A dispensing container and adapter system for use with a planetary mixer is disclosed. The dispensing container has a longitudinal axis and a transverse axis. The dispensing container may include a nozzle and a removable cap to cover the nozzle. The removable cap may have a first width dimension measured along the transverse axis. The dispensing container may include a body having a second width dimension measured along the transverse axis. An adapter may receive the dispensing container. The adapter may include a cavity to receive the removable cap. The cavity may have a cavity width that exceeds the first width dimension. The adapter may also include a recess for receiving a portion of the dispensing container. The recess may extend from the cavity. At least a portion of the recess may have a width dimension smaller than both the first width dimension and the second width dimension.

A processing vessel (1) provided with a material inlet (2, 3, 4, 5) and a processed material outlet (25) wherein the material flows continuously through the vessel which is split into a series of zones (6, 7, 8) through which the material passes wherein the zones are shielded from each other by controlling the rate at which the material flows and an increasing level of vacuum is applied inconsecutive zones and the system is provided with acoustic energy which imparts energy to the process material by virtue of the contact between the zone dividers and the process material and processing material in such a vessel.

The present disclosure relates to a system and method for treating wastewater, the method comprising the steps of: providing a vessel for receiving wastewater and a gas, wherein the gas comprises one or more constituent gas components; directing the wastewater and a first gas component of the gas to the vessel; reducing the temperature of the contents of the vessel from a first temperature to a second temperature to facilitate the formation of clathrate hydrates comprising the wastewater and the first gas component; increasing the temperature of the contents of the vessel with respect to the second temperature to facilitate melting of the clathrate hydrates; and removing clean water and/or the first gas component from the vessel.

The present disclosure relates to a system and method for treating wastewater, the method comprising the steps of: providing a vessel for receiving wastewater and a gas, wherein the gas comprises one or more constituent gas components; directing the wastewater and a first gas component of the gas to the vessel; reducing the temperature of the contents of the vessel from a first temperature to a second temperature to facilitate the formation of clathrate hydrates comprising the wastewater and the first gas component; increasing the temperature of the contents of the vessel with respect to the second temperature to facilitate melting of the clathrate hydrates; and removing clean water and/or the first gas component from the vessel.

Electronic devices for treating a biological fluid and methods of operating the devices are disclosed. In some embodiments, the electronic device includes a plurality of non-safety critical components, a first controller communicatively coupled to the plurality of non-safety critical components, a plurality of safety critical components, and a second controller communicatively coupled to the plurality of safety critical components. In some embodiments, the electronic device includes a treatment interface.

Electronic devices for treating a biological fluid and methods of operating the devices are disclosed. In some embodiments, the electronic device includes a plurality of non-safety critical components, a first controller communicatively coupled to the plurality of non-safety critical components, a plurality of safety critical components, and a second controller communicatively coupled to the plurality of safety critical components. In some embodiments, the electronic device includes a treatment interface.

A hydraulic vibration generation device or hydraulic motor is provided. The device includes a manifold having an inner volume with a pressure chamber formed in the inner volume, a fluid inlet orifice and a fluid outlet orifice. The device further includes a vibration generating member having a grooved drive and an off-center weight and retaining plates. The inner volume receives the vibration generating member within it. The vibration generating member rotates and generates vibration in response to hydraulic fluid flowing into the manifold through the inlet orifice and directed through the pressure chamber, relieves pressure upon exiting the pressure chamber into a pressure relief channel and out of the manifold through the outlet orifice. Also provided a hydraulic motor with a same manifold and pressure chamber, but with a power generating member having the same groove drive without an off-center weight. Rotation of the power generating member generates power.

An internal vibratory device for compacting a casting compound includes a vibratory unit having an electric motor, an electronic unit electromechanically coupled to the vibratory unit for controlling the electric motor via a hose connection, and a power supply unit for electrically supplying power to the electronic unit and the electric motor. The electric motor can be controlled by the electronic unit for a short time such that a critical operating state, in particular a low power state of the power supply, can be indicated via a change in its rotational speed.

An emulsification process and use of lipid substances are provided. The process includes: adding an emulsification raw material into an emulsification cylinder through a feeding pipe, and setting the temperature and pressure; turning on an ultrasonic generator; turning on a driving motor, such that the driving motor drives a stirring mechanism to rotate to stir the emulsion to drive the emulsification raw material to flow circumferentially; the stirring mechanism driving shearing mechanisms to intermittently reversely move to shear, disperse and impact the emulsion; and opening a valve on a liquid outlet pipe to discharge the emulsion, wherein an emulsifying device is further included and includes an emulsification cylinder which is installed on a base, and a liquid outlet pipe is provided at the bottom of the emulsification cylinder; and the stirring mechanism drives, when moving, the shearing mechanisms to intermittently reversely move to shear, disperse and impact the emulsion.