An automated system and method for storing/retrieving vessel holders is presented. A first storage compartment comprises first storage sections. A first translating mechanism vertically translates one storage section to a loading level for loading holders into the first storage compartment and translates one storage section to a handing-in level for handing in holders to/from an analyzer. A second storage compartment comprises second storage sections. A second translating mechanism vertically translates one second storage sections to a handing-out level and translates one storage section to an unloading level for unloading holders from the second storage compartment. A first transport mechanism comprises a first conveyor for transporting holders from a first storage section at the handing-in level to a handing-over station. A second transport mechanism comprises a second conveyor for transporting holders from the handing-over station to a second storage section at the handing-out level. A controller operates the mechanisms.

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 specimen transportation system is configured from linear modules, turn modules, and connection modules. The modules can freely combine with one another. Moreover, the modules form multiple paths through which specimen racks outputted from one specimen output device are transported to multiple analysis devices. When transporting a specimen rack from an upstream side to a downstream side, each module attaches a destination signal associated with the specimen rack to the specimen rack and transfers the destination signal to the downstream side. As a consequence of each module transporting the specimen rack from the upstream side to the downstream side that corresponds to the destination signal, the specimen rack becomes transported along a path that corresponds to the destination signal.

A method of evaporation control of a sample which is stored in a thermally insulated state is configured for preventing evaporation or denaturing of the samples and specimens. The method includes carrying the samples contained in individual containers out from a cold container having a capability of cold storage. An elapsed time that each sample container has been removed from the cold container is measured and is compared with a preset time. If the elapsed time is less than the preset time, the sample container can be returned to the cold container. An alarm is output if the elapsed time exceeds the preset time.

The specimen storage apparatus includes: a specimen conveyor line which conveys a specimen for which the pre-processing is completed and which is installed on a specimen conveyance holder; a lift mechanism capable of driving a specimen tray having the specimen installed therein in front-and-back and vertical directions; a specimen chuck mechanism which transfers the specimen from a specimen acquisition position of the specimen conveyor line to the specimen tray on the lift mechanism; a specimen storage unit which receives the specimen tray from the lift mechanism, includes hierarchical specimen storage spaces in a vertical direction, and accommodates a plurality of specimen trays in a lateral direction while keeping them cold; a shutter mechanism which is opened and closed at the time of delivery of the specimen tray between the lift mechanism and the specimen storage unit; and a control unit which controls each of the mechanisms.

An automated system and method for processing vessels containing biological samples are presented. The system comprises vessel holders, a transport medium for transporting the vessel holders between the components of the system, a work cell for processing, a storage module for empty vessel holders, wherein the storage module is connected to the transport medium, a robotic manipulator for engaging and/or disengaging the vessels with empty vessel holders, an empty vessel holder transfer unit for introducing empty vessel holders into or retrieving them from the storage module, and an empty vessel holder detection unit, including an empty vessel holder detector for discriminating between filled and empty vessel holders as well as a transfer initiator configured to initiate the introduction or re-introduction of an empty vessel holder detected in or on the transport medium into the storage module by the empty vessel holder transfer unit.

An automated system and method for processing vessels containing biological samples are presented. The system comprises vessel holders, a transport medium for transporting the vessel holders between the components of the system, a work cell for processing, a storage module for empty vessel holders, wherein the storage module is connected to the transport medium, a robotic manipulator for engaging and/or disengaging the vessels with empty vessel holders, an empty vessel holder transfer unit for introducing empty vessel holders into or retrieving them from the storage module, and an empty vessel holder detection unit, including an empty vessel holder detector for discriminating between filled and empty vessel holders as well as a transfer initiator configured to initiate the introduction or re-introduction of an empty vessel holder detected in or on the transport medium into the storage module by the empty vessel holder transfer unit.

An automatic analyzing apparatus capable of obtaining an analysis result of a specimen high in urgency in a shorter time is provided. When a first rack 50 is present in a sampling line 103 and an analysis request for a second rack higher in the degree of urgency for analysis than the first rack 50 is detected, a control unit unloads the first rack 50 onto a transport line 100 through a return line 102, allows the first rack 50 to stand by at a rack standby position 120 on a transport line 101 between a loading line 101 and the return line 102 under control, and loads the second rack from the transport line 101 onto the sampling line 103 through the loading line 101 and transports the second rack to the dispensing position 111 under control while allowing the first rack 50 to stand by.

A method and a device for transferring tubes between a laboratory automation system and a sample archiving system are presented. When transferring a tube from the laboratory automation system to the sample archiving system, a tube carrier carrying a tube is conveyed to a first take-over module via a first conveyor. At the first take-over module, the tube is removed from the tube carrier and the empty tube carrier is conveyed away from the first take-over module via a second conveyor. When transferring a tube from the sample archiving system to the laboratory automation system, an empty tube carrier is conveyed to a second take-over module via a third conveyor. At the second take-over module, at least one tube is inserted into the tube carrier and the tube carrier carrying the at least one tube is conveyed away from the second take-over module via a fourth conveyor.

An automatic analyzer with high processing capacity is capable of immediately measuring an emergency specimen rack. The automatic analyzer includes a conveying line for conveying a specimen rack, and an analysis unit which has a dispensing line in which a plurality of specimen racks are arranged for waiting until sample dispensing, and a sampling area for dispensing the sample to the analysis unit. A rack save area is provided in the dispensing line and at a position adjacent to the upstream side of the sampling area. When a specimen rack exists in the sampling area at the time of measuring an emergency specimen rack, a controller moves the specimen rack to the save area and positions the emergency specimen rack to be moved from a downstream side of the sampling area to the sampling area.