A centrifuge having a driveshaft that has an end section that tapers toward the central axis of the driveshaft. A rotor is removably mounted on the driveshaft such that the rotor may be axially removed in a removal direction. A bearing surface of a locking element of the rotor is connected to the driveshaft and holds the rotor against removal. A quick-action closure is integrated into the rotor and prevents removal of the driveshaft and the rotor in the removal direction. The end section of the driveshaft extends through an opening in the rotor where it is partially surrounded by multiple locking elements of the rotor for fixing the rotor and the driveshaft together. The locking elements include bearing surfaces engaging the end section and support surfaces engaging the rotor. The quick-action closure has force-transmitting elements which connect the locking elements to a handle permitting locking and/or unlocking the quick-action closure by a respective movement of the handle.

In a centrifugal scroll screen apparatus there is provided a scroll assembly (20) driven by a scroll assembly drive shaft (25) and being connected to the scroll assembly by an axial adjuster comprising a shaft cam portion (92) and a scroll portion (96) each having a respective camming surface (94) whereby relative rotation of the scroll portion (96) and the shaft portion (92) axially adjusts the proximity of the vanes to a coaxial conical screening surface, and a locking ring (97) selectively operable to rotationally secure the scroll portion (96) and the shaft portion (92).

In a centrifugal scroll screen apparatus there is provided a scroll assembly (20) driven by a scroll assembly drive shaft (25) and being connected to the scroll assembly by an axial adjuster comprising a shaft cam portion (92) and a scroll portion (96) each having a respective camming surface (94) whereby relative rotation of the scroll portion (96) and the shaft portion (92) axially adjusts the proximity of the vanes to a coaxial conical screening surface, and a locking ring (97) selectively operable to rotationally secure the scroll portion (96) and the shaft portion (92).

A device provides selective modes of vibrational oscillations and centrifugal rotations for preparing analysis samples. The device includes a base, an elastic connection body, a group of a synchronous unidirectional bearing inner ring and a synchronous unidirectional bearing outer ring, a group of an eccentric unidirectional bearing inner ring and an eccentric unidirectional bearing outer ring, and a synchronous fixed ring and a motor on the base. The eccentric unidirectional bearing outer ring is connected to a sample plate for holding the analysis samples.

A device provides selective modes of vibrational oscillations and centrifugal rotations for preparing analysis samples. The device includes a base, an elastic connection body, a group of a synchronous unidirectional bearing inner ring and a synchronous unidirectional bearing outer ring, a group of an eccentric unidirectional bearing inner ring and an eccentric unidirectional bearing outer ring, and a synchronous fixed ring and a motor on the base. The eccentric unidirectional bearing outer ring is connected to a sample plate for holding the analysis samples.

A sample processing arrangement for processing a fluidic sample, the sample processing arrangement including a sample holder for accommodating the fluidic sample, an apparatus having a rotor mechanism and being configured for selectively operating the sample holder in an orbital motion mode for sample mixing, particularly for shaking, or in a rotary motion mode for sample separation, particularly for centrifuging, a mounting platform having a central portion on which the apparatus and the sample holder are mounted and having a surrounding portion circumferentially surrounding the central portion, and a plurality of module accommodation positions circumferentially distributed in the surrounding portion to surround the rotor mechanism and the sample holder, wherein each of the module accommodation positions is configured for detachably accommodating a selectable one of a plurality of sample processing modules, each being configured for fulfilling an assigned sample processing task, by accommodating the respective sample processing module in the respective one of the module accommodation positions.

A sample processing arrangement for processing a fluidic sample, the sample processing arrangement including a sample holder for accommodating the fluidic sample, an apparatus having a rotor mechanism and being configured for selectively operating the sample holder in an orbital motion mode for sample mixing, particularly for shaking, or in a rotary motion mode for sample separation, particularly for centrifuging, a mounting platform having a central portion on which the apparatus and the sample holder are mounted and having a surrounding portion circumferentially surrounding the central portion, and a plurality of module accommodation positions circumferentially distributed in the surrounding portion to surround the rotor mechanism and the sample holder, wherein each of the module accommodation positions is configured for detachably accommodating a selectable one of a plurality of sample processing modules, each being configured for fulfilling an assigned sample processing task, by accommodating the respective sample processing module in the respective one of the module accommodation positions.

A portable centrifuge having a housing containing a rotational mechanism and a centrifugal container having a longitudinal axis. The rotational mechanism has a circuit including an electrical motor, a switch, and an internal electrical power source. The centrifugal container is operably connected to the rotational mechanism through the housing, and is rotatable about the longitudinal axis. The centrifuge is portable and is for single use.

This disclosure is directed to manual devices or systems for mixing or separating components of a solution. The manual devices or systems include a body and an actuator movably coupled to the body that can be manually actuated by a user. The manual devices and systems include a coupling rotatably coupled to the body. A mounting mounts to the coupling to hold a container filled with a solution. The manual devices and systems include a transmission operatively connected to the actuator and to the coupling. The transmission transmits a manual force from the actuator to the coupling to rotate the coupling and the mounting and mix or separate components within the solution. The manual force applied to the actuator and transmitted to the coupling by the transmission is the only force actively applied by the manual device to the coupling to rotate the coupling.

This disclosure is directed to manual devices or systems for mixing or separating components of a solution. The manual devices or systems include a body and an actuator movably coupled to the body that can be manually actuated by a user. The manual devices and systems include a coupling rotatably coupled to the body. A mounting mounts to the coupling to hold a container filled with a solution. The manual devices and systems include a transmission operatively connected to the actuator and to the coupling. The transmission transmits a manual force from the actuator to the coupling to rotate the coupling and the mounting and mix or separate components within the solution. The manual force applied to the actuator and transmitted to the coupling by the transmission is the only force actively applied by the manual device to the coupling to rotate the coupling.