of shielding elements are positioned within the sample purification compartment so as to at least partially separate adjacent mixing zones and settling zones or separate adjacent mixing zones, the mixing zones being in fluid communication with the settling zones. A mixing element is disposed within each mixing zone. An acoustic wave settler is aligned with a portion of the container assembly, the acoustic wave settler being configured to emit an acoustic wave through the portion of the container assembly and a mixture disposed therein, the acoustic wave coalescing fluid phase droplets disposed in the mixture to increase the buoyancy or density of the fluid phase droplets.

A sample purification system includes a mixing zone; a settling zone in fluid communication with the mixing zone; a mixer element disposed in the mixing zone, the mixer element being configured to mix immiscible liquids to form a mixture; and a first acoustic wave settler configured to emit an acoustic wave into the mixture.

A batch carbonation apparatus includes a housing defining a vessel cavity. The housing includes an agitation mechanism. The pressure vessel includes a cap that has a CO2 inlet and a CO2 outlet is provided. The pressure vessel also includes a seal. The pressure vessel is moveable into an out of the vessel cavity. A locking mechanism is provided and is attached to the agitation mechanism to removably lock the cap and seal relative to the pressure vessel. A CO2 source is connected to a plurality of valves where each valve has a differing pressure. A selection toggle is attached to the housing. A control mechanism is coupled to the plurality of valves. A user selects a desired carbonation level using the selection toggle and CO2 is introduced to the pressure vessel at a specified pressure wherein the agitation mechanism agitates liquid within the pressure vessel forming a carbonated beverage having a selected carbonation level. Also disclosed is a process of forming a carbonated beverage in a batch.

The present invention is directed to a method and device to isolate compounds from plant material using vibrational pulsing, vibrational decanting, vibrational sieving and vibrational rinsing. A susceptible liquid is generated by vibrational agitation, decanted when in a vibrating container and then collected by passing over a series of vibrating screens and then rinsed with water while collected on the vibrating screens and the residue collected. The isolated compound can either be collected in the decant or retained on the screens. In an embodiment of the invention, the vibrational rinsing step reduces unwanted impurities isolated.

A light emitting device mixer includes at least two bowl feeders, each including a bowl capable of holding workpieces, and a driving unit capable of causing vibration to the bowl. The bowl feeders include a moving passage through which the workpieces may move from one bowl feeder to an adjacent bowl feeder.

An inner core assembly for a vibration mixer, includes a motor assembly and a compression assembly located above the motor assembly, wherein the motor assembly comprises a vibration motor, a rotor shaft of the vibration motor is connected to the compression assembly by using an eccentric structure, the compression assembly comprises a stage, the stage is connected to a pressure plate mounting bracket by using a guiding shaft, the pressure plate mounting bracket is capable of sliding along the guiding shaft, the rotor shaft of the vibration motor rotates and drives, by using the eccentric structure, the compression assembly to perform reciprocating motion.

An inner core assembly for a vibration mixer, includes a motor assembly and a compression assembly located above the motor assembly, wherein the motor assembly comprises a vibration motor, a rotor shaft of the vibration motor is connected to the compression assembly by using an eccentric structure, the compression assembly comprises a stage, the stage is connected to a pressure plate mounting bracket by using a guiding shaft, the pressure plate mounting bracket is capable of sliding along the guiding shaft, the rotor shaft of the vibration motor rotates and drives, by using the eccentric structure, the compression assembly to perform reciprocating motion.

The present technology provides a technology that liquid in round-bottom vessels is efficiently agitated. There is provided a vessel rack at least including a holder having a plurality of through-holes into which round-bottom vessels each having a closed-bottom tube shape are inserted, and a support having a plurality of supporting holes that are arranged facing to the through-holes and support bottoms of the round-bottom vessels, the bottoms of the supporting holes each having a bulge such that liquid in the round-bottom vessels forms a vortex at a time of agitation of the liquid. Also, there is provided an agitator of agitating liquid in round-bottom vessels at least including the vessel rack, a mounting unit that mounts the vessel rack, and a rocking unit that rocks the mounting unit, and the like.

The present technology provides a technology that liquid in round-bottom vessels is efficiently agitated. There is provided a vessel rack at least including a holder having a plurality of through-holes into which round-bottom vessels each having a closed-bottom tube shape are inserted, and a support having a plurality of supporting holes that are arranged facing to the through-holes and support bottoms of the round-bottom vessels, the bottoms of the supporting holes each having a bulge such that liquid in the round-bottom vessels forms a vortex at a time of agitation of the liquid. Also, there is provided an agitator of agitating liquid in round-bottom vessels at least including the vessel rack, a mounting unit that mounts the vessel rack, and a rocking unit that rocks the mounting unit, and the like.