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.

A sample container carrier for a laboratory sample distribution system is presented. The sample container carrier comprises a magnetic element that is arranged such that a magnetic move force applied to the sample container carrier depends on an angularity. A laboratory sample distribution system comprising such a sample container carrier and a laboratory automation system comprising such a sample distribution system are also presented.

An analytical laboratory system and method for processing samples is disclosed. The system includes a manager unit, as well as an aliquotter unit and a centrifuge unit.

A magazine device (14) and method are provided for a measuring device (12) for measuring a concentration of gaseous and/or aerosol components of a gas mixture. The magazine device (14) includes a holding device (16) for a plurality of reaction carriers (18), which have each at least one reaction chamber with a reactant. The reactant is designed to react with a particular component to be measured in the gas mixture or with a reaction product of the component to be measured in an optically detectable manner. A feed device (20) removes a reaction carrier (18) of the plurality of reaction carriers (18) from the holding device (16) and feed the reaction carrier to the measuring device (12) for carrying out a measurement of the particular component to be measured in the gas mixture. A control unit (22) controls the holding device (16) and/or the feed device (20).

The invention concerns a laboratory product transport element for a laboratory transport system with an energy receiver and/or energy accumulator to provide drive power, at least one signal receiver to receive control signals, a control unit to generate drive signals as a function of at least one control signal obtained from the at least one signal receiver, movement devices for independent movement of the laboratory product transport element on a transfer path as a function of the drive signals of the control unit, in which the drive devices are driven by the drive power and at least one holder to hold a laboratory product being transported. The invention also concerns a laboratory transport system with at least one laboratory product transport element according to an embodiment of the invention and a transfer path arrangement. The invention also concerns methods for operation of laboratory transport systems according to an embodiment of the invention.

A device for releasably holding an elongated object, such as a test tube, in a predetermined orientation includes a gripping element configured for circumferential expansion and contraction with respect to the object. An actuator element coupled to the gripping element is configured to effect circumferential expansion of the gripping element to an expanded configuration able to receive an end of the elongated object. A locking mechanism coupled to the actuator element is configured to lock the actuator element in a position holding the gripping element in the expanded configuration. A lock release mechanism is configured to be triggered by an elongated object inserted into the expanded gripping element and to release the locking mechanism, thereby allowing the biased gripping element to return to a contracted configuration gripping a portion of the object. The device and an object held thereby can be conveyed on a conveyor.

The invention concerns a laboratory product transport element for a laboratory transport system with an energy receiver and/or energy accumulator to provide drive power, at least one signal receiver to receive control signals, a control unit to generate drive signals as a function of at least one control signal obtained from the at least one signal receiver, movement devices for independent movement of the laboratory product transport element on a transfer path as a function of the drive signals of the control unit, in which the drive devices are driven by the drive power and at least one holder to hold a laboratory product being transported. The invention also concerns a laboratory transport system with at least one laboratory product transport element according to an embodiment of the invention and a transfer path arrangement. The invention also concerns methods for operation of laboratory transport systems according to an embodiment of the invention.

A laboratory sample distribution system and a laboratory automation system comprising such a laboratory sample distribution system are presented. The laboratory sample distribution system comprises a number of sample container carriers adapted to move autonomously and to communicate with each other and with a central control unit.

A method of rotating a sample container carrier on a transport plane of a laboratory sample distribution system is presented. The sample container carrier is rotated by using a movement relative to a number of rotator elements. A laboratory sample distribution system being able to perform such a method and a laboratory automation system comprising such a laboratory sample distribution system are also presented

An automation system for an in vitro diagnostics environment includes a plurality of intelligent carriers that include onboard processing and navigation capabilities. The intelligent carriers can include one or more image sensors to observe the relative motion of the track as the carrier traverses it. The carriers can also observe position marks on the track surface to provide absolute position information, which can include additional data, such as routing instructions. Synchronization marks may be provided to correct errors in the observed trajectory.