Described herein are devices and methods for rotating a container (e.g., a capped tube containing a sample). The disclosure provides devices and methods of rotating a container using one motor, resulting in a less complex device. The device moves and rotates a container rotating member which in turn is used to rotate a container. The devices can be used in automated analytical instruments (e.g., automated blood analyzers) that automatically transport and detect the identity of sample containers. The devices can also be used in instruments that automatically spin sample containers to mix or homogenize the sample.

Provided is an electrolyte analyzing device that prevents contamination caused by contacting different reagents by a suction nozzle when reagent replacement is performed. The electrolyte analyzing device includes a nozzle support part 203 coupled to a suction nozzle 6 and movable between a reagent container replacement position and a reagent suction position; a locking mechanism 301 fitted with the nozzle support part 203 moved to the reagent container replacement position and fixes the nozzle support part 203 at the reagent container replacement position; and an unlocking mechanism 302 that releases fitting of the nozzle support part 203 and the locking mechanism 301 in a power-on state. When a reagent container 101 satisfies a predetermined condition, the unlocking mechanism 302 is controlled to release the fitting between the nozzle support part 203 and the locking mechanism 301, so that the nozzle support part 203 moves to the reagent suction position.

A conveyor assembly for transporting a carrier coupled to a receptacle to a processing station located within a housing of an instrument. The conveyor assembly includes a spur conveyor subassembly and a buffer conveyor subassembly for transporting the carrier from a host conveyor assembly to the spur conveyor subassembly. The spur conveyor subassembly includes (i) a rotatable diverter having at least one recess for receiving and moving the carrier between the buffer conveyor subassembly and the spur conveyor subassembly and (ii) a gripper configured to grasp the carrier and move it from the diverter to the processing position located within the housing of the instrument.

A container carrier for carrying a sample container along a track is presented. The container carrier comprises a holding portion for receiving and holding a sample container and a base portion. A radio frequency identification (RFID) tag containing identifying information is provided with an antenna for wireless communication of the RFID tag with a reader device of the diagnostics system to read the identifying information. The RFID tag is on the holding portion. An arrangement for a diagnostics system is provided comprising container carriers and a track with a transport mechanism for moving the container carriers along a transportation lane. The transport mechanism defines a transport plane along which the container carriers move. A reader device reads the identifying information from the RFID tags. The reader device comprising a reader antenna above the transport plane to generate and emit a reader field for wireless communication with the RFID tag's antenna.

A sample tube rack for receiving at least one sample tube comprises an upper part comprising an upper surface, wherein at least one upper opening for receiving the sample tube is provided in the upper surface; an intermediate part comprising an intermediate surface, wherein at least one intermediate opening for receiving the sample tube is provided in the intermediate surface; and a lower part comprising a supporting surface, wherein at least one supporting position for supporting the sample tube is provided in the supporting surface. Therein, the intermediate part is connected to both the upper part and the lower part such that the at least one upper opening is substantially aligned above the at least one intermediate opening and above the at least one supporting position for receiving the at least one sample tube. At least one gripping orifice is provided in a lateral side of the lower part.

An automatic analyzer for analyzing samples includes a lift, a part take-out station and a rack recovery station. The lift is configured to raise and lower a plurality of stacked part racks to the part take-out station and to the rack recovery station while keeping the part racks together. The part take-out station comprises a first rack separator configured to prevent the uppermost one of said stacked part racks from being lowered when the lift lowers, while allowing the other part racks to lower, so that the uppermost rack is separated from the other part racks so as to remain in the part take-out station. The rack recovery station comprises a second rack separator configured to prevent the uppermost one of said stacked part racks from being lowered when said lift lowers, while allowing the other part racks to lower, so as to remain in the rack recovery station.

Systems and methods for safe collection and transportation of fluid samples for analysis are described to avoid exposure of hazardous materials to personnel during collection and transfer of samples to laboratory processing equipment. A system embodiment includes, but is not limited to, a sample module including an enclosure configured to separate a sample from an external environment; a filling station defining a compartment into which the sample module can be received, the filling station configured to direct a fluid sample into the sample module and to rinse fluid connections between the filling station and the sample module prior to decoupling of the sample module from the filling station; and a sample transfer station configured to receive the sample module and to transfer sample from the sample module and direct the sample into a sample container.

A method for generating a control program for a laboratory automation device includes: receiving video data displaying a work area of a laboratory assistant, the work area containing a hand-held pipette and containers for receiving a liquid; detecting openings of the containers in the video data and determining positions of the openings; detecting a pipette tip of the hand-held pipette in the video data and determining a movement of the tip; and generating the control program for the laboratory automation device from the movement of the pipette tip with respect to the positions of the openings, wherein the control program is adapted for moving a pipetting arm with a robot pipette of the laboratory automation device with respect to containers of the laboratory automation device accordingly to the movement of the hand-held pipette in the work area.

A rover-based integrated laboratory system including autonomous mobile robots is disclosed. Namely, a rover-based integrated laboratory system is disclosed comprising a workspace; a laboratory component within the workspace, the laboratory component being adapted to perform a laboratory technique; a labware component within the workspace that is adapted to be used in the laboratory technique; and a rover component within the workspace that is operatively connected to the laboratory and the labware components, the rover component being an autonomous mobile robot.

In order to easily identify a specimen to be extracted because, for example, an item remains uninspected, from a rack 31 collected in a storage part 13 or the rack 31 taken out from the storage part, a camera of a smart device takes an image of the rack; and a calculation unit included in the smart device provides a mark, by AR technology, at the position of a specimen to be extracted. For example, the item that remains uninspected is identified on the basis of information about a combination of a rack ID and an identifier and information, which is received from an operation unit about specimens at respective positions. Thus, irrespective of a place or whether the specimen to be extracted is inside or outside of the device, the specimen to be extracted can be reliably specified from a plurality of specimen containers provided on a holder.