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.

A receiving device to form a manufacturing apparatus when the receiving device is inserted into a mixing machine, includes a first receiving location configured to receive a first capsule containing a first formulation, a second receiving location configured to receive a second capsule containing a second formulation, a first bearing element located at the level of a first actuation face of the receiving device and movable inside the first receiving location, to exert a force on the first capsule, and/or a second bearing element located at the level of a second actuation face, preferably opposite to the first actuation face, and movable inside the second receiving location, in order to exert a force on the second capsule, wherein at least one bearing element is a vane movable in rotation about a hinge, the movable vane being configured to enter one of the first and second receiving locations.

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.