The disclosure provides an apparatus for storing platelet-rich plasma (PRP). The apparatus is configured to reversibly receive a platelet-rich plasma (PRP) container. The apparatus comprises a platform defining at least one recess configured to receive the PRP container therein; and an agitator configured to move the platform, and thereby agitate PRP stored in the PRP container. The agitator is configured to move the platform in a circular motion at a frequency of between 10 and 10,000 revolutions per minute (RPM).

A mixer device 1 includes: a drum 3 configured to store materials to be mixed; a device body 4 configured to rotatably support the drum 3; an electric motor 6 configured to apply a rotational driving force to the drum 3; and a battery 8 configured to supply electric power to the electric motor 6, wherein a wheel 29 is attached to the device body 4, and the battery 8 is arranged above the wheel 29.

A DTF continuous ink supply device with a built-in stirring function, comprising a box body and a box cover, the box body and the box cover are installed and connected in a detachable up-and-down structure, ink bottles are installed in the box body, the ink bottles are arranged in six groups, wherein two of the groups are white ink bottles, each white ink bottle is provided with a stirring paddle, a motor is installed on an internal top wall of each white ink bottle, a rotating shaft of the stirring paddle is connected to an output end of the motor. The invention relates to the technical field of ink supply devices.

A portable warming blender includes a base assembly with a recessed portion; a temperature control system; a detachable agitator rotatably mounted on an axle extending longitudinally into the recessed portion; an electric motor; a rechargeable power system; and a controller. The base assembly includes a housing with a cylindrical sidewall, housing the motor, the power system, and the controller. An inner surface of the recessed portion is threaded. The temperature control system includes a temperature sensor and a heating element. The temperature sensor is mounted adjacent to the axle. The heating element heats the recessed portion. The motor is magnetically coupled with the agitator. The rechargeable power system includes a rechargeable battery and a charging port. The controller selectively transmits power to the temperature control system and the motor from the power system when an operating mode is selected. The blender warms, blends, or both in one device anywhere, anytime.

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 mixing device and methods for making bone cement. A piston (156) of the mixing device is located in a first region (158) of a chamber (112) such that a mixing paddle (154) rotates to mix bone cement components at a first pressure to make a bone cement mixture. The piston (156) is moved passed an inlet opening (136) to be located within a second region (160) of the chamber (112) to compress the bone cement mixture to a second pressure greater than the first pressure to compress the bone cement mixture and make the bone cement. The bone cement may be transferred to a delivery device. The mixing device may include features that automatically initiate the compression and transferring phases after completion of the mixing phase, and further include features that automatically terminate the operational cycle. A three-step intuitive workflow utilizing the mixing device to improve efficiency in the surgical suite is also disclosed.

A portable warming blender includes a base assembly with a recessed portion; a temperature control system; a detachable agitator rotatably mounted on an axle extending longitudinally into the recessed portion; an electric motor; a rechargeable power system; and a controller. The base assembly includes a housing with a cylindrical sidewall, housing the motor, the power system, and the controller. An inner surface of the recessed portion is threaded. The temperature control system includes a temperature sensor and a heating element. The heating element heats the recessed portion. The motor is magnetically coupled with the agitator. The rechargeable power system includes a rechargeable battery and a charging port. The controller selectively transmits power to the temperature control system and the motor from the power system when an operating mode is selected. The blender warms, blends, or both in one device anywhere, anytime.

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.

A mixing device and methods for making bone cement. A piston of the mixing device is located in a first region of a chamber such that a mixing paddle rotates to mix bone cement components at a first pressure to make a bone cement mixture. The piston is moved passed an inlet opening to be located within a second region of the chamber to compress the bone cement mixture to a second pressure greater than the first pressure to compress the bone cement mixture and make the bone cement. The bone cement may be transferred to a delivery device. The mixing device may include features that automatically initiate the compression and transferring phases after completion of the mixing phase, and further include features that automatically terminate the operational cycle. A three-step intuitive workflow utilizing the mixing device to improve efficiency in the surgical suite is also disclosed.